Bird Flu: Science and Policy

[Biowatch]

Australia flu 'may tip pandemic'
By Phil Mercer
BBC News, Sydney

A cruise ship scare helped spike swine flu infections in Australia

The World Health Organization has said that a sharp increase in swine flu cases in Australia may push it to finally announce a flu pandemic.

It would be the first such pandemic announced in four decades.

More than 1,200 people have contracted the virus in Australia, a four-fold increase in a week. [No fatalities.]

etc.

http://news.bbc.co.uk/2/hi/asia-pacific/8092474.stm

[bird_splitter]

http://health.yahoo.com/news/reuters/us_birdflu_china.html

Is Bird Flu coming back stronger?

[toddao]

Avoid Flu Shots With the One Vitamin that Will Stop Flu in Its Tracks


http://articles.mercola.com/sites/articles/archive/2008/10/21/avoid-flu-shots-vitamin-d-is-a-better-way.aspx

[Preciouslife1]

A Clinical Trial of a Whole-Virus H5N1 Vaccine Derived from Cell Culture

http://content.nejm.org/cgi/content/full/358/24/2573?query=TOC

Hartmut J. Ehrlich, M.D., Markus Müller, M.D., Helen M.L. Oh, M.D., Paul A. Tambyah, M.B., B.S., Christian Joukhadar, M.D., Emanuele Montomoli, Ph.D., Dale Fisher, F.R.A.C.P., Greg Berezuk, M.S., Sandor Fritsch, Ph.D., Alexandra Löw-Baselli, Ph.D., Nina Vartian, Ph.D., Roman Bobrovsky, Ph.D., Borislava G. Pavlova, Ph.D., Eva Maria Pöllabauer, M.D., Otfried Kistner, Ph.D., P. Noel Barrett, Ph.D., for the Baxter H5N1 Pandemic Influenza Vaccine Clinical Study Team


ABSTRACT

Background
Widespread infections of avian species with avian influenza H5N1 virus and its limited spread to humans suggest that the virus has the potential to cause a human influenza pandemic. An urgent need exists for an H5N1 vaccine that is effective against divergent strains of H5N1 virus.

Methods
In a randomized, dose-escalation, phase 1 and 2 study involving six subgroups, we investigated the safety of an H5N1 whole-virus vaccine produced on Vero cell cultures and determined its ability to induce antibodies capable of neutralizing various H5N1 strains. In two visits 21 days apart, 275 volunteers between the ages of 18 and 45 years received two doses of vaccine that each contained 3.75 µg, 7.5 µg, 15 µg, or 30 µg of hemagglutinin antigen with alum adjuvant or 7.5 µg or 15 µg of hemagglutinin antigen without adjuvant. Serologic analysis was performed at baseline and on days 21 and 42.

Results
The vaccine induced a neutralizing immune response not only against the clade 1 (A/Vietnam/1203/2004) virus strain but also against the clade 2 and 3 strains. The use of adjuvants did not improve the antibody response. Maximum responses to the vaccine strain were obtained with formulations containing 7.5 µg and 15 µg of hemagglutinin antigen without adjuvant. Mild pain at the injection site (in 9 to 27% of subjects) and headache (in 6 to 31% of subjects) were the most common adverse events identified for all vaccine formulations.

Conclusions
A two-dose vaccine regimen of either 7.5 µg or 15 µg of hemagglutinin antigen without adjuvant induced neutralizing antibodies against diverse H5N1 virus strains in a high percentage of subjects, suggesting that this may be a useful H5N1 vaccine. (ClinicalTrials.gov number, NCT00349141 [ClinicalTrials.gov].)

The rest of the article can be viewed in the link
provided above from the NEJM

[Preciouslife1]

Genome Of 150 Different Avian Influenza Viruses Released

http://www.sciencedaily.com/releases/2008/06/080606133251.htm

(Jun. 11, 2008) — The complete genetic coding sequences of 150 different avian influenza viruses were recently released by U.S. Department of Agriculture (USDA) scientists and government, industry and university collaborators. The information improves scientific understanding of avian influenza, a virus that mainly infects birds but that can also infect humans.

"This is a major milestone in avian influenza research," said David Suarez, research leader of the Exotic and Emerging Avian Viral Diseases Research Unit at the Southeast Poultry Research Laboratory (SEPRL) operated at Athens, Ga., by the Agricultural Research Service (ARS). ARS is the chief intramural scientific research agency of USDA. Suarez oversees the ARS avian influenza virus repository at SEPRL.

"This sequence information, deciphered by our large team, will help researchers better understand virus biology and improve diagnostic tests for avian influenza viruses," Suarez added.

The new release to GenBank, the National Institutes of Health's genetic sequence database, was part of a special sequencing project supported by the presidential initiative on avian influenza. Partners involved in collecting the viruses included USDA's Animal and Plant Health Inspection Service's Wildlife Services, as well as researchers at the University of Georgia (UGA), Ohio State University (OSU) and the University of Alaska-Fairbanks, and others.

After the virus isolates were prepared at SEPRL, the virus' noninfectious genetic material, called ribonucleic acid or RNA, was sent to industry collaborator SeqWright Corporation in Houston, Texas, which used its expertise to fully sequence the genome of each virus. The sequence information was reviewed and annotated at SEPRL for release to GenBank.

"The project's ultimate goal is to sequence 900 avian influenza viruses from the SEPRL repository," said Suarez. "These include avian influenza viruses collected from both poultry and wild bird species in the United States and around the world."

The sequence information will be combined with studies comparing the viruses' ability to infect and cause disease in several poultry species including chickens, turkeys and domestic ducks. The analysis of the sequence and biological data will provide new insights into how these viruses cause disease in man and animals. The biological characterization was performed with collaborations with UGA, OSU and University of Delaware collaborators.Adapted from materials provided by USDA/Agriculture Research Service.

[DewDiligence]

What does one name a pre-pandemic
vaccine for bird flu? Prepandrix, of course!

http://online.wsj.com/article/SB121115520068602285.html

>>
EU Clears Glaxo's Prepandrix

By ELENA BERTON
May 19, 2008

LONDON -- GlaxoSmithKline PLC said its Prepandrix vaccine, which could provide protection against the H5N1 bird-flu virus in advance of a potential pandemic, was cleared for use in the European Union.

The European Commission's approval follows a recommendation by the European Medicines Agency in February, which made Glaxo the first pharmaceutical company to obtain a European license for a prepandemic vaccine.

Prepandrix offers some protection against several strains of the H5N1 virus, which has resulted in the deaths of several hundred people and the slaughter of millions of poultry.

In the event of a pandemic, Prepandrix would be given to people, especially health workers, to provide some form of immunity while drug makers develop a more precise vaccine that would directly target the virus responsible for the outbreak.

Due to vaccines' long manufacturing times, a vaccine using a specific strain would become available up to six months after an outbreak, leaving the population unprotected if a prepandemic vaccine weren't used in the meantime.

A number of European countries, including Switzerland and Finland, already have placed orders for the vaccine, while others are in talks with Glaxo, of the United Kingdom, with a view to building stockpiles.

The company has invested $2 billion over the past few years to boost production capacity at its vaccine plants and for its antiviral flu treatment Relenza.

The H5N1 bird-flu virus has been circulating for several years. While it is capable of spreading to people who have extensive physical contact with infected birds, there is no evidence of human-to-human transmission. But there are concerns it may mutate into a strain capable of spreading through humans.

French drug maker Sanofi-Aventis SA, Switzerland's Novartis AG and Baxter International Inc. of the U.S. also are developing pandemic vaccines.
<<

[Preciouslife1]

New Strategies Against Bird Flu

http://www.sciencedaily.com/releases/2008/04/080417130539.htm

(Apr. 21, 2008) — Multiple lethal pathogens such as H5N1 avian flu trigger acute lung injury with a high death rate. Scares of an epidemic have led to an increasing interest in understanding the molecular mechanisms that lead to this condition. Scientists have now identified oxidative stress and innate immunity as a common pathway that controls the severity of ARDS.

The Spanish flu outbreak of 1918 killed between 30 and 50 million people. In the infected patients, the ultimate cause of death was acute respiratory distress syndrome (ARDS). This fatal condition is a massive reaction of the body during which the lung becomes severely damaged. ARDS can be induced by various bacterial and viral infections, but also by chemical agents. These could be toxic gases that are inhaled or gastric acid when aspirated. Once ARDS has developed, survival rates drop dramatically. Among patients infected with H5N1 bird flu, about 50 percent die of ARDS.

An international team of scientists has been addressing the underlying disease mechanisms for the past five years.
The team involved researchers from leading institutions in Vienna, Stockholm, Cologne, Beijing, Hongkong, and Toronto as well as the US-army at Fort Detrick. The international effort was coordinated by Josef Penninger and Yumiko Imai of the Institute of Molecular Biotechnology (IMBA) of the Austrian Academy of Sciences.

A first breakthrough came in 2005 when IMBA-scientists identified ACE2 as the essential receptor for SARS virus infections and showed that ACE2 can protect from acute lung failure in disease models (Imai et al. Nature 2005; Kuba et al. Nature Medicine 2005). Based on these data, ACE2 is now under therapeutic development.

In a paper recently published by Cell, the authors describe an essential key injury pathway that is operational in multiple lung injuries and directly links oxidative stress to innate immunity. They also report for the first time a common molecular disease pathway explaining how diverse non-infectious and infectious agents such as anthrax, lung plague, SARS, and H5N1 avian influenza may cause severe and often lethal lung failure with similar pathologies.

To identify these pathways, the researchers studied numerous tissue samples from deceased humans and animals. Victims of bird flu and SARS were examined in Hongkong, and the US-army provided samples from animals infected with Anthrax and lung plague. Common to all ARDS samples was the massive amount of oxidation products found within the cells. Based on these findings, the scientists showed that oxidative stress is the common trigger that ultimately leads to lung failure.

To elucidate the entire pathway, Yumiko Imai of IMBA developed several mouse models. She was now able to show that a molecule called TLR4 (Toll-like receptor 4) is responsible for initiating the critical signalling pathway. TLR4 is displayed at the surface of certain lung cells called macrophages, important players of the body's immune system.
Once activated, TLR4 initiates an entire chain reaction which ends with the fatal failure of the lungs.
Surprisingly, mice challenged with inactivated H5N1 avian influenza virus also dveloped the full reaction. On the other hand, mutant mice in which the function of TLR4 was genetically impaired were protected from lung failure in repsonse to the inactivated virus.

Based on these findings, the researchers can now outline a common molecular disease pathway: Microbial or chemical lung pathogens trigger the oxidative stress machinery.
Oxidation products are intrepreted as danger-signals by the receptor TLR4. Subsequently, the body's innate immune system is activated. This defense machinery in turn leads to a chain of reactions with severe and often fatal lung damage as a consequence.

For Yumiko Imai, a Postdoc in Josef Penninger's team and pediatrician by training, these results are highly satisfying. Her motivation to study ARDS is based on personal experience in over 10 years at a pediatric intensive care unit. "I have seen so many children die from acute lung failure and felt utterly helpless", Imai says. "Since we found a common injury pathway, our hopes are high that we may be able to develop a new and innovative strategy for tackling severe lung infections."

The paper "Identification of oxidative stress and Toll like receptor 4 signalling as a key pathway of acute lung injury" by Imai et al. will be published on April 18 in Cell, Vol. 133(2).

[Preciouslife1]

New Vaccine May Give Long-term Defense Against Deadly Bird Flu And Its Variant Forms

http://www.sciencedaily.com/releases/2008/04/080417152027.htm

(Apr. 20, 2008) — A new vaccine under development may provide protection against highly pathogenic bird flu and its evolving forms, according to researchers at Purdue University and the Centers for Disease Control and Prevention who discovered the new preventative drug and have tested it in mice.

Unlike traditional influenza vaccines, the new vaccine could be produced quickly and stored for long periods in preparation for a pandemic of dangerous disease-causing avian influenza - H5N1 - and its variants, said Suresh Mittal, a Purdue virologist. In an earlier study with mice, he and his colleagues found that the vaccine protected against H5N1 for a year or longer. Because the studies have only been done in mice, it's not yet known whether the same results will be obtained in humans.

"We want to have a vaccine that can be stored in advance and have the potential to provide protection for a period of time until we can change the vaccine to match the latest form of avian influenza," Mittal said. "The combination of flu genes that we've used to produce the vaccine, I think, will provide that capability."

The importance of having a long-lasting, broadly protective vaccine is that it would give some cross-protection against new viruses with pandemic potential caused by mutations in currently circulating H5N1 viruses. This would give scientists time to develop a better vaccine that would match the latest form of the bird flu.

Mittal and his colleagues, including Suryaprakash Sambhara, the CDC principal investigator on the project, report their findings on the vaccine in the April 15 issue of The Journal of Infectious Diseases. In the December issue of Clinical Pharmacology and Therapeutics, Mittal, Sambhara and their collaborators published their findings of the long-lasting capabilities of the vaccine.

"In humans we want a vaccine to be fully effective for at least a year," said Mittal, a professor of comparative pathobiology. "How long it will last in humans, we don't know yet."

To produce the new vaccine, the scientists used a mutated common cold virus, known as an adenovirus, as a delivery system for important genes from two types of the H5N1 avian influenza. The adenovirus is incapable of multiplying and so cannot cause illness to people. By using the adenovirus vector technology, a couple of problems with existing vaccines used to fight annual flu outbreaks are solved.

Problems with current influenza vaccines include that they are made from eggs, a process that can take as long as six months. The vaccine Mittal and his research team has developed isn't grown in eggs, making vaccine production much faster.

Additionally it would be difficult under normal conditions to produce the hundreds of millions of doses needed to protect everyone at risk for highly pathogenic forms of bird flu. With the beginning of a pandemic, since H5N1 decimates poultry populations, the egg supply needed to produce vaccines would be drastically cut.

The new vaccine uses an adjuvant, molecules added to the vaccine that stimulate the body's immune system, so that lower doses of the vaccine can be used. The adjuvant also allows the vaccine to be stockpiled so more people can be vaccinated, and it helps the vaccine protect against variant forms of the H5N1. The only FDA-approved H5N1 vaccine protects against only that specific strain of flu and only works in about 60 percent of those immunized with a high dose.

"Adenoviral vector-based pandemic vaccines are an attractive option for developing countries where egg-independent cell-based vaccine technologies for other vaccines already are available," Sambhara said. "Since this process is already in place, our vaccine could be produced locally at an affordable price."

Since H5N1 has been known, it has changed so that there are now two main subgroups, called clades. Within one of the clades, five subclades have emerged. This has complicated the task of developing a "perfect match" vaccine for the highly pathogenic bird flu. Other avian influenza viruses exist, but they have not proved to be as lethal to humans or other animals as has H5N1.

Influenza viruses are classified according to the combination of two types of proteins found on the virus cell surface. Different combinations of the 16 types of hemagglutinin (H) protein and nine types of neuraminidase (N) protein form a large number of influenza viruses for which birds are the natural hosts.

New, often more dangerous flu strains develop when the H and N combinations change and combine with other genes from circulating influenza viruses. When the genes of a human or swine influenza mix with an avian variety, a highly pathogenic human flu likely will result, Mittal said.

The first bird-to-human H5N1 case was recorded in 1997 in Hong Kong. The deadly virus has been documented in more than 60 countries, according to the World Health Organization (WHO). Though it mainly has struck wild birds and poultry, there have been more than 300 human cases in 14 countries in the past decade with a 60 percent fatality rate. Most of the human cases have occurred in people who live and work closely with their poultry, but a few cases have been documented of the disease spreading from person to person.

In a typical case, WHO this week reported the most recent fatality - the death of a 30-year-old Egyptian woman who became ill on April 2 after handling sick birds. She did not respond to the antiviral treatment Tamiflu, which can be given after contact with a flu carrier.

The next step in the bird flu vaccine project will be to test the vaccine on new viruses that are appearing, Mittal said.

The scientific team's vaccine work is being developed by PaxVax Inc., which has licensed the technology. Mittal is a scientific adviser for the company but has no financial stake in the commercial development of the vaccine, nor do his colleagues.

National Institute of Allergy and Infectious Diseases and the CDC's National Center for Infectious Diseases and National Vaccine Program provided funding for the study.

The other researchers involved with The Journal of Infectious Diseases study were paper co-lead researcher Mary Hoelscher, postdoctoral researcher Sanjay Garg, research scientists Vic Veguilla and Yumi Matsuoka, and principal investigators Jacqueline Katz and Ruben Donis, all of the CDC; and co-lead researcher Neetu Singh, postdoctoral researcher Lakshmi Jayashankar, and graduate student Aseem Pandey, all of Mittal's Purdue laboratory.

The other researchers involved with the Clinical Pharmacology and Therapeutics study were Hoelscher, Garg, Veguilla, Katz and Xuihua Lu of the CDC; and Singh and Jayashankar of Purdue. Hoelscher and Jayashankar were equal contributors for this study

[Preciouslife1]

Bird flu expert urges vigilance in China

http://www.reuters.com/article/scienceNews/idUSHKG23213220080311?sp=true

HONG KONG (Reuters) - A Chinese expert on respiratory diseases says the H5N1 bird flu virus has shown signs of mutation and urged vigilance at a time when seasonal human influenza is at a peak, newspapers reported on Tuesday.

"When avian flu is around and human flu appears, this will raise the chances of avian flu turning into a human flu. We have to be very alert and careful in March," Zhong Nanshan was quoted by the Ming Pao newspaper as saying.

"People who were killed by bird flu last year and this year were too poor to seek treatment. If you happen to have high fever and pneumonia, you must seek treatment fast," said Zhong, director of the Guangzhou Institute of Respiratory Diseases in China's southern Guangdong province.

Experts are worried about seasonal flu, because it could get mixed up with a deadly novel strain, such as the H5N1 bird flu virus. Such a hybrid would not only become easily transmissible between people, but packed with great killing power.

"The bird flu virus has shown signs of mutation. If infected people don't get treatment in a timely manner, they can die easily," Zhong was quoted as telling reporters on the sidelines of the Chinese parliament's annual meeting.

But World Health Organization (WHO) spokesman Gregory Hartl played down Zhong's concerns.

"Mutations occur in influenza viruses. Separately from that, the (bird flu) virus continues to be deadly. But there is no new jump in deadliness," Hartl said in Geneva.

Three Chinese have died this year of H5N1 bird flu and they were infected probably through contact with sick poultry. The World Health Organization said there was no evidence of transmission between humans in all three cases.

HONG KONG SHUTS SCHOOL

In Hong Kong, the government shut a primary school early ahead of the Easter holidays after one of its students, a 7-year-old boy, died at noon on Tuesday. The boy was admitted to hospital last week with flu-like symptoms and authorities are still trying to determine the cause of his illness.

Thomas Tsang, controller of the Centre for Health Protection, said five other pupils at the school have been admitted to hospital for respiratory infection and their conditions were stable. Three samples have tested positive for influenza A, Tsang said, without specifying the strain.

"The school will close early for Easter from tomorrow ... to facilitate disinfection," Tsang told a news conference. But he said there was no reason to close all schools in Hong Kong, although they would monitor the situation closely.

Hong Kong, which lies at the south of China, is in the grip of a seasonal flu peak, with outbreaks reported in a growing number of schools.

A 3-year-old girl died last week of human H3N2 flu and authorities have ordered schools to conduct fever checks and advise those who are unwell to stay home.

Although the H5N1 virus has infected only 372 people around the world since 2003, its mortality rate has been high, killing 235 of them.

[DewDiligence]

European Regulators Approve Glaxo's Bird-Flu Vaccine

http://online.wsj.com/article/SB120362217503883593.html

>>
By JEANNE WHALEN
February 21, 2008 3:41 p.m.

European regulators have given preliminary approval to a vaccine designed for use in advance of a bird-flu pandemic to help people build immunity against the lethal H5N1 virus.

The vaccine, made by GlaxoSmithKline PLC, is the first vaccine designed to be used before an outbreak occurs. The European Medicines Agency recommended Thursday that the vaccine be approved for sale; the European Commission must still give final approval. A Glaxo spokesman said the company plans to submit the vaccine for U.S. Food and Drug Administration approval by the end of this year.

In a statement, Glaxo said that a "number of national governments" have expressed interest in stockpiling the vaccine, called Prepandrix. The Glaxo spokesman declined to comment on whether the shot would be sold directly to consumers.

The H5N1 virus has been circulating for several years, killing thousands of birds and hundreds of people, but has not yet mutated into a strain that could be easily passed from person to person. If that does happen, it would spark a pandemic.

Prepandrix is designed to raise immunity against several strains of the H5N1 virus. If a pandemic were to happen, vaccine makers would attempt to isolate the strain causing the outbreak and make a more precise vaccine to protect people against it.

A number of other companies are developing bird-flu vaccines, including Sanofi-Aventis SA, Novartis AG, CSL Ltd. of Australia and Baxter International Inc., of Deerfield, Ill.

Last year, the FDA approved a Sanofi vaccine that targets an early strain of H5N1 but has some drawbacks: it showed limited efficacy in clinical tests and must be taken in two large doses. Public health officials worry that vaccines requiring large doses of the active ingredient, or antigen, aren't practical because there is limited manufacturing capacity worldwide. The U.S. government has stockpiled doses of the Sanofi vaccine until more advanced shots are available.

Glaxo's vaccine, Prepandrix, contains an extra ingredient known as an adjuvant, which allows a low level of active ingredient to be used in each shot.
<<

[Preciouslife1]

Shape Of Sugar Molecule Could Be All That Is Stopping Bird Flu Pandemic

http://www.medicalnewstoday.com/articles/93184.php

US scientists have found that the shape of sugar molecules on cell surfaces in the upper respiratory tract determine how easy it is for influenza viruses to infect humans, and suggest that if the deadly strain of H5N1 bird flu were to adapt a way to bind to this shape of sugar molecule it would spread easily from human to human and provoke a world pandemic.

The study, which is funded by the US National Institutes of Health (NIH) is published in the 6th of January early online issue of Nature Biotechnology. The research team that conducted the study was led by Dr Ram Sasisekharan, of the Massachusetts Institute of Technology in Cambridge.

The deadly strain of H5N1 can only pass from bird to human, because it does not have the ability to spread via coughing and sneezing since the virus does not yet have a way of gaining entry to cells in the human upper respiratory tract.

In this study Sasisekharan and colleagues have discovered what makes it possible for some flu viruses to gain a foothold in the cells lining our noses and throats and why other strains find it more difficult.

Dr Jeremy M. Berg, director of the National Institute of General Medical Sciences (the part of NIH that sponsored the research) said:

"Using an approach that combines experimentation and database analysis, Sasisekharan's team has changed our view of flu viruses and how they must adapt to infect us."

"The work may improve our ability to monitor the evolution of the H5N1 virus and thwart potential outbreaks," he added.

The researchers were interested in a group of sugars called glycans. These are long chain molecules of different shapes that sit on the surfaces of cells and control entry into them. They are like gatekeepers of the cells and only let in agents that have the correct protein (rather like a "pass key"). Some viruses can get in because they have the correct protein to bind with the appropriate glycan.

The flu virus has a pass key called hemagglutinin, a protein that is slightly different for each strain of flu, and latches onto glycans for different cell types. The hemagglutinin of flu viruses that transmit easily between humans are able to bind to the glycans of the cells in the upper respiratory tract (the ones that line the nose and throat).

But the bird flu virus does not have the right type of hemagglutinin to gain access to the upper respiratory tract, it can only bind with glycans on the surfaces of lower respiratory tract cells.

However, Sasisekharan had seen some studies that found bird flu hemagglutinin had sometimes been able to bind to glycans on cells in the upper respiratory tract, and was puzzled as to why the virus didn't spread very well. So he and his team decided to investigate this.

They consulted a database maintained by the Consortium for Functional Glycomics (CFG) which holds information on the interactions between proteins and different types of glycan sugars.

They used the CFG glycan preference array which allowed them to see the different protein-glycan preferences and started to look at the shapes and structures of the glycan chains to see if there was a consistent pattern for the upper respiratory tract sugars.

Sasisekharan said they were surprised by the diversity of shapes:

"Even though these glycans are all linked the same way chemically, they have very different shapes."

There was however a consistent pattern. Upper respiratory tract glycans tend to be either short and cone-like, or long and umbrella-like.

The hemagglutinin from human-adapted flu viruses attached mainly to the long umbrella glycans that dominate the upper respiratory tract and the bird flu hemagglutinin attached mainly to the short cone glycans that dominate the lower respiratory tract.

The researchers concluded that H5N1 would have to change its hemagglutinin structure so it could latch onto the long umbrella glycans in order to get a foothold in the upper respiratory tract of humans and thereby spread more easily and provoke a pandemic.

Hopefully this new information will alert scientists to keep an eye on how the H5N1 virus evolves, especially in the way it attaches to long glycans.

It will also help to develop new types of therapies for seasonal and pandemic flu, said the researchers.

"Glycan topology determines human adaptation of avian H5N1 virus hemagglutinin."
Aarthi Chandrasekaran, Aravind Srinivasan, Rahul Raman, Karthik Viswanathan, S Raguram, Terrence M Tumpey, V Sasisekharan & Ram Sasisekharan.
Nature Biotechnology, Published online: 06 January 2008.
doi:10.1038/nbt1375

[Preciouslife1]

Update on Avian Influenza A (H5N1) Virus Infection in Humans.

Writing Committee of the Second World Health Organization Consultation on Clinical Aspects of Human Infection with Avian Influenza A (H5N1) Virus.

http://content.nejm.org/cgi/content/full/358/3/261?query=TOC

The unprecedented epizootic of avian influenza A (H5N1) viruses among birds continues to cause human disease with high mortality and to pose the threat of a pandemic.
This review updates a 2005 report1 and incorporates information recently published or presented at the Second World Health Organization (WHO) Consultation on Clinical Aspects of Human Infection with Avian Influenza A (H5N1) Virus.

Viral Ecology

Highly pathogenic avian influenza A (H5N1) viruses are entrenched among poultry in parts of Asia, Africa, and perhaps the Middle East. The highly pathogenic avian influenza H5 hemagglutinin has evolved into many phylogenetically distinct clades and subclades (Figure 1), that generally correlate with antigenic differences that must be considered in the selection of candidates for H5N1 vaccines. These diverse lineages have been largely separate geographically since 2005 (Figure 1), although clade viruses from China have recently circulated in other Southeast Asian countries.

Figure 1. Evolution of the Hemagglutinin and Other Key Mutations Associated with Virulence or Drug Resistance in Avian Influenza A (H5N1) Virus.
The phylogenetic tree is for the hemagglutinin gene of highly pathogenic avian influenza A (H5N1) viruses. The geographic distributions refer to avian isolates, and the tree is based on publicly available sequences. Clade 0 includes viruses that were first recognized to cause human infections in Hong Kong Special Administrative Region in 1997. Viruses from clades and subclades 0, 1, 2.1, 2.2, 2.3, and 7 have caused human disease. Clade 1 viruses predominated in Vietnam, Thailand, and Cambodia in the early phase of the outbreak (2004–2005), and clade 2.1 viruses are endemic in Indonesia. Clade 2.2 viruses were associated with a major outbreak of H5N1 disease in migratory birds in Qinghai Lake, China, and have since spread, causing avian disease in Central and South Asia, the Middle East, Europe, and Africa and human disease in western Asia, the Middle East, and Africa. Clade 2.3 has become dominant in southern China and has also been detected in adjacent countries. (Modified from the WHO Web site: www.who.int/csr/disease/avian_influenza/guidelines/nomenclature/en/index.html.) The influenza genome contains eight individual segments of RNA, several of which encode two proteins. Within clade 1 or clade 2.1 viruses, polymerase basic protein 2 (PB2) Glu627Lys is observed in some isolates of human viruses but not in avian viruses.3 Some human clade 1 viruses without PB2 627Lys have PB2 701Asn; clade 2.2 viruses of both human and avian origin have PB2 Glu627Lys.4 The importance of sequence variations in NS1, in which most influenza A (H5N1) viruses contain a carboxyl-terminus–sequence motif that mediates binding to various cellular proteins bearing a PDZ domain, remains to be determined..

The influenza A (H5N1) viruses that have infected humans have been entirely avian in origin, and they reflect strains circulating locally among poultry and wild birds. Avian influenza viruses can be maintained, amplified, and disseminated in live-poultry markets. Migratory birds may spread A (H5N1) viruses to new geographic regions, but their importance as an ecologic reservoir is uncertain. The spread of influenza A (H5N1) viruses appears to be principally related to the movement of poultry and poultry products, although recent outbreaks of clade 2.2 virus infection in sub-Saharan Africa, Egypt, and Europe may indicate introduction of the virus by wild birds. The risk of the introduction of influenza A (H5N1) viruses into North America by birds migrating through Alaska appears to be low.

Epidemiology of Human Infections/Incidence and Demographic Characteristics

Despite widespread exposures to poultry infected with avian influenza A (H5N1) viruses, influenza A (H5N1) disease in humans remains very rare. Since May 2005, the numbers of both affected countries13 and confirmed cases of influenza A (H5N1) virus infection (340 cases as of December 14, 2007) have increased, in part because of the spread of clade 2.2 viruses across Eurasia and to Africa5, (Fig. 1 of the Supplementary Appendix, available with the full text of this article at www.nejm.org).

The median age of patients with influenza A (H5N1) virus infection is approximately 18 years, with 90% of patients 40 years of age or younger and older adults underrepresented.
The overall case fatality proportion is 61%; it is highest among persons 10 to 19 years of age and lowest among persons 50 years of age or older.
Whether preexisting immunity, differences in exposure, or other factors might contribute to the apparently lower frequency of infection and lethal illness among older adults is uncertain. Most patients with influenza A (H5N1) virus infection were previously healthy.
Of six affected pregnant women, four have died, and the two survivors had a spontaneous abortion.

Increases in human cases of influenza A (H5N1) have been observed during cooler months in association with increases in outbreaks among poultry (see Fig. 1 of the Supplementary Appendix). However, because cases have occurred year-round, clinicians must be alert to possible human infection at any time, especially in countries with outbreaks of influenza A (H5N1) among birds. To date, no cases of influenza A (H5N1) illness have been identified among short-term travelers visiting countries affected by outbreaks among poultry or wild birds, although clinicians in unaffected countries should consider this possibility in travelers with exposures to poultry.

Surveillance for cases of influenza A (H5N1) has focused on patients with severe illness, but milder illnesses in children, which are not pneumonic, occur.
Limited seroepidemiologic studies conducted since 2003 involving villagers living with backyard poultry, workers in live-poultry markets, and health care workers suggest that asymptomatic or mild human influenza A (H5N1) virus infection is rare (Table 1 of the Supplementary Appendix).

Transmission

Direct avian-to-human H5N1 virus transmission is the predominant means of human infection, although the exact mode and sites of influenza A (H5N1) virus acquisition in the respiratory tract are incompletely understood. Handling of sick or dead poultry during the week before the onset of illness is the most commonly recognized risk factor.
Most patients have acquired A (H5N1) infection from poultry raised inside or outside their houses. Slaughtering, defeathering, or preparing sick poultry for cooking; playing with or holding diseased or dead poultry; handling fighting cocks or ducks that appear to be well; and consuming raw or undercooked poultry or poultry products have all been implicated as potential risk factors.
The defeathering of dead wild swans was implicated in one case cluster.

The influenza A (H5N1) virus can also infect multiple mammalian hosts, including domestic cats and dogs.
None have been implicated in influenza A (H5N1) virus transmission to humans yet, but any animal infected with the virus theoretically poses a risk of transmission and of being a host for viral adaptation to mammals.

Clusters of human influenza A (H5N1) illness with at least two epidemiologically linked cases have been identified in 10 countries and have accounted for approximately one quarter of cases.
Most clusters have involved two or three persons; the largest affected eight. More than 90% of case clusters have occurred among blood-related family members, suggesting possible genetic susceptibility, although one statistical model indicated that these clusters might have occurred because of chance alone.
Most persons in case clusters probably acquired infection from common-source exposures to poultry, but limited, nonsustained human-to-human transmission has probably occurred during very close, unprotected contact with a severely ill patient.
In the largest cluster, transmission probably occurred from the index case to six blood-related family members and subsequently to another family member. Respiratory secretions and all bodily fluids, including feces, should be considered potentially infectious.

In one quarter or more of patients with influenza A (H5N1) virus infection, the source of exposure is unclear, and environment-to-human transmission remains possible.
For some patients, the only identified risk factor was visiting a live-poultry market.
Plausible transmission routes include contact with virus-contaminated fomites or with fertilizer containing poultry feces, followed by self-inoculation of the respiratory tract or inhalation of aerosolized infectious excreta. It is unknown whether influenza A (H5N1) virus infection can begin in the human gastrointestinal tract. In several patients, diarrheal disease preceded respiratory symptoms,36 and virus has been detected in feces. Acquisition of influenza A (H5N1) virus infection in the gastrointestinal tract has been implicated in other mammals Drinking potable water and eating properly cooked foods are not considered to be risk factors, but ingestion of virus-contaminated products or swimming or bathing in virus-contaminated water might pose a risk.

Incubation Period

After exposure to infected poultry, the incubation period generally appears to be 7 days or less, and in many cases this period is 2 to 5 days. In clusters in which limited, human-to-human transmission has probably occurred, the incubation period appears to be approximately 3 to 5 days, although in one cluster it was estimated to be 8 to 9 days.

Pathogenesis/Viral Factors

The viral and host factors that determine host-restriction and disease manifestations are incompletely understood. Preferential binding of the influenza A (H5N1) virus to 2,3-linked sialic acid receptors on avian cells39 is thought to be key in preventing influenza A (H5N1) and other avian influenza viruses from readily infecting humans. Some influenza A (H5N1) viruses isolated from humans have acquired mutations that permit binding to both 2,3-linked sialic acid receptors and 2,6-linked sialic acid receptors, but these mutations appear to be insufficient for efficient human-to-human transmission.
To date, influenza A (H5N1) viruses have shown no transmissibility or poor transmissibility between ferrets and between swine, and reassortment between an influenza A (H5N1) virus and an influenza A (H3N2) virus did not confer transmissibility in ferrets.
Changes in multiple viral genes are probably required to generate a potentially pandemic influenza A (H5N1) virus.

All recent influenza A (H5N1) viruses retain a polybasic amino acid motif at the HA1–HA2 connecting peptide that is characteristic of highly pathogenic avian influenza viruses. Geographic variations in this motif have not been associated with obvious changes in the virulence of infection in humans. Amino acid substitutions in the polymerase basic protein 2 (PB2) gene are associated with mammalian adaptation, virulence in mice, and replication at temperatures present in the upper respiratory tract (Figure 1). However, these mutations do not correlate with obvious differences in mortality among humans with this viral infection.

Viral Replication

The primary pathologic process that causes death is fulminant viral pneumonia. The target cells for replication of the influenza A (H5N1) virus include type 2 alveolar pneumocytes and macrophages.
Bronchiolar and alveolar cells, but not epithelia from the trachea or upper respiratory tract, express detectable 2,3-linked sialic acid receptors.
However, influenza A (H5N1) viruses replicate in ex vivo organ cultures of the upper respiratory tract, postmortem studies show virus in tracheal epithelia, and high titers of virus are detectable in specimens of throat and tracheal aspirates from humans infected with influenza A (H5N1) virus.
These findings suggest that the initial infection may occur in either the upper or lower respiratory tract, although the latter may support more efficient replication.

Limited data show that patients with influenza A (H5N1) disease may have detectable viral RNA in the respiratory tract for up to 3 weeks, presumably because of negligible preexisting immunity and possibly viral evasion of immune responses.3 One patient with fatal infection treated with both antiviral agents and corticosteroids had viral antigen and RNA in tracheal samples on day 27 after the onset of illness.
Viral loads in the pharynx are higher and plasma viral RNA is detected more often in patients with fatal disease than in those with nonfatal disease, indicating that levels of viral replication influence the outcome.3 The reported presence of infectious virus in the blood, cerebrospinal fluid, or viscera of several patients with fatal disease indicates that, as in birds and several mammalian species, disseminated infection occurs in some humans.
A fatal influenza A (H5N1) infection in one pregnant woman who received corticosteroids for treatment of the disease was associated with virus infection of the brain, placenta, and fetus.
Infectious virus and viral RNA have been detected in feces and intestines, suggesting that the virus sometimes replicates in the gastrointestinal tract.

Pathological Findings

The few reported autopsies of patients with influenza A (H5N1) virus infection have shown diffuse alveolar damage with hyaline membrane formation, patchy interstitial lymphoplasmacytic infiltrates, bronchiolitis with squamous metaplasia, and pulmonary congestion with varying degrees of hemorrhage.
Acute exudative, diffuse alveolar damage with macrophages, neutrophils, and activated lymphocytes has been detected in patients who died within 2 weeks after the onset of illness. Apoptosis in alveolar cells and infiltrating leukocytes are prominent findings.
Lymphocyte depletion occurs in the spleen, lymph nodes, and tonsils; histiocytic hyperplasia and reactive hemophagocytosis presumably result from host cytokine responses and viral infection. Edema and degeneration of myocytes in the heart and extensive acute tubular necrosis in the kidney have been observed.

Host Responses

Higher plasma levels of macrophage and neutrophil-attractant chemokines and both proinflammatory and antiinflammatory cytokines (interleukin-6, interleukin-10, and interferon-) have been observed in patients with influenza A (H5N1) virus infection — particularly in patients with fatal infection — than in patients with conventional influenza.
Plasma levels of cytokines and chemokines correlate positively with pharyngeal viral loads, suggesting that these responses are driven by high-level viral replication. In vitro experiments involving primary human macrophages and lung pneumocytes show differential up-regulation of multiple cytokines by influenza A (H5N1) virus as compared with human influenza viruses, indicating that viral hyperinduction probably contributes to hypercytokinemia.

In mouse models of influenza A (H5N1) virus infection, mice with deficient induction of interleukin-6, macrophage inflammatory protein 1, or tumor necrosis factor or its receptors, and mice treated with glucocorticoids, had similar mortality as compared with wild-type animals; mice without interleukin-1 receptors had increased mortality.
Tissue damage in human influenza A (H5N1) disease probably results from the combined effects of unrestrained viral infection and inflammatory responses induced by influenza A (H5N1) infection. Knowledge of the mechanisms of hypercytokinemia is insufficient to guide safe, rational immunomodulatory treatment at present.

Clinical Features

Currently, illness due to influenza A (H5N1) viruses typically manifests as severe pneumonia that often progresses rapidly to the acute respiratory distress syndrome. The time from the onset of illness to presentation (median, 4 days) or to death (median, 9 to 10 days) has remained unchanged from 2003 through 2006 (Table 1).16 Observed differences in mortality among patients with presumed clade 1 and clade 2 virus infections (Table 1 and Table 2) are difficult to interpret because of variations in medical practices and the time from the onset of illness to treatment among affected countries.


Table 1. Case Fatality Proportion According to Clade or Subclade and Median Time from Onset of Illness to Hospitalization or Death in Patients with Confirmed Influenza A (H5N1) Illness.

Table 2. Clinical and Common Laboratory Features of Influenza A (H5N1) Disease at Hospital Admission.

Febrile upper respiratory illnesses without pneumonia in children have been reported more frequently since 2005.
Early consultation and antiviral therapy may have altered the clinical course of these illnesses. Less frequent gastrointestinal symptoms have been reported since 2005 (Table 2), suggesting that some manifestations of clade 1 and 2 virus infections may differ from each other.
Leukopenia, lymphopenia, mild-to-moderate thrombocytopenia, and elevated levels of aminotransferases are common but not universal (Table 2). Lymphopenia and increased levels of lactate dehydrogenase at presentation have been associated with a poor prognosis. Other reported abnormalities include elevated levels of creatine phosphokinase, hypoalbuminemia, and increased d-dimer levels and changes indicative of disseminated intravascular coagulopathy.

The nonspecific clinical presentation of influenza A (H5N1) disease has often resulted in misdiagnosis of subsequently confirmed cases (Table 3); influenza A (H5N1) virus infection has been suspected in only a small number of patients. Health care staff should include influenza A (H5N1) virus infection in the differential diagnosis for patients who present with epidemiologic risk factors and unusual courses of illness, especially rapidly progressing pneumonia (see Fig. 2 of the Supplementary Appendix).

Table 3. Initial Diagnosis in Patients with Confirmed Influenza A (H5N1) Virus Infection.

Laboratory Diagnosis

Detection of viral RNA by means of conventional or real-time reverse-transcriptase polymerase chain reaction remains the best method for the initial diagnosis of influenza A (H5N1).
These assays can provide results within 4 to 6 hours and can be performed under biosafety level 2 conditions. The genetic variability of influenza A (H5N1) viruses, calls for frequent updating of primers and probes. Consequently, access to sequences from recent influenza A (H5N1) viral isolates is essential. To detect other influenza A virus infections and reduce false negative results due to mutations in the H5 hemagglutinin gene, a conserved influenza A gene (e.g., matrix or nucleoprotein) should also be targeted.

Diagnostic yields are higher with throat specimens than with nasal swabs because of higher viral loads of influenza A (H5N1) in the throat.
However, nasal swabs are useful for detecting human influenza viruses, so collection of both specimens is recommended. If they are available, tracheal aspirates have higher viral titers and yields than specimens from the upper respiratory tract. Negative results in single respiratory specimens do not rule out influenza A (H5N1) virus infection, and repeated collection of multiple specimen types is recommended.
Previous antiviral treatment may reduce the diagnostic yield. Detection of influenza A (H5N1) viral RNA in feces or blood may provide prognostic information,3 but it has lower diagnostic sensitivity than influenza A (H5N1) viral RNA in respiratory specimens.

Commercially available rapid assays for influenza-antigen detection have poor clinical sensitivity for the detection of influenza A (H5N1) virus (Table 2 of the Supplementary Appendix),1,20,21 and they do not differentiate between human and avian subtypes of influenza A viruses. Although rapid antigen tests have similar analytic sensitivity for detecting human and avian influenza A (H5N1) viruses, they require 1000 times higher levels of virus than viral cultures to be positive.

The detection of anti-H5 antibodies is essential for epidemiologic investigations and may provide retrospective diagnostic confirmation in patients. Seroconversion generally occurs 2 to 3 weeks after infection. Microneutralization assays are the most reliable methods for detecting antibodies to avian viruses, but they are labor-intensive and require biosafety level 3 facilities and appropriate strains of influenza A (H5N1) viruses. As compared with initial samples, elevations of four times or more or single titers of 1:80 or more in convalescent-phase samples are considered to be diagnostic.
Modified nonpathogenic influenza A (H5N1) virus generated by reverse genetics or lentivirus pseudotyped with H5 hemagglutinin may provide alternatives for performing neutralization tests in biosafety level 2 facilities. Hemagglutination-inhibition assays with the use of horse erythrocytes show promising results but require further validation.

Treatment/Antiviral Agents

Susceptibility to current antiviral agents varies among circulating strains of influenza A (H5N1) viruses. Clade 1 viruses and most clade 2 viruses from Indonesia are fully resistant to M2 inhibitors, whereas clade 2 viruses from the lineages in other parts of Eurasia and Africa are usually susceptible (Klimov A: personal communication).
As compared with influenza A (H5N1) viruses from 1997 or influenza A (H1N1) viruses in vitro, clade 1 viruses generally show enhanced susceptibility to oseltamivir carboxylate, but the high-level replication of some oseltamivir-susceptible strains requires higher doses or more prolonged administration, or both, in animal models. Clade 1 viruses appear to be 15 to 30 times more sensitive to oseltamivir than clade 2 isolates from Indonesia and Turkey, although the possible clinical relevance of such differences in oseltamivir susceptibility remains to be determined. During oseltamivir therapy, the emergence of highly resistant variants with an H274Y neuraminidase mutation may be associated with a fatal outcome. Infection by influenza A (H5N1) viruses containing an N294S mutation that causes a reduction in oseltamivir susceptibility by a factor of 12 to 15 times was reported to be present in two Egyptian patients with fatal disease before therapy, and avian influenza A (H5N1) viruses with reduced susceptibility to neuraminidase inhibitors are occasionally detected.

Early treatment with oseltamivir is recommended, and data from uncontrolled clinical trials suggest that it improves survival (Table 4), although the optimal dose and duration of therapy are uncertain. Mortality remains high despite administration of oseltamivir; late initiation of therapy appears to be a major factor.
Uncontrolled viral replication, as reflected in the detection of persistent pharyngeal RNA after completion of standard therapy, is associated with a poor prognosis.
Higher levels of viral replication and slower clearance of infection probably occur in the lower respiratory tract.
The oral bioavailability of oseltamivir in patients with severe diarrhea or gastrointestinal dysfunction related to influenza A (H5N1) virus infection or those in whom the drug has been administered extemporaneously (e.g., by means of a nasogastric tube) is uncertain.

Table 4. Effects of Treatment and Time to Treatment with Oseltamivir on Survival among Patients with Influenza A (H5N1) Infection.


A higher dose of oseltamivir (e.g., 150 mg twice daily in adults) and an increased duration of therapy, for a total of 10 days, may be reasonable, given the high levels of replication of the influenza A (H5N1) virus, observations of progressive disease despite early administration of standard-dose oseltamivir (75 mg twice daily for 5 days in adults) within 1 to 3 days after the onset of the illness, and the proven safety of higher doses in adults with seasonal influenza, especially if there is pneumonic disease at presentation or evidence of clinical progression.
In mouse models of amantadine-sensitive influenza A (H5N1) virus infection, as compared with monotherapy, the combination of oseltamivir and amantadine significantly increased survival rates and inhibited viral replication in the internal organs. No adverse pharmacologic interactions have been shown in humans.
In areas where influenza A (H5N1) viruses are likely to be susceptible to amantadine, combination treatment with oseltamivir would be reasonable, especially in seriously ill patients.

Although zanamivir is active against oseltamivir-resistant variants with N1 neuraminidase mutations at H274Y66 or N294S, the value of inhaled zanamivir has not been studied in human influenza A (H5N1) disease. Suboptimal delivery to sites of infection in patients with pneumonic or extrapulmonary disease is a concern. Parenteral delivery of zanamivir or the neuraminidase inhibitor peramivir results in antiviral activity in animal models of influenza A (H5N1) virus infection; these agents and others are under clinical development (Table 3 of the Supplementary Appendix).

Other Treatments

Supportive care with correction of hypoxemia and treatment of nosocomial complications remains fundamental in the management of influenza A (H5N1) disease.
Corticosteroids should not be used routinely.
Corticosteroid therapy has thus far not been shown to be effective in patients with influenza A (H5N1) virus infection, and prolonged or high-dose corticosteroid therapy can result in serious adverse events, including opportunistic infections such as central nervous system toxoplasmosis (Soeroso S: unpublished data). In northern Vietnam, mortality was 59% among 29 recipients of corticosteroids, as compared with 24% among 38 persons who did not receive corticosteroids (P=0.004) (Cao T, Thanh Liem N: personal communication). The possible value of other immunomodulators remains to be determined.

Prevention

Avian influenza A viruses are readily inactivated by a variety of chemical agents and physical conditions, including soaps, detergents, alcohols, and chlorination. Guidelines for the prevention of infection with influenza A (H5N1) virus in various risk groups, including poultry workers, travelers, and health care workers, are available from the U.S. Centers for Disease Control and Prevention and the WHO.

Antiviral Chemoprophylaxis

WHO guidelines for the use of antiviral agents for prophylaxis in persons who have been exposed to influenza A (H5N1) viruses in the current pandemic-alert period have been published.
Mathematical models of an emerging outbreak of influenza A (H5N1) in rural Asia predict that a strategy of mass, targeted antiviral chemoprophylaxis and social-distancing measures might extinguish or delay pandemic spread of the virus. The WHO has a stockpile of oseltamivir for this purpose and is working with partners for implementation of its distribution in the event of an outbreak.

Immunization

Safe and immunogenic inactivated H5 vaccines have been developed. Reverse genetics permits the rapid generation of seed viruses with attenuated virulence, but the changing antigenicity of circulating strains of influenza A (H5N1) viruses calls for new candidate vaccines from different lineages6 and the development of vaccines that elicit cross-clade immunogenicity. H5 hemagglutinin appears to be a weak human immunogen. For subvirion vaccines without adjuvants, persons who have not received a priming dose require two doses with a high hemagglutinin antigen content (Table 4 of the Supplementary Appendix). As compared with conventional subunit vaccines, certain oil-in-water adjuvant agents, or the use of whole-virus H5N1 vaccines, can substantially reduce the amount of vaccine antigen required to induce immune responses in persons who have not received a priming dose, and they can induce immune responses to antigenically drifted viruses. However, the specific adjuvant, formulation, dose, stability, and ratio with the antigen are important variables that require clinical testing for each candidate vaccine. Alum adjuvants have not consistently improved the responses to H5 vaccines, whereas certain proprietary adjuvants (e.g., MF59 and AS03) appear to be highly effective and allow for considerable antigen-sparing and cross-reactive antibody responses.
These adjuvants have also been associated with increased rates of local and sometimes systemic reactogenicity.

The antibody levels required for protection against human influenza A (H5N1) illness are unclear. The durability of antibody responses is limited, but boosting with a homologous vaccine or virus vaccine with viral antigen from another clade appears to be effective in persons who have received two priming doses. Prepriming might allow single doses of a homologous vaccine to be sufficient for an antigenically drifted pandemic virus. However, decisions regarding the use of vaccine before a pandemic and stockpiling require complex risk–benefit and cost–benefit analyses that include effects on the seasonal capacity of vaccine production, because the timing and cause of the next influenza pandemic are unknown, and it is unclear whether immunization of large populations could have adverse consequences.

Initial studies in children and elderly persons suggest that antibody responses to subvirion vaccines at high doses (45 or 90 µg) are similar to those in young adults.
Approximately 15 to 20% of older adults have some baseline neutralizing antibodies to H5N1 virus and may have a response to a single dose.6 The mechanisms leading to these antibodies are uncertain. Other studies to date have shown that intradermal H5 vaccines at low doses are poorly immunogenic and may be associated with injection-site reactions.
Intranasal live attenuated H5 vaccines are highly effective in animal models, but they show a variable ability to replicate in humans and to induce immune responses. Various investigational approaches, including conserved antigen vaccines, vectored H5 vaccines, and other adjuvants, are being explored.


Dr. Chotpitayasunondh reports receiving grant support from Sanofi Pasteur and lecture fees from Sanofi Pasteur, GlaxoSmithKline, and Merck; and Dr. Peiris, consulting fees from GlaxoSmithKline and Novartis and travel expenses and lecture fees from Novartis, Roche, and Sanofi Pasteur. No other potential conflict of interest relevant to this article was reported.

Two authors (Drs. Hayden and Shindo) are staff members of the WHO. The authors alone are responsible for the views expressed in this article, and they do not necessarily represent the decisions or the stated policy of the WHO. The views expressed in this article do not necessarily reflect those of the other organizations whose staff participated in the WHO consultation.

© World Health Organization 2008. All rights reserved. Published with permission from the World Health Organization.

We thank Drs. Christoph Steffen and Kaat Vandermaele of the WHO for their help with access to data and development of the management algorithm, Diane Ramm of the University of Virginia for her assistance in the preparation of an earlier version of the manuscript, and our colleagues in countries affected by A (H5N1) virus for their willingness to share unpublished clinical data for this article.

* Affiliations of the writing committee are listed in the Appendix. The participants in the meeting of the Second World Health Organization Consultation on Clinical Aspects of Human Infection with Avian Influenza A (H5N1) Virus, Antalya, Turkey, March 19–21, 2007, are listed in the Supplementary Appendix, which is available with the full text of this article at www.nejm.org.


Source Information

The members of the writing committee (Abdel-Nasser Abdel-Ghafar, M.D., Tawee Chotpitayasunondh, M.D., Zhancheng Gao, M.D., Ph.D., Frederick G. Hayden, M.D., Nguyen Duc Hien, M.D., Ph.D., Menno D. de Jong, M.D., Ph.D., Azim Naghdaliyev, M.D., J.S. Malik Peiris, M.D., Nahoko Shindo, M.D., Santoso Soeroso, M.D., and Timothy M. Uyeki, M.D.) assume responsibility for the overall content and integrity of the article.

Address reprint requests to Dr. Hayden at the Global Influenza Program, Department of Epidemic and Pandemic Alert and Response, World Health Organization, 20 Ave. Appia, Ch-1211, Geneva 27, Switzerland, or at haydenf@who.int.

[Preciouslife1]

WHO confirms human-to-human birdflu case
Thu Dec 27, 2007

http://www.reuters.com/article/healthNews/idUSL2732429220071227?sp=true

WHO says only limited human H5N1 spread in Pakistan

GENEVA (Reuters) - The World Health Organization (WHO) confirmed on Thursday a single case of human-to-human transmission of the H5N1 bird flu virus in a family in Pakistan but said there was no apparent risk of it spreading wider.

A statement from the U.N. agency said tests in its special laboratories in Cairo and London had established the "human infection" through presence of the virus "collected from one case in an affected family".

But it said a WHO team invited to Pakistan to look into an outbreak involving up to nine people, from late October to December 6 had found no evidence of sustained or community human-to-human transmission.

No identified close contacts of the people infected, including health workers and other members of the affected family, had shown any symptoms and they had all been removed from medical observation, the WHO added.

The outbreak followed a culling of infected chickens in the Peshawar region, in which a veterinary doctor was involved. Subsequently he and three of his brothers developed proven or suspected pneumonia.

The brothers cared for one another and had close personal contact both at home and in the hospital, a WHO spokesman in Geneva said. One of them, who was not involved in the culling, died on November 23.

His was the human-to-human transmission case confirmed by the WHO. The others all recovered.

"All the evidence suggests that the outbreak within this family does not pose a broader risk," the WHO spokesman told Reuters. "But there is already heightened surveillance and there is a need for ongoing vigilance."

It was the first human-to-human case of H5N1 transmission in Pakistan, while others have been confirmed in Indonesia and Thailand in similar circumstances of what the WHO calls close contacts in a very circumscribed area.

Global health experts fear the virus -- which has killed 211 people out of 343 infections reported since 2003 -- could mutate into a form that spreads easily from one person to another, possibly triggering a pandemic that could kill millions.

[Preciouslife1]

Sinovac reports positive Phase II influenza vaccine results

Datamonitor Pharmaceutical and HealthWire - Dec. 26, 2007
http://www.therapeuticsdaily.com/news/article.cfm?contenttype=sentryarticle&contentvalue=1657367&channelID=31

China-based Sinovac Biotech has announced positive top-line results of completed, stratified, randomized, double-blind Phase II clinical trial of its pandemic influenza whole viron inactivated vaccine. The trial was designed to assess the safety and immunogenicity of the vaccine.

The Phase II trial of the pandemic influenza (H5N1) whole viron inactivated vaccine included 402 volunteers, between the ages of 18 and 60, who were each vaccinated with two doses of 5ug, 10ug or 15ug. The preliminary results of the trials suggested that each of the three dosages can induce varying degrees of immune response. The trial result did not show any serious adverse reaction among volunteers, suggesting the vaccine's good safety profile.
Weidong Yin, chairman, president and CEO, said: "We are very pleased with the achievements of our team that led to the development of a pandemic influenza vaccine.
After Phase II clinical trials of the whole viron H5N1 vaccine, the vaccine dosages and schedule can now be determined. This accomplishment is a further step towards providing an effective prevention option for the government in the event of a future influenza pandemic."

[Preciouslife1]

One dead, five infected with bird flu in Pakistan
Sun Dec 16, 2007 12:18pm EST

http://www.reuters.com/article/healthNews/idUSL1530586720071216?sp=true

ISLAMABAD (Reuters) - Pakistan has recorded its first human death from bird flu and five other people have been infected with the deadly H5N1 virus, the Health Ministry said on Saturday.
Health officials are also investigating a second death from suspected bird flu.
The cases were reported in the North West Frontier Province in late October.

"Six cases were found positive for H5N1 avian influenza virus," the Ministry of Health said in a statement. "Five of them have fully recovered."

The statement said one man with confirmed H5N1 died in hospital and his brother, who had not been tested, has also died. The second death is being investigated.

While Pakistan has registered cases of bird flu in poultry this is the first time it has been reported in humans, Federal Health Secretary Khushnood Akhtar Lashari told Reuters.

The first poultry case appeared in early 2006.

Lashari said no more poultry or human cases had been detected in the last two weeks. A World Health Organisation (WHO) team will arrive in Pakistan in the next few days.

It has so far appeared difficult for humans to contract H5N1, which is mainly an animal disease. But experts fear the strain could spark a global pandemic and kill millions if it mutates to spread more easily.

The Geneva-based WHO said it was aware of eight suspected human cases of H5N1 bird flu in Pakistan's Peshawar region.

"These cases were detected following a series of culling operations in response to outbreaks of H5N1 in poultry. One of the cases has now recovered and a further two suspected cases have since died," the United Nations agency said in a statement on its Web site www.who.int.

WHO spokesman Gregory Hartl said the first known person infected with H5N1 in Pakistan was a man who had worked as a poultry culler, who died as a result of the virus.

Two of his brothers had also fallen ill, one of whom subsequently died. It has not been confirmed whether the second death occurred as a result of the man caring for his brother or from exposure to infected birds kept in their home, Hartl said.

"The details are not 100 percent clear ... The virus has not been characterized yet," Hartl said, referring to analysis on whether the bird flu strain had mutated. "There are several cases within one family. We don't know how the family members contracted the virus."

The Pakistani cases bring to nearly 350 the number of people worldwide who are known to have contracted the H5N1 virus, which has killed more than 200 people since 2003.

Indonesia has had the heaviest toll, with 115 human cases including 92 deaths, followed by Vietnam with 100 cases and 46 deaths, according to WHO figures.

[Preciouslife1]

Massive bird flu cull launched

http://news.bbc.co.uk/1/hi/uk/7106304.stm

Another 68,000 birds are to be culled in Suffolk

A further 68,000 birds are being slaughtered on a sixth poultry farm in Suffolk in a bid to control the outbreak of bird flu in the region.
Defra officials say the latest cull - more than double the other five combined - is precautionary and falls within the existing surveillance zone.

The move comes amid fears that workers at the farm have travelled to other farms that are deemed a flu risk.

More than 28,600 turkeys, ducks and geese have already been slaughtered.

Acting Chief Veterinary Officer Fred Landeg said the move is based on new information about exposure risk and stressed that all poultry keepers must immediately report any signs of the disease.

Employee movement

A spokeswoman at the Department for the Environment, Food and Rural Affairs (Defra) said the latest farm is owned by the same company that operates Redgrave Park Farm near Diss, on the Norfolk-Suffolk border, where the virus was first detected earlier this month.

The spokeswoman said employee routes between the farms are being monitored for signs of the disease spreading.

A 3km protection zone and 10km surveillance zone were immediately set up, and remain in place.

The sixth cull will include 56,000 ducks, 9,000 turkeys and 3,000 geese.

Bird flu has been confirmed at both the original site of the outbreak and one other nearby site owned by the same company.

The latest premises to be added to the cull list supplied poultry to the farm at the centre of the outbreak, but this latest move is more linked to employee movement, the spokeswoman said.

Tests negative

On Tuesday it was confirmed that turkeys culled at two other farms over fears they had been exposed to the disease tested negative.

These were Stone House, in West Harling, and Bridge Farm, in Pulham, both in Norfolk.

On Monday, tests showed birds at Hill Meadow Farm in Knettishall on the Norfolk/Suffolk border had been infected with H5N1, a strain of the virus at the centre of fears that it may mutate and cause an epidemic among humans.

Another of the farms, Grove Farm, Botesdale, Suffolk was upgraded to a slaughter site on suspicion of having the disease last week, after dozens of birds were found dead by officials.

But initial tests on 5,500 turkeys slaughtered found the premises were free of disease.

A variant of the deadly H5N1 strain is capable of being transmitted to humans.

[Preciouslife1]

Indonesian girl did not die of bird flu: official

JAKARTA (AFP) — A young Indonesian girl who died at the weekend on the island of Sumatra was not infected with bird flu, a health ministry official said Monday.

The 10-year-old was admitted to hospital on Saturday suffering symptoms that led doctors to suspect she could be carrying the H5N1 virus, which has killed 88 people in Indonesia, the highest number anywhere in the world.

"The test result is negative," said Haris Sugiantoro, an official at the health ministry's bird flu information centre.

If the ministry result is positive, a second test is carried out at a separate laboratory before a patient is confirmed as infected with bird flu in Indonesia.

http://afp.google.com/article/ALeqM...Z44gDktG8uuCKeg

[Preciouslife1]

Insights Into Cell Specificity Of Human Vs. Avian Viruses

http://www.medicalnewstoday.com/articles/85150.php

Researchers have identified which sites and cell types within the respiratory tract are targeted by human versus avian influenza viruses, providing valuable insights into the pathogenesis of these divergent diseases. The report by van Riel et al, "Human and avian influenza viruses target different cells in the lower respiratory tract of humans and other mammals," appears in the October issue of The American Journal of Pathology and is accompanied by a commentary and highlighted on the cover.

Differences in cellular expression of target molecules correspond to host specificity of influenza viruses.
They also define which organs or tissues are infected within the host. For example, highly pathogenic H5N1 avian influenza virus targets cells deep within the lower respiratory tract whereas human influenza virus is thought to target cells of the upper respiratory tract, including the trachea.

To better elucidate the differences between low and highly pathogenic avian influenza virus versus human influenza virus, researchers led by Dr. Thijs Kuiken of Erasmus MC, Rotterdam, The Netherlands, used a technique called virus histochemistry. This method examines the attachment pattern of influenza virus to isolated respiratory tissues, thus identifying the cells targeted by the virus.

When human viruses were tested, both attached strongly to the trachea and bronchi, but virus binding to the bronchioles and alveoli (deeper within the lung) was less abundant in comparison. In contrast, viral attachment of avian viruses was rare in the trachea but more abundant in the bronchioles and alveoli. Further, the cellular targets in the alveoli also differed: human virus preferred type I pneumocytes whereas avian virus bound type II pneumocytes and alveolar macrophages. Interestingly, low and highly pathogenic avian influenza viruses attached to the same cell types, demonstrating that factors other than binding ability must contribute to the pathogenicity.

These data are consistent with the differences in human disease presentation, with human influenza causing tracheobronchitis and highly pathogenic avian influenza causing severe pneumonia. But which animal models are the best for studying the disease in humans" To answer this question, the authors next assessed the pattern of virus attachment in animal models used for influenza studies. Of several mammals tested, ferrets, cats, and pigs most closely resembled the human patterns of virus attachment for avian influenza viruses, thus demonstrating their usefulness as models of infection and disease.

These studies "improve our understanding of the pathogenesis of human respiratory tract disease from both human and avian influenza A virus infection," state the authors. Combined with the results obtained with different animal models, they may lead to a better understanding of the factors that are critical for virus binding and infection, enabling the future development and testing of feasible control strategies.

[Preciouslife1]

Avian Flu -- 1918 and Today -- Protein Enhances Lethality Of Virus

http://www.sciencedaily.com/releases/2007/10/071010120543.htm

Often called the most devastating epidemic in the recorded history of the world, the 1918 influenza virus pandemic was responsible for more than 40 million deaths across the globe. The incredible lethality of the 1918 flu strain is not well understood, despite having been under intense scrutiny for many years. Now, a new study published by Cell Press in the October issue of the journal Cell Host & Microbe unravels some of the mystery surrounding the devastating 1918 pandemic and provides key information that will help prepare for future pandemics.

It is relatively rare for an influenza virus to be virulent enough to cause death in healthy humans. Many deaths associated with influenza are caused by the combined influence of viral disease and the following secondary bacterial infection. Although the 1918 pandemic strain was one of the few influenza viruses capable of killing healthy victims on its own, the majority of fatal cases from the "Spanish Flu" can be attributed to secondary bacterial pathogens rather than primary viral disease. This important interaction between influenza viruses and bacteria is not well understood.

Dr. Jonathan A. McCullers from the Department of Infectious Diseases at St. Jude Children's Research Hospital in Memphis, Tennessee and colleagues examined this interaction by studying a newly discovered influenza A virus (IAV) protein, called PB1-F2. The gene encoding PB1-F2 is present in nearly all IAVs, including highly pathogenic avian IAVs that have infected humans and the IAV associated with the 1918 pandemic. "PB1-F2 was recently shown to enhance viral pathogenicity in a mouse infection model, raising questions about its effects on the secondary bacterial infections associated with high levels of influenza morbidity and mortality," explains Dr. McCullers.

The researchers found that expression of PB1-F2 increased the incidence of and exacerbated secondary bacterial pneumonia in a mouse model. Intranasal delivery of a synthetic peptide derived from a portion of PB1-F2 had the same effects. Further, an influenza virus engineered to express a version of PB1-F2 identical to that in the 1918 pandemic strain was more virulent in mice and led to more severe bacterial pneumonia, explaining in part both the unparalleled virulence of the 1918 strain and the high incidence of fatal pneumonia during the pandemic.

The finding that PB1-F2 promotes lung pathology in primary viral infection and secondary bacterial infection also provides critical information for the future. "Given the importance of IAV as a leading cause of virus-induced morbidity and mortality year in and year out, and its potential to kill tens of millions in the inevitable pandemic that may have its genesis in the viruses currently circulating in southeast Asia, it is imperative to understand the role of PB1-F2 in IAV pathogenicity in humans and animals," says Dr. McCullers. "These findings also reinforce the recent suggestion of the American Society for Microbiology that nations should stockpile antibiotics for the next pandemic, since many of the deaths during this event are likely to be caused by bacterial super-infections."

Reference: McAuley et al.: "Expression of the 1918 Influenza A Virus PB1-F2 Enhances the Pathogenesis of Viral and Secondary Bacterial Pneumonia." Publishing in Cell Host & Microbe 2, 240--249, October 2007. DOI 10.1016/j.chom.2007.09.001

The researchers include Julie L. McAuley of Department of Infectious Diseases, St. Jude Children's Research Hospital in Memphis; Felicita Hornung of Laboratory of Viral Diseases, National Institute of Allergy and Infectious Diseases in Bethesda; Kelli L. Boyd of Animal Resources Center, St. Jude Children's Research Hospital in Memphis; Amber M. Smith of Department of Mathematics, University of Utah in Salt Lake City; Raelene McKeon of Department of Infectious Diseases, St. Jude Children's Research Hospital in Memphis; Jack Bennink and Jonathan W. Yewdell of Laboratory of Viral Diseases, National Institute of Allergy and Infectious Diseases in Bethesda; and Jonathan A. McCullers of Department of Infectious Diseases, St. Jude Children's Research Hospital in Memphis.

This work was supported by the NIH the NIAID intramural research program, and the American Lebanese Syrian Associated Charities (ALSAC).

[Preciouslife1]

Vical Demonstrates Dose-sparing Of Protein-based H5N1 Influenza Vaccine With Vaxfectin(TM) Adjuvant

http://www.medicalnewstoday.com/articles/85081.php

Vical Incorporated (Nasdaq: VICL) announced that data from a study in mice demonstrated the potential of its patented Vaxfectin(TM) adjuvant to be used as a dose-sparing agent with a protein-based H5N1 pandemic influenza vaccine currently stockpiled by the U.S. government. Dose-sparing ability could be critical in extending limited vaccine supplies to protect the greatest number of people in the event of a pandemic influenza outbreak. Alain Rolland, Pharm.D., Ph.D., Vical's Senior Vice President of Product Development, presented the data at the World Vaccine Congress (Lyon, France, October 8 - 10).

Vaxfectin(TM)-formulated Measles DNA Vaccine

The company also announced that a measles DNA vaccine formulated with the company's Vaxfectin(TM) adjuvant elicited sustained protective levels of neutralizing antibodies in infant (6 - 10 week old) nonhuman primates confirmed by complete protection following challenge one year after intradermal vaccination, with no clinical signs of disease and no culturable virus after challenge.
In May, the company announced similar results in juvenile (1 - 2 year old) nonhuman primates. Both measles studies were conducted in collaboration with Diane E. Griffin, M.D., Ph.D., Alfred and Jill Sommer Professor and Chair of Molecular Microbiology and Immunology, Johns Hopkins Bloomberg School of Public Health, under a grant from the Bill and Melinda Gates Foundation.

"We continue to expand the database demonstrating the dose-sparing and immunogenicity-enhancing capabilities of our Vaxfectin(TM) adjuvant," said Dr. Rolland, "as well as its potential safety and tolerability advantages. Our lead DNA vaccine candidate against H5N1 influenza, formulated with Vaxfectin(TM), provided 100% protection in mice and ferrets against lethal challenges, and is currently in Phase 1 human testing. We are encouraged by the recent influenza and measles data, and look forward to further evaluation of Vaxfectin(TM)."

Study Details

In the recent influenza study, mice were vaccinated with U.S. government-supplied H5N1 vaccine (rgA/Vietnam/1203/2004 - BEI Resources, Catalog No. NR-4143), with or without the Vaxfectin(TM) adjuvant, and evaluated for antibody responses by Enzyme-Linked ImmunoSorbent Assay (ELISA). After a single injection, the Vaxfectin(TM)-formulated vaccine yielded five-fold higher antibody responses at the same dose as the unformulated vaccine, and comparable or better antibody responses at one-third the dose of unformulated vaccine. After a second injection, the Vaxfectin(TM)-formulated vaccine yielded nine-fold higher antibody responses at the same dose as the unformulated vaccine, and five-fold better antibody responses at one-third the dose of the unformulated vaccine.

In an earlier influenza study, the company demonstrated that the Vaxfectin(TM) adjuvant significantly boosted the immune response to a protein-based seasonal influenza vaccine. Mice were vaccinated with trivalent inactivated influenza vaccine (Sanofi-Pasteur Fluzone(R) 2005-2006 Formula commercial product), with or without the Vaxfectin(TM) adjuvant, and evaluated for antibody responses through hemagglutination inhibition (HI) titers. The Vaxfectin(TM)-formulated vaccine yielded significantly higher antibody responses than the unformulated vaccine at the same dose as well as a dose-sparing effect.

In the recently completed measles study in infant nonhuman primates, neutralizing antibody levels exceeded the accepted protection threshold prior to the second injection at Week 4, peaked at Week 8, and remained above the threshold at least through the 20-week follow-up period. Animals were challenged by intratracheal inoculation after one year, resulting in complete protection of all vaccinated animals. None of the vaccinated animals had disease symptoms or culturable levels of measles virus, in contrast to negative control animals which all had rashes and positive virus cultures. No adverse events related to the vaccination were observed.

About Vical

Vical researches and develops biopharmaceutical products based on its patented DNA delivery technologies for the prevention and treatment of serious or life-threatening diseases. Potential applications of the company's DNA delivery technology include DNA vaccines for infectious diseases or cancer, in which the expressed protein is an immunogen; cancer immunotherapeutics, in which the expressed protein is an immune system stimulant; and cardiovascular therapies, in which the expressed protein is an angiogenic growth factor. The company is developing certain infectious disease vaccines and cancer therapeutics internally. In addition, the company collaborates with major pharmaceutical companies and biotechnology companies that give it access to complementary technologies or greater resources. These strategic partnerships provide the company with mutually beneficial opportunities to expand its product pipeline and address significant unmet medical needs. Additional information on Vical is available at http://www.vical.com.

This press release contains forward-looking statements subject to risks and uncertainties that could cause actual results to differ materially from those projected, including: whether Vical or others will continue evaluation of Vaxfectin(TM) as an adjuvant for vaccines against influenza or measles; whether Vaxfectin(TM) will be used as a dose-sparing agent with conventional influenza vaccines against seasonal or pandemic influenza strains; whether Vical or others will continue development of the pandemic influenza or measles DNA vaccine candidates; whether H5N1 or other strains of influenza will emerge as pandemic threats; whether the company's DNA vaccine candidate will be effective in protecting humans against H5N1 or other strains of influenza; whether the measles vaccine will be effective in protecting juvenile or infant humans against infection or disease; whether the influenza or measles vaccines or any other product candidates will be shown to be safe and effective; the timing, nature and cost of clinical trials; whether Vical or its collaborative partners will seek or gain approval to market the influenza vaccine or any other product candidates; whether Vical or its collaborative partners will succeed in marketing the influenza vaccine or any other product candidates; and additional risks set forth in the company's filings with the Securities and Exchange Commission. These forward-looking statements represent the company's judgment as of the date of this release. The company disclaims, however, any intent or obligation to update these forward-looking statements.

Vical Incorporated
http://www.vical.com

[Preciouslife1]

Researchers Identify Key Step Bird Flu Virus Takes To Spread Readily In Humans

http://www.medicalnewstoday.com/articles/84869.php

Since it first appeared in Hong Kong in 1997, the H5N1 avian flu virus has been slowly evolving into a pathogen better equipped to infect humans. The final form of the virus, biomedical researchers fear, will be a highly pathogenic strain of influenza that spreads easily among humans. In a new study a team of researchers from the University of Wisconsin-Madison report the identification of a key step the virus must take to facilitate the easy transmission of the virus from person to person. The study, published today in the journal PLoS Pathogens, details how a team of researchers led by virologist Yoshihiro Kawaoka of the UW-Madison School of Veterinary Medicine has identified a single change in a viral protein that facilitates the virus' ability to infect the cells of the upper respiratory system in mammals. This adaptation could allow the virus to infect a wider range of cell types and spread more easily, potentially setting the stage for a flu pandemic.

"The viruses that are in circulation now are much more mammalian-like than the ones circulating in 1997," says Kawaoka, an internationally recognized authority on influenza. "The viruses that are circulating in Africa and Europe are the ones closest to becoming a human virus." There are other yet-to-be-determined changes required for the virus to become a human pathogen of pandemic proportions, Kawaoka explains, but establishing itself in the upper respiratory system is necessary as that enables easy transmission of the virus through coughing and sneezing. As its name implies, bird flu first arises in chickens and other birds. Humans and other animals in close contact with the birds may become infected as the virus begins to adapt to new host animals, a process that may take years as small changes accumulate. Over time, an avian virus may gather enough genetic change to spread easily, as experts believe was the case with the 1918 Spanish flu, an event that killed at least 30 million people worldwide.

To date, more than 250 H5N1 human infections worldwide have been reported. Of those, more than 150 have been fatal, but so far efficient human-to-human transmission has not occurred. Most infections have occurred as a result of humans being in close contact with birds that have the virus, such as chickens.

According to Kawaoka, the avian virus can reside in the lungs of humans and other mammals as the cells of the lower respiratory system have receptors that enable the virus to establish itself. Temperatures in the lungs are also higher and thus more amenable to the efficient growth of the virus.

The new study involved two different viruses isolated from a single patient -- one from the lungs, the other from the upper respiratory system. The virus from the upper respiratory system exhibited a single amino acid change in one of the key proteins for amplification of influenza virus genes.

The single change identified by the Wisconsin study, Kawaoka says, promotes better virus replication at lower temperatures, such as those found in the upper respiratory system, and in a wider range of cell types.

"This change is needed, but not sufficient," Kawaoka explains. "There are other viral factors needed to cause a viral pandemic" strain of bird flu. However, Kawaoka and other flu researchers are convinced it is only a matter of time, as more humans and other animals are exposed to the virus, before H5N1 virus takes those steps and evolves into a virus capable of causing a pandemic.

In addition to Kawaoka, authors of the new PLoS Pathogens study include Masato Hatta, Yasuko Hatta, Jin Hyun Kim, Shinji Watanabe of the UW-Madison School of Veterinary Medicine; Kyoko Shinya of Japan's Tottori University; Tung Nguyen of the Vietnamese National Centre for Veterinary Diagnostics; Phuong Song Lien of the Vietnam Veterinary Association; and Quynh Mai Le of the Vietnamese National Institute of Hygiene and Epidemiology. The work was funded by grants from the U.S. National Institutes of Health and the Japan Science and Technology Agency.

CITATION: Noda T, Ebihara H, Muramoto Y, Fujii K, Takada A, et al. (2006) Assembly and budding of Ebolavirus. PLoS Pathog 2(9): e99. DOI: 10.1371/journal.ppat.0020099

[Biowatch]

Quick test for bird flu devised
Scientists in Singapore say they have created a hand-held device that can detect the deadly H5N1 bird flu virus within 30 minutes.

They say it is able to isolate, purify and amplify the viral DNA from throat swab samples and then identify it.

The hopes are that the kit could contain any outbreak much easier, as other available tests take at least several hours to produce results.

Nearly 200 people have died from the H5N1 strain worldwide.

'440% faster'

Writing in the journal Nature Medicine, the team of scientists from Singapore's Institute of Bioengineering and Nanotechnology says the new kit will be able to test people rapidly at the point of infection or at transport centres.

They say the device is "equally sensitive and is 440% faster and 2,000-5,000% cheaper" than commercially available tests.

The so-called mini-lab will be especially useful where basic health resources are lacking, the scientists say.

They say the prototype has delivered accurate results within 28 minutes when tested on samples of the H5N1 virus.

The virus is highly contagious to birds. Although experts say the disease cannot easily jump the species barrier, there are fears it will mutate into a virus that can be transmitted from human to human.
Story from BBC NEWS:
http://news.bbc.co.uk/go/pr/fr/-/2/hi/asia-pacific/7009750.stm

Published: 2007/09/23 22:21:28 GMT

[DewDiligence]

New Vaccine May Beat Bird Flu Before It Starts

http://news.yahoo.com/s/nm/20070809/hl_nm/birdflu_vaccine_dc_1

>>
By Maggie Fox, Health and Science Editor
09-Aug-2007

Researchers studying bird flu viruses said on Thursday they may have come up with a way to vaccinate people ahead of a feared influenza pandemic.

Experts have long said there is no way to vaccinate people against a new strain of influenza until that strain evolves. That could mean months or even years of disease and death before a vaccination campaign began.

But a team at the National Institute of Allergy and Infectious Diseases in Maryland and the Emory University School of Medicine in Atlanta said they may have found a short-cut.

The vaccine might protect people against the mutation that would change the H5N1 avian flu virus from a germ affecting mostly birds to one that infects people easily, the NIAID's Dr. Gary Nabel and colleagues report in Friday's issue of the journal Science.

"What Dr. Nabel and his colleagues have discovered will help to prepare for a future threat," NIH Director Dr. Elias Zerhouni said in a statement.

…To better try and understand the threat, researchers have studied various strains of H5N1 and compared them to the worst known flu virus ever -- the H1N1 virus that killed anywhere between 50 million and 100 million people in 1918 and 1919.

They found a tiny mutation that makes one strain of the H1N1 virus more easily infect birds, and another one prefer humans. It lies in the part of the virus that attaches to cells in the respiratory tract.

They then made the same alteration in an H5N1 virus, and vaccinated mice with some of this genetically engineered H5N1 DNA.

They found one immune system protein called an antibody that could neutralize both types of H5N1 -- H5N1 adapted to birds, and an engineered form that would in theory prefer humans.

If a vaccine could be designed to protect people against viruses with this mutation, it might be used to vaccinate populations before a pandemic even started, the researchers said.

"Now we can begin, preemptively, to consider the design of potential new vaccines and therapeutic antibodies to treat people who may some day be infected with future emerging avian influenza virus mutants," NIAID director Dr. Anthony Fauci said in a statement. "This research could possibly help to contain a pandemic early on."

Companies are already making human vaccines against H5N1, but they are designed using the current strain of the virus, which does not easily infect people. Scientists fear they are a poor match for any form of the virus that may eventually infect people.
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[Biowatch]

Birds with H5N1 FLU IN EUROPE:

http://www.dw-world.de/dw/article/0,2144,2671360,00.html

[DewDiligence]

Tamiflu Stockpile Could Halve Pandemic-Flu Deaths

http://yahoo.reuters.com/news/articlehybrid.aspx?storyID=urn:newsml:reuters.com:20070622:MTFH07962_2...

>>
Fri Jun 22, 2007 2:47 AM ET

GENEVA, June 22 (Reuters) - Using antiviral Tamiflu could halve the potential death toll from an influenza pandemic if it was used both to treat and prevent the disease, its maker Roche said on Friday.

Research presented by Beate Sander of the University of Toronto, Canada, showed a stockpile of Tamiflu sufficient to cover 65 percent of a country's population could cut deaths by approximately half, Roche said.

Tamiflu is seen as one of the best defences against a possible bird flu pandemic. It is recommended by the World Health Organisation as a first-line defence, and governments and are stockpiling the drug.

Some governments are now planning stockpiles sufficient to will allow them to provide Tamiflu preventatively to people who have been in close contact with infected individuals, Roche said.

"The reality is that country stockpiles of Tamiflu are limited and are targeted at treatment only rather than treatment and prevention," the Roche statement said.

"However, some governments are now planning for sufficient antiviral stockpiles that will allow them to provide Tamiflu preventatively to close contacts of infected individuals, it said."

Details were presented at an influenza conference in Toronto.
<<

[DewDiligence]

How Dr Chan Intends to Defend the Planet from Pandemics

http://www.economist.com/world/international/displaystory.cfm?story_id=9340488

>>
The new powers vested in a UN agency's boss should, in theory, cut the risk of killer diseases raging round the world

Jun 14th 2007

With its big electronic screens and global satellite links, the command centre feels like the heart of a vast military campaign. Every morning, there are strategy sessions to mull the latest intelligence, and rapid-response teams are sent to remote places at the commander's bidding.

In this case, the control room answers not to any general, but to the World Health Organisation (WHO)—the Geneva-based United Nations agency whose job is to monitor and respond to infectious diseases. In recent years, it has nipped in the bud over six dozen outbreaks that could have led to global crises. Unless outbreaks are spotted early, and virus strains shared with researchers worldwide, there is a recurring risk of a pandemic similar to the strains of influenza which caused havoc over the past century (see table).

That may sound obvious, but in practice, countries don't always help the WHO. In 2002, when the respiratory disease dubbed SARS emerged in China, the authorities hid the early signs for fear of hurting trade and tourism. More recently, Indonesia has been mired in a more intractable dispute—raising hard questions about the balance of economic power in the world.

Last year, the Indonesians stopped giving the WHO samples of the H5 virus which is responsible for avian flu, a disease that has forced a mass slaughter of poultry in many countries and could, if it mutates, cause a deadly epidemic among humans. Indonesia won some sympathy for its complaint that it was giving away precious intellectual property, while it might well be unable to afford the vaccines which are then developed. There was little the WHO could do in response.

However the agency's hand will be strengthened by a treaty that enters force on June 15th. The new “international health regulations” (IHRs) oblige governments to co-operate with Margaret Chan, the WHO's director-general, and report potential pandemics at once. If it succeeds, this could lead to a “good-governance revolution” in disease prevention, says David Fidler of Indiana University.

But will it work? Sceptics are not short of arguments. The new system requires countries to do a lot of things to improve public health, but provides no money. Implementing the treaty could prove hard in federal states like Canada and the United States, adds Kumanan Wilson of the University of Toronto; some of the actions required by the IHRs are handled at state or provincial level. Even so, the IHRs have one advantage over treaties like the Kyoto protocol on climate change. At least in the short term, Kyoto imposes heavy costs on some countries that are hard to explain to voters. But every country has an immediate, obvious interest in avoiding pandemics. That, in principle, could put a great deal of power in Dr Chan's hands.

The new treaty commits countries to tell her within 24 hours of any emerging global health threat, something they have often failed to do. In a break with normal UN practice, the WHO will no longer be required only to rely on data from member governments: it can now use non-government sources, including the press and the internet, in its surveillance. If a country tries to hide vital data about a potential pandemic, Dr Chan can override national sensitivities and ring the alarm bells.

That sounds promising, but it does not quite deal with the problem raised by Indonesia. Poor countries, where most potential pandemics start, rarely have the health facilities or vaccine-making capacity to combat a serious outbreak on their own; they rely on external help and vaccine imports. They complain that big firms in rich countries are exploiting their vulnerability. Indonesian officials put it bluntly: why should they hand over precious virus strains when the resultant vaccine may never benefit their people?

The Indonesians have a point. It is true that most of the factories that make pandemic vaccines are located in rich countries, and those plants cannot make enough to cover even the rich world's needs. And in previous global health panics, it has been obvious that rich states think of their own voters first. So at a WHO assembly in May, rich countries agreed that the poor must have access to life-saving vaccines in the event of a pandemic; Indonesia duly agreed to share its virus samples again. On June 13th Dr Chan announced plans to create a global stockpile of avian flu vaccine with the help of donations from GlaxoSmithKline, a British drugs firm, and others.

Fine, but how exactly any strategic stockpile will be split up during a global pandemic remains a mystery. The new rules do not offer much help on that front.

What Indonesia and other poor states really want is to have vaccine-making units within their borders. The WHO has helped a few poor countries to start such plants, but the technology involved is tricky. Not every country in the world can expect to have such factories; and those that do may well resist the idea of helping rival states. As Laurie Garrett of America's Council on Foreign Relations notes, Indonesian politicians would balk at sharing vaccines with Papua New Guinea. That explains why stockpiling and building new factories are partial answers at best to the global challenge.

Perhaps the best reason to take the IHRs seriously is that by making it harder for governments to hide pandemic data, they make innovation more likely. And innovation is desperately needed: today's vaccines cannot be made in the volume needed for the whole world, and they cannot keep up with the evolution of some virus strains. But as Joseph Hogan of GE, an industrial firm with a health division, points out, smarter vaccines and more efficient manufacturing may solve that problem. Vijay Samant of Vical—one of several firms now investing heavily in a new generation of pandemic technology—also welcomes the increased powers for Dr Chan and her agency. “Without access to the latest strains, researchers can't come up with new vaccines,” he argues. Dr Chan faces a big job, and big expectations.
<<

[DewDiligence]

FDA Finalizes Plan to Speed Flu-Vaccine Development

http://news.yahoo.com/s/nm/20070531/hl_nm/birdflu_fda_dc_1

>>
By Susan Heavey
Thu May 31, 5:29 PM ET

U.S. health regulators finalized guidelines on Thursday to speed development and production of vaccines against bird flu and seasonal strains of influenza.

The recommendations, proposed in March 2006, were designed to help manufacturers use newer technology that allows vaccines to be made faster once a strain of flu is identified, and to encourage more companies to get into the vaccine business.

"Having additional manufacturers of licensed influenza vaccines will enhance the capacity to produce more doses of seasonal influenza vaccines, as well as contribute to the nation's pandemic preparedness, one of our top priorities," said Jesse Goodman, director of the U.S. Food and Drug Administration's Center for Biologics Evaluation and Research.

GlaxoSmithKline Plc, Sanofi-Aventis, Novartis AG, and MedImmune Inc. currently make seasonal flu vaccines for the United States.

Sanofi won U.S. approval in April for a vaccine against the H5N1 bird flu virus, which health authorities fear could mutate and spread from person to person causing a global pandemic. Glaxo and Novartis are also working on bird flu vaccines.

Vaccine makers say they rely on the government to recommend inoculation and to provide contracts to purchase and stockpile their products.

International health officials have said a global shortage of flu vaccine is expected to last for at least five years.

Under the final recommendations, the FDA outlined steps for companies seeking approval using newer manufacturing methods such as cell cultures or advanced genetic technology.

Companies using either method would have to provide data from clinical trials, the FDA said. But companies looking to use new technology could test vaccines against various predictors of how well a product works and conduct trials later to confirm results.

Drugmakers currently rely on chicken eggs that incubate the virus for months, which experts say is unreliable.

The guidelines are posted on the FDA's Web site at www.fda.gov/cber/gdlns/trifluvac.htm and www.fda.gov/cber/gdlns/panfluvac.htm .
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[DewDiligence]

Flu Shots From Caterpillars May Shorten Production Time

http://www.msnbc.msn.com/id/18037806/

>>
The Associated Press
April 10, 2007

CHICAGO - Genetically engineered flu vaccine made from yellow striped caterpillars instead of hen eggs has been shown for the first time to keep people from getting the flu, scientists say.

The results are preliminary but suggest the insect method could be a quicker, easier alternative to the lengthy, antiquated egg-based procedure now used and lead to a more rapid response to a pandemic, the study authors say.

The experimental vaccine used in a study of 451 adults during the 2004-2005 flu season was designed to protect against three common influenza strains. Among participants who got a single high-dose injection, at least two-thirds had a strong immune response and none developed the flu that season.

More than half of those given a lower dose had a strong immune response and two got the flu. By contrast, seven patients who received a dummy vaccine got the flu.

Vaccine-related side effects were mostly mild and included pain at the injection site and headaches.

Larger studies are needed to confirm the results, but the findings suggest the caterpillar model could be a promising approach for preventing seasonal and pandemic flu, the authors said.

The research was funded by the vaccine’s maker, Protein Sciences Corp. The company designed the study with lead author Dr. John Treanor, a flu vaccine specialist at the University of Rochester in Rochester, New York.

The vaccine has been tested before, but “this is the first time we’ve seen protection using this approach,” Treanor said.

The results appear in Wednesday’s Journal of the American Medical Association.

Insect method is faster

The current method takes about nine months each year. It relies on hens laying millions of eggs. Live flu viruses injected into the eggs multiply, then the eggshells are broken, the viruses are inactivated and are treated to create vaccine.

The experimental method uses fall army worms, abundant caterpillars that are vulnerable to a bug virus. Scientists replace a gene from that virus with a flu virus gene, then inject it into the worm, where it makes more flu virus.

The process takes about a month less than the egg method and doesn’t involve using live flu virus, which can infect workers during the production process, Treanor said.

The study is important and suggests that the insect method is “a technology that’s worth pursuing,” said Dr. Tom Talbot, a Vanderbilt University vaccine expert who was not involved in the study.

The process appears to be less labor-intensive than egg-based manufacturing, and would be useful for people who are allergic to eggs, Talbot said. Only a small percentage of people have egg allergies, but that still amounts to probably hundreds of thousands of people who go unvaccinated, he said.
<<

[Biowatch]

Closing schools reduced flu deaths in 1918

Mon Apr 2, 5:46 PM ET

Cities that quickly closed schools and discouraged public gatherings had fewer deaths from the great flu pandemic in 1918 than cities that did not, researchers reported on Monday.

Decisive, immediate action can reduce the most acute effects of a pandemic, while allowing the population to build some natural immunity to the virus, the U.S. government study found.

Experts agree that a pandemic of some virus, most likely influenza, is almost 100 percent certain. What is not certain is when it will strike and which virus it will be.

The worst-case scenario is the 1918 flu pandemic, which killed tens of millions of people globally. Researchers are going through records to learn from the actions taken decades ago.

Dr. Richard Hatchett of the National Institute of Allergy and Infectious Diseases and colleagues studied 17 U.S. cities.

"Cities in which multiple interventions were implemented at an early phase of the epidemic had peak death rates about 50 percent lower than those that did not," they wrote in their report, published in the Proceedings of the National Academy of Sciences.

In Kansas City, no more than 20 people could attend weddings or funerals. New York mandated staggered shifts at factories. In Seattle, the mayor told people to wear face masks.

No single action worked on its own, the researchers found, it was the combination of measures that saved lives.

The World Health Organization has been urging countries to get ready for a pandemic. The H5N1 avian influenza is considered the most likely candidate to cause one.

So far, it has spread mostly in birds, across Asia and into Africa and Europe. But it sometimes infects people and has killed 170 people out of 288 known to have been infected.

LESSONS FROM PAST

It is constantly evolving and if it mutates in just the right way, it could spread easily from one person to another, causing widespread death and sickness.

No good vaccine would be available for months, and drugs that treat influenza are in very short supply.

So experts are looking at what they call non-pharmacologic interventions -- ways to prevent infection without drugs. They hope this can buy time while companies make and distribute vaccines and drugs.

Because the virus is spread by small droplets passed within about three feet (1 meter) from person to person, keeping people apart is considered a possible strategy.

Hatchett's study suggests this worked nearly a century ago.

"The first cases of disease among civilians in Philadelphia were reported on September 17, 1918, but authorities downplayed their significance and allowed large public gatherings, notably a citywide parade on September 28, 1918, to continue," they wrote.

"School closure, bans on public gatherings, and other social distancing interventions were not implemented until October 3, when disease spread had already begun to overwhelm local medical and public health resources," they added.

St. Louis authorities introduced "a broad series of measures designed to promote social distancing" as soon as flu showed up.

Philadelphia ended up with a peak death rate of 257 people per 100,000 population per week. St. Louis had just 31 per 100,000 at the peak.

When the cities relaxed their policies, death rates rose.

The U.S. government flu plan calls for similar measures, including allowing employees to stay home for weeks or even months, telecommuting and closing schools and perhaps large office buildings.


http://news.yahoo.com/s/nm/birdflu_cities_dc

[DewDiligence]

Scientists Hope Vigilance Stymies Avian Flu Mutations

http://www.nytimes.com/2007/03/27/health/27flu.html

>>
March 27, 2007
By DONALD G. McNEIL Jr.

Just exactly what is the bird flu virus doing?

The virus, H5N1, which was first isolated in humans in 1997, has not started a pandemic in a full decade of trying, so a few flu experts think it never will.

But the mainstream view is less optimistic. Viruses mutate constantly, many experts point out. And when one has already acquired the ability to jump species, occasionally spread from human to human and kill 60 percent of the people who catch it, it is far too early to dismiss it.

So even though the human death toll from H5N1 is still below 200, scientists around the world are racing to study the ways in which it might mutate to spread easily among humans.

The 1918 Spanish flu, they argue, was not even noticed until it had killed thousands. It might have been gathering virulence for years, hidden in the background of seasonal flu deaths.

Today’s H5N1 flu is probably changing more slowly, because health officials have been vigilant about attacking clusters of cases, which presumably wipes out the most dangerous strains. Whenever several human cases appear, even in remote villages in Indonesia or Egypt, local officials and World Health Organization teams move in to kill all the local poultry and dose all the humans with antiviral drugs — the so-called Tamiflu blanket strategy.

Each stifled outbreak robs the virus of the chance to carom wildly through dozens of human hosts as it does in a flock of chickens or ducks. That fends off what virologists most fear: gene-swapping in people infected with both human and avian flu.

But the Tamiflu blanket may not be able to smother every spark, especially if countries cannot get their poultry epidemics under control.

A human-bird hybrid strain has not yet been seen in nature. But if it did surface, that “would mean we might have a big problem on our hands,” said Dr. Nancy Cox, chief of the influenza branch of the Centers for Disease Control and Prevention.

Last year, Dr. Cox and colleagues created a hybrid in their lab between a human flu of the H3N2 strain and samples of the H5N1 virus collected from 1997 to 2004. They infected ferrets with it to see if it would spread to ferrets in the same cage or those in nearby cages. The hybrid strain proved less lethal and was transmitted only once after long contact.

But nature has a bigger laboratory than the C.D.C. does, and the agency’s director, Dr. Julie L. Gerberding, says the results do not mean that H5N1 cannot become more infectious. “They mean it’s probably not a simple process,” she said.

Dr. Anne Moscona, a flu expert at Weill Cornell Medical Center, was more emphatic in arguing that there is still reason to worry. “It would have been truly ominous if a monster virus had been created by these supersimple swaps,” she said. “But of three ferrets, one got the virus. Is 33 percent nothing?”

Geneticists at the University of California, Irvine, concluded that the H5N1 flu originated in Guangdong Province in Southern China, where millions of people and chickens live in close proximity. Guangdong is also believed to be the likely birthplace of previous flu strains — even if they later picked up names like “Hong Kong flu” — and to be where the SARS virus jumped from horseshoe bats to masked palm civets to humans.

But flus mutate incessantly wherever they move, and in viral samples from Asia, the Middle East and Africa, many individual changes that look potentially dangerous have been spotted.

In May 2005, for example, the virus in China escaped in migratory birds going north and traveled across Russia, Europe and Africa. It became known as the Qinghai strain after the lake in Northern China where thousands of ducks and geese were found dead. (The older strain in Southern China and Southeast Asia is sometimes called the Fujian strain.)

The Qinghai strain has a mutation known as PB2 E627K. (The abbreviation can be read this way: at position No. 627 on polymerase basic protein 2, the amino acid called glutamic acid, abbreviated by scientists as E, has been replaced by lysine, known as K.)

The change helps the virus grow at the temperatures found in human noses, which are cooler than the insides of birds’ intestines.

It is “characteristic of a gene that’s been in mammals,” said Dr. Robert G. Webster, a virologist at St. Jude Children’s Research Hospital in Memphis. “It says to me that it was in a mammalian species in China, and got back into ducks. But what species? We don’t know.”

The Qinghai strain has now reached about 50 countries.

To give a sense of how important such a tiny change can be: switching just one of the 1,255 amino acids in the SARS virus protein that attached to cells in the masked palm civet, a relative of the mongoose that is sold in wild-meat markets in Asia, allowed it to attach to human cells.

After that discovery, the Chinese government ordered that all the 10,000 civets in captivity in Guangdong be killed, thus probably wiping out the disease everywhere except in bats.

In avian flu, two mutations known to help viruses spread more easily — because they attach to the receptors in human noses and throats instead of those deep in the lungs — were found in outbreaks in Azerbaijan and Iraq in 2006. But those outbreaks were snuffed out.

Another mutation, increasingly common in Egypt, where the disease is still raging through poultry and occasionally infecting humans, is called M230I. Scientists do not know what it does, but its persistence is worrisome, says Henry L. Niman, a Pittsburgh biochemist who runs a Web site tracking the genetics of flu cases.

M230I is also found in typical annual flu strains like H1N1, H3N2 and influenza B; in H7 flus, which pass easily from birds to humans but usually cause nothing more serious than pinkeye; and in H3N8, the flu that has spread from dog to dog in many American kennels, often fatally.

All the human cases in Egypt with M230I have been fatal, Dr. Niman said, and those without it have not been, although that may be coincidence.

Mutations that confer resistance to Tamiflu have also been found in Egypt.

Any antiviral resistance is worrisome because the world still has very few weapons against the flu. H5N1 long ago became resistant to older “M2 inhibitors” like amantadine, possibly because farmers in China are suspected of feeding those drugs to their chickens in the late 1990s.

Tamiflu is in another class, known as neuraminidase inhibitors, including Relenza and peramivir.

After Tamiflu resistance was found in Egypt, the World Health Organization, moving to stave off panic, said the same change was seen in Vietnam years before. Still, the Vietnam cases led doctors to start doubling the typical Tamiflu dose, effectively halving the world’s stockpiles of it.

An American Navy research lab in Cairo found that two Egyptian cases had a dangerous mutation known as N294S even before they got Tamiflu. That implies that it exists in Egyptian poultry, though it has not been found yet.

Every flu virus is different, and it is impossible to predict exactly what constellation of changes will turn one into a pandemic strain.

Dr. Cox and Dr. Ruben Donis, the influenza branch’s chief virologist, said they would be most worried if they saw spontaneous human-avian crossovers like those they created, or if they saw multiple changes in the virus’s hemagglutinin gene, the attachment “spike” on the virus’s shell.

“We’re looking very, very carefully at the viruses that exhibit changes at the receptor binding pocket,” Dr. Cox said. “But it’s clear that these single changes don’t allow the virus to move from person to person efficiently.”

And even if H5N1 fails to become a plague, Dr. Webster of St. Jude in Memphis has what he styles his “hit list” of others waiting their turn.

They include H7N7, which infected 89 chicken industry workers in the Netherlands in 2003 but killed only one veterinarian; H9N2, which he says is in “every poultry house in Eurasia” and causes no symptoms but every once in a while jumps into immuno-suppressed people; and H2N2, which is in the wild bird population in the United States.
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[DewDiligence]

Poor Countries Seek Pact on Avian-Flu Vaccines

http://online.wsj.com/article/SB117486117267548356.html

>>
By NICHOLAS ZAMISKA
March 26, 2007

JAKARTA -- Earlier this year, Indonesia's health minister asked a stark question: What does her poor country get out of sharing bird flu samples with scientists and vaccine makers? This week, global and regional health authorities and scientists meeting here will try to hash out an answer.

Among the thorniest issues in the battle to protect the world against a bird-flu pandemic is how to ensure that vaccines are available to the people at greatest risk of catching the disease. In recent years, poorer countries such as Indonesia and Thailand have given samples of the H5N1 strain of bird flu they collect from sick and dying patients to laboratories and companies in richer countries, such as France and the U.S., to study and to develop life-saving vaccines.

But what they can get in return for sharing the virus has remained unclear. Even given best-case scenarios, the world's current manufacturers could produce only a fraction of the amount of vaccine that would be needed if a pandemic were to break out. And because the world's largest vaccine makers are in rich countries, far from Asia, where nearly all of the deaths have been, many have wondered privately whether the supplies would be hoarded at the expense of people closest to the source of the outbreak.

That is what prompted Indonesian Minister of Health Siti Fadilah Supari to ask her question, explicitly and publicly for the first time. She stopped sending the samples her government was collecting to the World Health Organization, leaving vaccine makers and laboratories without access to the most recent, and potentially useful, strains of the virus. The move was intended to protest what Indonesia felt was a one-way exchange, with little sign Indonesians would benefit from a vaccine made from a virus collected on its soil.

At the meeting, which opens today, officials from the WHO and health ministries in Asia, along with top influenza scientists, will focus on these issues. While many similar gatherings often have relatively predetermined outcomes, and officials convene merely to ratify an agreement that's already been endorsed, both sides agree the Jakarta meeting could result in a pact or a continuing conflict.

Nancy Cox, director of the influenza division at the U.S. Centers for Disease Control and Prevention in Atlanta, is one of the many attendees.

The Jakarta meeting is "very important," Dr. Cox said. "We really need to have more viruses from all the affected countries so we can compare and contrast what's happening so we can be as prepared as possible."

In an interview, Dr. Supari said: "We want a mechanism to ensure access to vaccines. "To make vaccines more accessible, more affordable to all of the countries, especially developing ones."

Dr. David Heymann, the WHO's representative for avian influenza, said one solution to the issue could involve the WHO soliciting funding to buy stockpiles of vaccine from manufacturers on behalf of developing countries. He said wealthier nations might have a direct incentive to contribute to such purchases as those vaccines could help contain an nascent pandemic if deployed quickly before it could spread.

"She has raised an issue that had to be addressed," said Dr. Heymann of Dr. Supari. But he added that if the meeting doesn't produce a solution, "we will have to use our moral authority...we will have to begin to talk about this as a threat to public health security." He added, "Nobody else is withholding viruses. She's the only one that's doing this."

When asked what prompted her to stop sharing her country's samples with the WHO, Dr. Supari said she worries ordinary Indonesians, as well as people in other developing countries, wouldn't have access to affordable vaccines if a pandemic breaks out.

She mentioned what she called a disheartening experience in 2005 when she approached Swiss drug giant Roche Holding AG to buy two million doses of the antiviral drug Tamiflu, Roche's blockbuster treatment for influenza that has been used on patients with bird flu. The company said it didn't have any available, she said.

"They said, 'Sorry, ma'am... the stocks have run out because several other countries bought everything,'" she recalled. The health minister said "I am worried about the next experience with the vaccine."

Roche said that it did take around 10 to 12 months for Indonesia's order to be filled. But Martina Rupp, a company spokeswoman, said that was only because Roche was in the process of meeting surging Tamiflu demand and had to fill orders "on a first come, first serve basis." Other countries placed orders earlier, she added.

Indonesia has had the highest number of human deaths from bird flu. World-wide, there have been at least 281 human cases since the virus re-emerged in 2003, according to the WHO. Indonesia has had 81 cases, of which 63 have been fatal.

"I didn't agree with the rules of the game, so I asked the WHO to please think about the developing countries like us," Dr. Supari said. "My country suffers from avian flu. We have lots of patients dying. When the other companies take advantage of the virus, I think this is just an ethical matter."

But the minister said WHO "is our global organization. Indonesia is also in this organization. WHO is not my enemy."
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[DewDiligence]

GSK’s Vaccine Provides Cross-Immunity

http://online.wsj.com

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LONDON March 5 (Dow Jones)--GlaxoSmithKline PLC's (GSK) pre-pandemic flu vaccine can protect against diverse strains of H5N1, the virus involved in recent outbreaks of bird flu, the company said Monday.

According to the results of two new studies, the experimental vaccine provides a significant level of cross-immunity, since it can recognize and kill a strain that differs from the one used in its formulation.

"This means that proactive administration of our pre-pandemic vaccine before or just after the start of the pandemic could help to substantially slow down the spread of disease," said Jean Stephenne, President of GlaxoSmithKline Biologicals, the drugmaker's vaccine unit.

In the first study, which tested 400 adults, the vaccine stimulated a strong immune response against the Indonesian strain of the virus, even with low levels of antigen - the substance that stimulates an immune response.

The results were achieved thanks to GlaxoSmithKline's own adjuvant system, or booster, which requires a significantly lower amount of antigen to raise a strong immune response. This could give the ability to produce very large quantities of the product for mass vaccination, according to the company.

The second study, carried out on ferrets, showed that the vaccine could protect against two different H5N1 flu strains, also at very low levels of antigen.

"Cross-immunity is certainly being driven by the adjuvant," said Rip Ballou, GlaxoSmithKline's vice president of clinical research and development, adding that rival experimental vaccines have shown limited cross-protection data.

Both Sanofi-Aventis SA (SNY) and Novartis AG (NVS) are developing pandemic vaccines.

GlaxoSmithKline's pre-pandemic vaccine has already been accepted for review by the European health regulator in January. However the company doesn't yet have a planned date for a marketing application in the U.S., Ballou said.

The pre-pandemic vaccine could be adapted for pandemic use once the virus responsible for any flu pandemic has been identified.

The E.U. regulator has already endorsed GlaxoSmithKline's mockup pandemic vaccine, Daronrix.

The European Medicines Agency's mockup application allows vaccine manufacturers to go through many of the stages of regulatory approval on the basis of one virus strain.

Once any actual pandemic strain has been identified, drug companies would then simply replace the mockup strain without having to go through the entire regulatory process from scratch.

The strain which GlaxoSmithKline used to develop Daronrix is derived from the H5N1 strain.
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[DewDiligence]

CHMP Approves NVS ‘Mock-Up’ Bird-Flu Vaccine

http://online.wsj.com

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By Anita Greil
02-23-07 0933ET

ZURICH (Dow Jones)--The European Union health regulator Friday recommended approval of a mock-up vaccine for the treatment of pandemic flu by Swiss drugmaker Novartis AG (NVS).

The Committee for Medicinal Products for Human Use is recommending to grant marketing authorization for Focetria, which is intended for the prevention of influenza during an officially declared pandemic situation, once the pandemic viral strain has been included in the vaccine.

It's the second time the agency is endorsing such a vaccine, having already recommended GlaxoSmithKline Plc's (GSK) product Daronrix in December.

…A mock-up application allows vaccine manufacturers to go through many of the stages of regulatory approval on the basis of one virus strain. Once the actual pandemic strain is identified, drug companies then simply replace the mock-up strain without having to go through the entire regulatory process from scratch.

"The availability of a pandemic influenza vaccine soon after the declaration of a pandemic is essential to reduce disease burden and deaths," said Joerg Reinhardt, chief executive of the company's vaccines and diagnostics, a division of Novartis.

Focetria would contain the pandemic influenza strain declared at the time of a pandemic along with the proprietary adjuvant MF59 developed by Novartis. Studies have shown that this adjuvant boosts the body's immune response to the vaccine's active ingredient. It can also extend vaccine supplies by allowing for smaller amounts of viral antigens to be used in each dose compared to vaccines without this additive.

…Novartis bought into the vaccine business last year by acquiring Chiron Corp. and has since made it a key pillar of its strategy, which also includes significant operations in prescription medicines and generics.

Novartis and GlaxoSmithKline have also developed a new vaccine manufacturing process that uses cell cultures rather than chicken eggs to produce antigens. The new technology is expected to reduce production time to meet demands of influenza outbreaks and to combat evolving strains of the virus, including avian influenza strains that are difficult to grow in eggs.

Novartis' cell culture-based vaccine Optaflu was submitted for E.U. regulatory approval in July 2006 and is currently in clinical studies in the United States.
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[DewDiligence]

Big Pharma Disagree re Commercial
Potential of Pre-Pandemic Vaccine

http://online.wsj.com/asia

>>
By Nicholas Zamiska
02-15-07 1632ET

Drug makers have developed a vaccine for the bird-flu strain that scientists fear could mutate and spark a global pandemic. Now regulators and companies are weighing whether or not to make it widely available before any outbreak occurs.

Girding for the possibility of a large-scale outbreak among humans of a highly lethal form of avian influenza, scientists have been working on a vaccine that could conceivably save millions of lives. In the past few years, big pharmaceutical companies such as GlaxoSmithKline PLC and Sanofi-Aventis SA have made steady progress. Governments already are stockpiling supplies of a vaccine that appears to work.

So far, the plan seems to be to use a vaccine only if an outbreak occurs. The vaccine has yet to get an endorsement from any regulatory agency for prepandemic use. Still, potential demand for such prepandemic protection was flagged last year, when fears of a bird-flu pandemic sent people around the world rushing to buy up supplies of Roche Holding AG's antiviral drug Tamiflu, which can be used to treat the disease. An effective vaccine could be just as important as Tamiflu, if not more important, in saving a person from avian influenza.

"We have calls from people saying, 'Can I buy it? Can I buy it?'" says Alain Bernal, a spokesman for Sanofi Pasteur, the vaccine unit of Sanofi-Aventis of France.

Experts say it wouldn't make sense to cut corners on a normal regulatory process, given that the threat is a hypothetical one at this stage. They also point out that production capacity is needed to make vaccines for seasonal influenza, which poses a more immediate threat.

The European Union is weighing the pros and cons of a prepandemic vaccine, says Marie-Paule Kieny, director of the initiative for vaccine research at the World Health Organization, which on Thursday began a two-day meeting in Geneva with vaccine makers from around the world that are working on a bird-flu product.

Possible advantages, she says, include people being primed before a pandemic and needing only a booster dose should an outbreak occur. On the other hand, dangers include adverse effects and whether a vaccine against the current virus would even be effective against a mutated form of the virus.

At Sanofi, Mr. Bernal says making bird-flu vaccine for a potential threat would cut into the company's production capacity for vaccines for seasonal flu, which kills an estimated 250,000 to 500,000 people world-wide every year. By contrast, the H5N1 strain of bird flu, the one that worries health authorities most, has infected at least 273 people, killing 166 of them, mostly in Asia, since the virus re-emerged in late 2003, according to the WHO.

Mr. Bernal says global vaccine-production capacity for seasonal influenza already is limited to an estimated 350 million doses a year, of which Sanofi Pasteur produces about half. "The real public-health need today is for seasonal flu," he says. "You either produce [vaccines for] seasonal flu or H5N1."

As a result, he says, the H5N1 vaccine "is not a vaccine that we want to sell to the public. We don't have a marketing strategy for this product," Mr. Bernal says. A committee of outside advisers to the U.S. Food and Drug Administration is scheduled to meet Feb. 27 to make recommendations on the safety and effectiveness of Sanofi's H5N1 vaccine.

In addition, the current H5N1 vaccine seems to require a high dose to offer protection, making production issues worse, says Anthony Fauci, director of the U.S. National Institute of Allergy and Infectious Diseases, which has been working with vaccine makers on an antidote for a government stockpile. "It's not going to be something you're going to see on the shelf for sure," Dr. Fauci says. "It will likely be strictly controlled."

What's more, public-health officials warn that using a vaccine for an outbreak that might never materialize could carry more risks than rewards. Even approved new vaccines involve a certain amount of risk, especially if administered on a large scale, and there is a "wariness of using a vaccine that might not even be necessary," says David L. Heymann, the director-general's acting representative for avian influenza at the WHO.

Bird flu has waxed and waned in the public spotlight for three years now, but scientists take it seriously as a pandemic threat. Currently the H5N1 virus passes occasionally from birds to humans, killing more than half of the people it infects (although that fatality rate may be lower if cases are going undetected). If the virus mutates to a form that could pass readily among people, it could take a massive toll.

The current vaccines are based on strains of the H5N1 bird-flu virus from recent years; should the virus mutate, as it would need to in order to spread among humans, it isn't clear that the vaccine would fully protect people against it. Still, some experts think the current vaccine probably would protect against severe illness and death, even if the victim still got sick. Governments are proceeding on that assumption, and millions of doses have been produced.

GlaxoSmithKline received approval from European drug regulators in December for one of its H5N1 vaccines, but only for use in the event of a pandemic, according to Alice Hunt, a spokeswoman in London for the company. Last month, the British drug company submitted another application for an H5N1 vaccine that could be used in advance of a pandemic.

Ms. Hunt says it is far too early to consider marketing that vaccine to consumers, since the company has only just submitted its application to the European regulator and is planning on submitting it to the U.S. FDA as well.

CSL Ltd., an Australian pharmaceutical company, announced last month that it had produced a safe, effective vaccine against H5N1. Australia's drug watchdog will soon review the company's application. CSL has no plans to market a version of the vaccine for general use, according to Rachel David, the company's spokeswoman.

Medical-products maker Baxter International Inc., of Deerfield, Illinois, is testing its H5N1 vaccine and has signed a deal with the British government to produce two million doses for a stockpile. Whether Baxter will ever market the vaccine directly to consumers is an open question, according to Deborah Spak, a spokeswoman for the company. "We are still under clinical evaluation and years away from receiving the approvals needed for commercialization," she says, adding that the company hasn't built sales of a bird-flu vaccine to consumers into any of its financial projections.

Some companies do say they see commercial potential in the vaccine. In November, the Swiss drug giant Novartis AG submitted its H5N1 vaccine to the European Medicines Agency in London for approval, according to Eric Althoff, a spokesman for the vaccine unit of the Swiss company. Mr. Althoff says he expects a response on that application this year.

Novartis believes that if that vaccine is approved, there is a potential commercial market for a prepandemic vaccine that would be sold to individuals and not just governments, he says.
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[DewDiligence]

GSK to Launch U.S. Bird-Flu Trial in 2Q07

http://online.wsj.com

>>
By Peter Loftus
02-07-07 1622ET

PHILADELPHIA (Dow Jones)--GlaxoSmithKline PLC (GSK) expects to begin North American patient trials of a proposed bird-flu vaccine during the second quarter.

The studies in the U.S. and Canada should last for about one year, after which Glaxo expects to apply for U.S. Food and Drug Administration approval of the vaccine, Jean Stephenne, president of GSK Biologicals, told Dow Jones Newswires this week at Glaxo's North American headquarters in Philadelphia. The timeline puts Glaxo's U.S. regulatory efforts for the vaccine behind its efforts in Europe, where it has already applied for regulatory approval.

A Glaxo spokeswoman said Wednesday the company expects to conduct two studies involving about 5,000 people. The trials will track safety and immune responses. Glaxo is still in talks with the FDA to finalize design of the studies.

The U.K. company last year announced a breakthrough in the worldwide effort to prepare for a potentially deadly avian-influenza pandemic. Glaxo said it had developed a vaccine that was effective in inducing strong immune responses in a study of 400 healthy adults in Belgium, and at relatively low dosages.

The Glaxo vaccine includes a proprietary additive, or adjuvant, that allows for smaller amounts of the vaccine's main ingredient, or antigen, than some prior bird-flu vaccines. The lower antigen amounts in each dose would make it easier to produce mass quantities of doses to cover large populations in preparation for a pandemic. Glaxo applied for European regulatory approval of the proposed vaccine in January.

But a filing of the proposed vaccine with the FDA probably wouldn't happen until 2008 because separate studies are needed. That is partly because Glaxo would supply the vaccine in North America from a plant in Canada, while the Belgian study used a vaccine produced in Germany, Stephenne said. The FDA views the Canadian-produced antigen as a "different product" from the one produced in Germany, even though it is essentially the same vaccine, Stephenne said.

…An older Glaxo bird-flu vaccine, called Daronrix, received a positive opinion from a European regulatory body in December. This vaccine uses an older adjuvant and is designed for use once a pandemic has officially been declared by WHO. The newer vaccine could be used in advance of a pandemic to bolster people's immune systems, and could also be modified for use once a pandemic has been declared.

Glaxo has previously said it would probably charge about $8 to $12 per shot, or about the same as a standard flu shot. Analysts have estimated peak annual sales could run into the hundreds of millions of dollars.

Meanwhile, Glaxo continues to negotiate with governments worldwide for contracts to supply pandemic flu vaccines. Stephenne said the company was in "advanced discussions" with about 20 to 30 governments for such contracts. Glaxo has previously announced supply contracts with the U.S., Switzerland, and an Asian nation that it didn't identify.

Several other companies are developing pandemic-related vaccines, including Novartis AG (NVS) and Sanofi-Aventis (SNY).
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[DewDiligence]

Baxter Inks Controversial Flu ‘Understanding’ with Indonesia

http://yahoo.reuters.com/news/articlehybrid.aspx?type=comktNews&storyID=urn:newsml:reuters.com:2...

>>
Wed Feb 7, 2007 11:45 AM ET
By Fitri Wulandari

JAKARTA, Feb 7 (Reuters) - Indonesia signed a memorandum of understanding with a unit of U.S. company Baxter International Inc. <BAX> on Wednesday to develop a human bird flu vaccine, as Jakarta came under fire for not sharing samples of the virus.

Earlier reports of the pact -- which sets a framework for future talks with Baxter -- stirred controversy because it had been linked to Indonesia's decision not to share H5N1 bird flu virus samples with foreign laboratories.

"The Indonesian government does not have an exclusive arrangement with us," said Baxter spokeswoman Deborah Spak. "Our role is in developing and producing vaccines. We are not involved in ownership issues related to virus strains."

Experts say sharing H5N1 samples is crucial as it allows specialists to study the makeup of the virus and trace its evolution and the geographical spread of any particular strain. Samples are also used to prepare vaccines.

Indonesia has the highest fatalities from the disease, accounting for 63 deaths out of the global total of 166 in the past four years. Bird flu largely remains an animal disease, but it can kill people who have close contact with infected fowl.

Kim Bush, president of Baxter's vaccine unit in Switzerland, said at the signing ceremony the decision on samples was Indonesia's.

"We certainly support and endorse the best practice recommendation coming from WHO (the World Health Organization) for the sharing of viruses and sequence data," Bush said.

Medical experts criticised Indonesia's decision not to share virus samples with foreign laboratories. "This seems to be a rather perverse take on intellectual property rights. It seems perverse that they would get upset by people using this," said a virologist in Hong Kong, who declined to be identified. "If it was a Western country that did that, there would be outright condemnation. How could they be so arrogant as to put the world at risk?"

If Baxter successfully develops a vaccine, it will confer protection against the H5N1 strain now in Indonesia, but not necessarily against other H5N1 strains prevalent in Indochina, parts of Europe, the Middle East and Africa.

"This is an ethical issue. The need to know should not be confined to just Indonesia; it is a world problem," said Hong Kong infectious disease expert Lo Wing-lok.

RULES OF THE GAME

Health Minister Siti Fadillah Supari defended Indonesia's decision, saying the samples should only be used for diagnostic and not commercial purposes.

"The specimens we sent to the WHO have been forwarded to their collaborating center. There it has been used for various reasons such as vaccine development ... or research," Supari said.

"Later they sold the discovery to us. This is not fair. We are the ones who got sick. They took the sample through WHO and with WHO consent and they tried to produce it for their own use," she said at a news conference after the signing of the pact with Baxter.

Supari said Australia was producing a human bird flu vaccine using the Indonesian virus strain, but did not give details.

"I was shocked because I never gave permits to Australia to produce a vaccine using our strain," she said.

"We have been working with Baxter since the beginning and are processing intellectual property rights with them. Baxter protects our intellectual property rights," she said.

Baxter's spokeswoman said the company has not signed any formal agreement.

"What this memorandum of understanding does is provide a framework for continued discussions that may or may not lead to a formal agreement or contract," Spak said.

A Health Ministry statement said the pact called for the ministry's research and development agency to supply specimens of H5N1; Baxter will provide technology to help develop a vaccine.

Health Ministry spokeswoman Lily Sulistyowati said on Tuesday that the vaccine was to prevent poultry-to-human infection, needed for the current situation but not for a future pandemic that might involve human-to-human transmission.

Under the memorandum of understanding, Indonesia would have the right to produce and market the bird flu vaccine domestically. It is negotiating to export it to a number of countries. Production would be carried out by makers appointed by the Health Ministry.

Supari said Indonesia hoped to have the vaccine ready by the end of the year. Another senior Indonesian official said earlier this month that development of the vaccine was at a very early stage.
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[Biowatch]

Altering virus coats may halt flu spread

By LAURAN NEERGAARD, AP Medical WriterThu Feb 1, 8:29 PM ET

Making a small change in the outer coating of the lethal 1918 flu virus was enough to stop it from spreading, a discovery that may help scientists monitor today's bird flu and other influenza strains for signs of the next pandemic.

The 1918 pandemic was triggered by a bird virus that mutated into one that could attack humans, going on to kill a staggering 50 million people worldwide in a matter of months.

To learn what caused that catastrophic bird-to-human transformation, scientists with the Centers for Disease Control and Prevention turned back the clock: They worked with recreated batches of the actual H1N1 flu strain that spawned the 1918 pandemic, but they altered two spots in a key protein to make that virus a little more birdlike again.

Then the researchers dripped the altered virus into the noses of ferrets, who catch and spread influenza like humans do.

The infected ferrets still sickened and died as the flu ravaged their lungs. But remarkably, they didn't infect healthy ferrets caged right next to them, the CDC team reports in Friday's edition of the journal Science.

Why not? Most flu spreads when an infected person coughs or sneezes out droplets of virus. Ferrets infected with the altered 1918 virus didn't sneeze at all.

The research suggests that for a new flu strain to become a pandemic threat, a protein called hemagglutinin that coats the virus' surface must prefer attaching to cells found mostly in the human nose and windpipe, where it can be sneezed easily.

That's good news when it comes to the notorious Asian bird flu that scientists are watching anxiously today. That strain known as H5N1 bears hemagglutinin — the H in its name — that still prefers cells mostly found in the gastrointestinal tracts of birds. While it has killed at least 164 people worldwide and killed or prompted the slaughter of millions of birds across Asia since late 2003, the H5N1 virus can't yet spread easily from person to person.

"This is very, very elegant work," said Dr. William Schaffner, an infectious disease specialist at Vanderbilt University who advises the federal government on flu issues.

"It may not be exactly the same mutations that would change an H5 virus," Schaffner cautioned. Still, he said, "We appear to be narrowing down our understanding of the kinds of mutations it might take to change a bird-specific virus to one that could be transmitted readily among humans."

The CDC's next step, in fact, is to study these same changes in hemagglutinin amino acids, the protein's building blocks, in H5N1.

But it will almost certainly take additional genetic changes to turn the H5N1 bird flu into a major human killer, changes that probably involve other proteins than just hemagglutinin, contends lead researcher Dr. Terrence Tumpey, a CDC microbiologist.

"I think that researchers may discover that the combination of genes needed is maybe unlikely to occur in nature," he said.

[DewDiligence]

Will Masks Stop Bird Flu? Students Experiment

http://news.yahoo.com/s/nm/20070130/ts_nm/birdflu_students_dc_2

>>
By Maggie Fox
Jan 30, 6:38 PM ET

Can wearing a face mask and regularly cleaning hands stop the spread of deadly bird flu? Students at the University of Michigan started a living experiment on Tuesday to find out.

They are using the peak of influenza season to see if simple cotton masks and little bottles of hand sanitizer will protect them.

Health experts fear the H5N1 avian influenza virus might mutate any moment and start a pandemic -- a global epidemic that could kill millions. If not H5N1, some other new virus could do the same, world health officials agree.

They also agree there is no easy way to stop one. Viruses are very difficult to treat with drugs, unlike bacteria, which can usually be stopped with antibiotics.

Antivirals exist to treat flu, but are in limited supply. Vaccines take time to make, and there is very limited capacity to produce them. So low-tech measures will be the first line of defense against any rapidly spreading new disease.

While influenza is hardly new, doctors do not fully understand or agree on how it is spread.

The virus is carried in droplets that can be coughed or sneezed, and a great deal of evidence shows it can survive in little droplets on surfaces, to be picked up with an errant finger and transferred to nose or mouth.

More than 2,000 students living in University of Michigan dormitories will wear masks and use hand sanitizer to see if they develop lower rates of influenza than students not using such protections.

The dense and intimate living conditions of college life are perfect for such an experiment, says Dr. Arnold Monto, a professor of epidemiology at the university who is leading the study. Students there share sleeping quarters, bathrooms, hallways and dining areas.

"There is some anecdotal evidence from prior pandemic outbreaks that masks may have helped, but no firm data," Monto said in a statement.

Monto's team has begun handing out 800 cases of alcohol-based hand sanitizer in small bottles for students to carry, and larger pump bottles for their rooms. They will also distribute cotton masks held on by rubber bands over the ears.

Students in one group will use hand sanitizer and wear simple cotton surgical masks. Another group will use only the masks and a third group will get no extra protections. They will use the products as soon as influenza is detected and reported among students.

The researchers will simply watch and see if the groups get influenza and related illnesses at different rates. The U.S. flu season generally starts in October and lasts through March, peaking in February.

"It's going to be a group effort, that's for sure," said Allison Aiello, an assistant professor of epidemiology.

The H5N1 flu remains mainly a disease of birds, but it has infected 270 people since 2003 and killed 164 of them. If it begins to spread as easily from person to person as seasonal flu, there will be no stopping a pandemic, experts say.
<<

[DewDiligence]

Dead Birds Fall From the Skies
in Australia and America

http://www.dailyindia.com/show/102198.php/Dead-birds-fall-from-the-skies-in-Australia-and-America

>>
London, Jan.11 (ANI): Two towns, in two separate continents, have reported the mysterious dropping of thousands of dead birds out of the sky.

Baffled wildlife officials were quoted by the Daily Mail as saying that three weeks ago thousands of crows, pigeons, wattles and honeyeaters fell out of the sky in Esperance, Western Australia. Last week, dozens of grackles, sparrows and pigeons dropped dead on two streets in Austin, Texas.

Veterinarians in both countries have been unable to establish a cause of death - despite carrying out a large number of autopsies on the birds.

The officials, however, have ruled out the possibility of the deaths having been caused by a severe storm, which recently struck the area.

"We estimate several thousand birds are dead, although we don't have a clear number because of the large areas of bush land. It's very substantial," the tabloid quoted District Nature Conservation Coordinator Mike Fitzgerald, as saying. Birds Australia, the country's largest bird conservation group, said it had not heard of a similar occurrence, and described it as a most unusual event.

Esperance resident Michelle Crisp, who normally sees hundreds of birds roosting in her garden, counted 80 dead ones in one day.

In Texas, officials are also working on the toxic poisoning theory.

Adolfo Valadez, medical director for Austin and Travis County Health and Human Services, said it might be weeks before any conclusive results were known.

Such was the concern that the birds suffered deliberate toxic poisoning that several streets were closed in Austin while police and fire crews checked the area for any substance that might be of harm to humans.

Federal officials in Washington said they were monitoring the situation, but a spokesman for the Department of Homeland Security said: "There is no credible intelligence to suggest an imminent threat to the homeland or Austin at this time." (ANI)
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[DewDiligence]

Scientists Warn That Tamiflu Use Could
Devastate Wildlife and Trigger a Second,
Deadlier Pandemic

[Does anyone think this is far-fetched?]

http://observer.guardian.co.uk/uk_news/story/0,,1984555,00.html

>>
By Robin McKie
January 7, 2007

Britain faces an ecological catastrophe that could wreak havoc on wildlife populations when the first outbreak of Asian flu hits the country. Scientists say they fear that tons of the anti-viral agent Tamiflu - taken by Britons trying to combat the disease - would be flushed down sewers into rivers and lakes.

Natural populations of microbes would be killed off by a deluge of water polluted with concentrated amounts of the anti-viral drug. As a result, birds, fish and other creatures that rely on these bacteria and viruses for their survival could be devastated.

In addition, waters containing Tamiflu would provide ideal conditions for the evolution of drug-resistant strains of bird flu virus. These strains would then infect wildfowl and ultimately human beings, triggering a second outbreak of the disease - although this time Tamiflu would provide no protection against the virus.

'Anti-viral drugs are quite new and no one has ever planned to use them in the vast quantities that are now being considered,' said Dr Andrew Singer, of the Centre for Ecology and Hydrology in Oxford. 'However, there are some very alarming environmental implications about giving out millions of doses of Tamiflu in order to combat an outbreak of Asian bird flu. These have not been considered by health authorities. This is unknown territory.'

…In Britain, health officials have persuaded the government to stockpile Tamiflu tablets. It is estimated that about 15.6 million doses are now in storage, ready for use. 'The aim is that people will take the drug as soon as the first outbreak is reported,' explained Singer.

'It is estimated that more than 100 million tablets, each containing 75mg of Tamiflu, could be consumed in the first weeks of a flu outbreak. Most of that will pass through people and be released in their urine. It will then be flushed away. Several tons of a powerful drug whose ecological behaviour is unknown will therefore be swept into our waterways, where it will remain active for several weeks in the country's sewers, rivers and lakes.'

Computer models developed by Singer and his colleagues at the CEH have shown that large areas of polluted water would quickly be established in many areas, probably within a few weeks of the flu cases first being reported. 'Tamiflu is an anti-viral agent, but is also known to attack bacteria - and that poses real problems for the country,' Singer said. 'Animal species have symbiotic relationships with many kinds of microbes. Human digestion relies on bacteria in our gut, for example. If these bugs are killed off by the tons of Tamiflu being dumped in our waters, all kinds of devastation could be triggered. Fish in our rivers, birds that feed off them and various kinds of river plant life could be seriously affected.'

In addition, there will also be serious implications for bird flu. A build-up of Tamiflu in our rivers is likely to cause the avian flu virus - which can infect ducks, swans and other wildfowl - to mutate so that it becomes resistant to the drug. The result will be the triggering of a second wave of the disease, though this time it will be resistant to the only form of defence we will have developed to counter it. The consequences could be extremely serious.

Singer - whose work is funded by the Natural Environment Research Council - believes health officials urgently need to tackle the problems raised by his research. 'There are things that we can think about doing,' he said. 'One course of action would be to develop chemicals that could break down Tamiflu once it has passed through a person's body but before it is flushed away. You could simply pour these into toilets to deactivate the drug before it is released into the environment. Certainly, we badly need to do a lot more research into this issue.'
<<

[mskatiescarletohara]

BioCryst Awarded $102.6 Million from U.S. Department of Health and Human Services to Develop Peramivir for Seasonal and Pandemic Influenza

Thursday January 4, 12:21 pm ET
U.S. Government Award Highlights Potential Importance of Peramivir as an Antiviral Therapy to Protect Nation Against Seasonal and Pandemic Influenza

BIRMINGHAM, Ala., Jan. 4 /PRNewswire-FirstCall/ -- BioCryst Pharmaceuticals, Inc. (Nasdaq: BCRX - News) today announced that it has been awarded a $102.6 million, four-year contract from the U.S. Department of Health and Human Services (DHHS) to develop the influenza neuraminidase inhibitor, peramivir, for the treatment of seasonal and life-threatening influenza, including avian flu.

(Logo: http://www.newscom.com/cgi-bin/prnh/20030414/BIOCRYSTLOGO)

"BioCryst is pleased to be working with the U.S. Government to further strengthen pandemic preparedness through the development of peramivir, a potentially safe and effective therapy for the treatment for seasonal and life-threatening influenza," said Charles E. Bugg, Ph.D., Chairman and CEO of BioCryst. "We are dedicated to working together to address the potential health crisis of an avian flu pandemic, as well as the annual threat of seasonal influenza."

Peramivir is an antiviral agent that inhibits the enzyme neuraminidase, potentially preventing the spread of the influenza virus.

The award made to BioCryst is part of a larger HHS initiative to pursue the development of new therapies and vaccines which may expand the ability of the United States to respond quickly to a potential pandemic. Receiving this contract from HHS further confirms the potential importance of peramivir as an effective antiviral agent for the treatment of seasonal and life-threatening influenza, including avian flu.

This contract commits $102.6 million to support the full development of both intravenous and intramuscular formulations of peramivir. The contract also funds the validation of multiple U.S.-based manufacturing facilities.

The company will sponsor a conference call at 4:30 p.m. Eastern Time today. The call is open to the public and can be accessed live either over the Internet from http://www.biocryst.com or by dialing 1-800-822-4794 (U.S.) or 1-913-981-4912 (international). No passcode is needed for the call.

[DewDiligence]

If the 1918 Flu Struck Today,
Death Toll Could Hit 81 Million

http://online.wsj.com/article/SB116674485710357238.html

>>
ASSOCIATED PRESS
December 22, 2006

LONDON -- A flu virus as deadly as the one that caused the 1918 Spanish flu could kill as many as 81 million world-wide if it struck today, a new study estimates.

By applying historical death rates to modern population data, the researchers calculated a death toll of 51 million to 81 million, with a median estimate of 62 million.

That is surprisingly high, said lead researcher Chris Murray of Harvard University. He did the analysis, in part, because he thought prior claims of 50 million deaths were wildly inflated.

"We expected to end up with a number between 15 and 20 million," Dr. Murray said. "It turns out we were wrong."

The new work is being published in the latest issue of the journal Lancet.

The 1918 flu outbreak killed at least 40 million people world-wide. But flu pandemics have varied widely in their severity. The most recent, in 1957 and 1968, were relatively mild, killing two million and one million people world-wide, respectively.

To get their estimates, Dr. Murray and his colleagues examined all available death registration data from 1914 to 1923. There was sufficient information from 27 countries, including numbers from 24 U.S. states and nine provinces in India.

The researchers compared death rates during the pandemic with average death rates before and after. That revealed how much the pandemic flu contributed to death rates, a figure called excess mortality. They then applied the excess mortality data to world-wide population data from 2004.

If their median estimate of 62 million flu deaths occurred in a single year, the total number of deaths from all causes world-wide would more than double, jumping by 114%.

The study estimates that 96% of the deaths would occur in the developing world. Dr. Murray and colleagues noted there was a 30-fold or more variation in mortality.

"That tells us it's not just the genetic makeup of the virus that will cause deaths, but that there are a lot of other things that intervene," he said. Population density, nutrition and immune status could all play roles, he suggests.
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[DewDiligence]

EMEA Backs Glaxo's Pandemic Flu Vaccine

http://yahoo.reuters.com/news/articlehybrid.aspx?storyID=urn:newsml:reuters.com:20061215:MTFH19102_2...

>>
Fri Dec 15, 2006 7:29 AM ET
By Ben Hirschler

LONDON, Dec 15 (Reuters) - A first-generation experimental bird flu vaccine for use in humans from GlaxoSmithKline Plc <GSK> has won outline support from European regulators.

The European Medicines Agency said on Friday it had recommended granting a license to Daronrix, a "mock-up" vaccine that could be used as the base for producing a shot to protect people in the event of a pandemic triggered by bird flu.

Daronrix is the first vaccine to win such endorsement. But it would only be used once a pandemic has officially been declared and would not be stockpiled in its current form, since it will have to be adapted to include the exact pandemic virus strain.

As such it marks just one approach in vaccine preparations.

Glaxo, like several of its rivals, is also working on a second-generation vaccine against the H5N1 virus that causes bird flu and plans to submit this product for regulatory approval within the next few weeks.

Its second vaccine is more flexible and could potentially be used as part of a pre-pandemic vaccination campaign, helping to prepare the human immune system in advance of a pandemic.

MASS PRODUCTION

The later vaccine, which Glaxo has already sold to some governments, has the added benefit of needing very little antigen to produce a strong immune response, allowing for production of large quantities for mass vaccination.

A key challenge in the race to produce a vaccine for millions of people around the world is how to make the maximum number of shots from the minimum amount of antigen, or active ingredient.

The U.S. government has ordered H5N1 vaccines from companies including Glaxo, Sanofi Pasteur <SASY.PA> and Novartis <NOVN.VX>, and other governments including Switzerland are also building stockpiles.

Industry analysts say the orders could give a significant boost to sales of Glaxo and its rivals next year.

…Any stockpiled H5N1 vaccine will not perfectly match whatever new strain emerges, but studies suggest it might help protect people from death.
<<

[DewDiligence]

One way to measure the slowdown in talk about bird flu is the activity level on this board, which has been around for 14 months.

During the first seven months, there were 350 posts, an average of 1.7 posts per day.

During the last seven months, there have been 42 posts, an average of 0.2 posts per day.

Are we becoming complacent?

[Emptyhead]

It is not even a year later...

http://news.yahoo.com/s/ap/20061210/ap_on_he_me/bird_flu

[DewDiligence]

Antiviral Researchers Focus on the Tail

http://yahoo.reuters.com/news/articlehybrid.aspx?storyID=urn:newsml:reuters.com:20061206:MTFH15473_2...

>>
By Patricia Reaney

LONDON, Dec 6 (Reuters) - Scientists said on Wednesday they have identified a weakness in a protein in influenza viruses which could be targeted by new drugs to halt the spread of infection.

The protein's long tail appears to be its weak point. The tail loop is almost identical in different strains of influenza A -- the most common form of the virus. New drugs that target it could be effective against multiple strains including the feared H5N1 bird flu.

"We have determined the atomic structure of the nucleoprotein from influenza A virus and found it contains a flexible tail loop," said Yizhi Jane Tao, the head of the research team from Rice University in Houston, Texas.

"This protein is important for virus replication.

The tail structure gives us some hints about how to design antiviral drugs by using this protein as a target," Tao explained.

The scientists are now collaborating with other researchers to screen possible drug compounds that could inhibit virus replication.

…The tail loop of NP has about 30 amino acids, which are the building blocks of proteins.

"We found that a mutation in only one residue out of 30 was enough to prevent the NPs from coming together to form the building blocks for the columns, and without these columns the virus cannot make copies and infect other cells," Tao said.
<<

[Biowatch]

S Korea in mass poultry slaughter
South Korean quarantine officials are to slaughter 236,000 poultry after an outbreak of the H5N1 form of bird flu at a chicken farm.

The outbreak occurred at a farm in Iksan, about 250km (155 miles) south of Seoul, earlier this week.

Test results confirmed the outbreak was caused by a type of H5N1 virus, the country's agriculture ministry said.

It said all birds within a 500-metre (1,650-foot) radius would be culled to prevent the virus from spreading.

The ministry also said it would limit the movement of about five million chickens and ducks from 221 farms within a 10-kilometre (six-mile) radius of the outbreak.

Park Yong-jong, a city official in Iksan, said the cull would begin on Sunday morning.

Lee Sang-gil, head of the agriculture ministry's livestock bureau, said no people had been infected.

South Korea killed 5.3 million birds during the last known outbreak of bird flu in 2003.

The H5N1 virus began hitting Asian poultry stocks in 2003, and has killed at least 153 people worldwide.

Most human cases have resulted from contact with infected birds.

Scientists fear the virus could mutate into a form that is more easily transmitted between people, possibly creating a pandemic.

Story from BBC NEWS:
http://news.bbc.co.uk/go/pr/fr/-/2/hi/asia-pacific/6184114.stm

Published: 2006/11/25 17:46:18 GMT

[DewDiligence]

US Orders More Bird Flu Vaccine

[It’s amusing that all three vendors (SNY, NVS, GSK) are European-based companies.]

http://yahoo.reuters.com/news/articlehybrid.aspx?storyID=urn:newsml:reuters.com:20061120:MTFH43463_2...

>>
Mon Nov 20, 2006 12:52 PM ET
By Maggie Fox

WASHINGTON, Nov 20 (Reuters) - The U.S. government said on Monday it had contracted for $200 million more worth of vaccines against the H5N1 avian flu virus.

The Health and Human Services Department said it had awarded contracts to three makers -- Sanofi Pasteur, Novartis, GlaxoSmithKline -- for enough doses to cover 2.7 million people.

The vaccine will be formulated against a new strain, or clade, of H5N1 that has emerged in recent months.

"Having a stockpile of influenza vaccine that may offer protection against the H5N1 virus is an important part of our pandemic influenza preparedness plan," Health and Human Services Secretary Mike Leavitt said in a statement.

Leavitt said the new vaccine will add to the existing stockpile of 5.9 million doses of H5N1 vaccine, which is enough to vaccinate about 3 million people because two doses are needed to achieve full immunity. The precise value of the contracts is $199.45 million.

HHS eventually plans to buy and stockpile enough vaccine for 20 million people.

The H5N1 avian flu virus mostly affects birds, but it can occasionally infect people. It has infected 258 people in 10 countries -- Thailand, Vietnam, Indonesia, China, Turkey, Azerbaijan, Iraq, Egypt, Djibouti and Cambodia -- and killed 153 of them.

Experts say the danger is that the virus will evolve just slightly into a form that people can easily catch and pass to one another, in which case the transmission rate would soar, causing a pandemic in which millions of people could die.

Any stockpiled H5N1 vaccine would not perfectly match whatever new strain emerges, but studies suggest it might help protect people from death.

Glaxo said it would make 800,000 doses at its newly bought factory in Pennsylvania, the first time it will be making bird flu vaccine in the United States.

"Additionally, HHS also has the option to purchase pre-pandemic vaccines together with one of GSK's proprietary adjuvant systems, which could mean that less antigen would be needed per dose to achieve a protective immune response," the company said in a statement.

Adjuvants are compounds added to vaccines to make them more effective.

"The three awards include a $117.9 million contract to sanofi pasteur for 3.7 million doses, a $40.95 million contract to Novartis for 800,000 doses and a $40.6 million to GlaxoSmithKline for 800,000 doses," HHS said in its statement.

In May, HHS announced more than $1 billion on contracts to five companies to develop better flu vaccine and make them in the United States. The new technology would make vaccines using lab dishes of cells, instead of the current slow, unwieldy and uncertain method that uses eggs.

"This contract covers clade 2 of the H5N1 virus (A/Indonesia) for use in the U.S. government stockpile. Previous stockpile contracts covered the clade 1 form of H5N1," sanofi said in a statement.

"Manufacturing and stockpiling more than one clade of H5N1 vaccine is strategic because circulating H5N1 influenza strains are mutating and diverging into distinct ... groups."
<<

[Biowatch]

Monitor Children on Flu Drug, F.D.A. Urges

[Apparently Tamiflu use is much higher in Japan than elsewhere, so adverse events would show up there sooner.]
http://www.nytimes.com/2006/11/14/health/policy/14tamiflu.html?_r=1&oref=slogin

By THE ASSOCIATED PRESS
Published: November 14, 2006

WASHINGTON, Nov. 13 (AP) — Doctors and parents should watch for signs of bizarre behavior in children treated with the flu drug Tamiflu, federal health officials suggested on Monday in citing an increasing number of such cases from overseas.

Food and Drug Administration officials do not know whether 103 cases recently reported, including three deaths from falls, are linked to the drug or to the flu virus, or to a combination. Most of the cases involved children.

Still, F.D.A. staff members suggested updating the Tamiflu label to recommend that all patients, especially children, be closely monitored while using the drug. They also acknowledged that stopping treatment with Tamiflu could harm influenza patients if the virus were the cause of delirium, hallucinations and other abnormal behavior like aggression and suicidal thoughts.

The pediatric advisory committee of the drug agency is to discuss the recommendation on Thursday. The agency is not required to follow the advice of its outside panels but usually does. A spokeswoman for the agency did not immediately return a call for comment.

A year ago, the same panel rejected linking Tamiflu to reports of 12 deaths in Japanese children since 2000 and voted against changing the drug label to suggest such a concern. At that time, however, the committee recommended that the drug agency continue to monitor the drug’s safety and return a year later with an update.

The panel decision after reviewing the update is likely to be closely watched because Tamiflu could have an important role in an outbreak of avian flu. The drug does not prevent flu but can reduce the length and severity of its symptoms.

Most of the 103 recent cases of bizarre behavior are from Japan, where the number of Tamiflu prescriptions is about 10 times that in the United States, with more than twice the population. The cases occurred from Aug. 29, 2005, to July 6, 2006.

The Japanese Tamiflu label now warns that disturbances in consciousness, abnormal behavior, delirium, hallucinations, delusions and convulsions may occur. It also recommends patients be carefully monitored and the drug be stopped if any abnormality is observed.

Even though severe flu cases of the flu can set off those conditions, the number and nature of the cases — along with comments from doctors who believed that the abnormal behavior was associated with the drug — have kept the drug agency from ruling out Tamiflu as the cause, according to agency documents.

The agency staff called the proposed changes prudent, because American use of Tamiflu could jump to Japan’s levels. The current American label mentions only “seizure and confusion” seen in some patients.

Tamiflu is made by the Swiss pharmaceutical company Roche Holding. A spokesman for Roche did not immediately return messages for comment. Previously, Roche has cited studies from the United States and Canada that show the death rate of influenza patients who took Tamiflu to be far below those who did not.
-----------
FDA Urges Caution on Flu Drug
By PATRICIA KOWSMANN
November 14, 2006; Page B2

WASHINGTON -- Food and Drug Administration staff recommended that the label for Roche Holding AG's flu drug Tamiflu be updated to include a precaution related to possible psychiatric problems in patients who take it.

The move follows a 10-month review that found 103 cases of "neuropsychiatric adverse events," including the death of a 14-year-old boy who fell after climbing on a balcony railing.

Of the cases, 67% were in children and 95% occurred outside the U.S., mostly in Japan, Tamiflu's biggest consumer. Two other related deaths by people who took Tamiflu were reported, including an adult who left a suicide note.

The officials still don't know if the new cases, reported from August 2005 to July, are linked to the drug, to the flu virus, or a combination of the two.

In Japan, Tamiflu's label already carries information on such events.

"Roche continuously reviews post-marketing safety information, and as a result, has agreed with the FDA that the Tamiflu label be revised to include reports of neuropsychiatric events such as self-injury and delirium in patients with influenza," a Roche statement said.

Write to Patricia Kowsmann at patricia.kowsmann@dowjones.com
URL for this article:
http://online.wsj.com/article/SB116344215315321759.html

[DewDiligence]

Skin Patches Instead of Shots

http://biz.yahoo.com/ap/061106/healthbeat_patch_vaccines.html?.v=1

>>
By Lauran Neergaard

Skin Patches Instead of Shots? Testing Under Way for Vaccines

GAITHERSBURG, Md. Nov 6 (AP) -- Dreaded vaccinations one day could be as simple as sticking on a Band-Aid -- ouchless and do-it-yourself.

Early tests of skin-patch vaccines are beginning in hundreds of volunteers, one version designed to protect against the flu and another to prevent travelers' diarrhea.

The idea isn't just pain-free vaccination. The National Institutes of Health is helping fund patch research in hopes of strengthening today's imperfect flu shots, and gaining extra help if bird flu or some other super-flu ever triggers a pandemic.

Indeed, patch developer Iomai Corp. proposes that the mailman, not a doctor, deliver flu vaccine during a pandemic. Once a vaccine is brewed, simply ship patches to people's homes with instructions to slap one on.

Doctors might not like the go-it-alone method. But the technology's main promise may be in developing countries. Unlike syringe-based vaccines, patches wouldn't need refrigeration -- nor pose the infection risk of reused needles, a continuing problem.

Only time will tell if the patches really work. Iomai is in initial stages of human testing, and years of additional work are required for proof. But previous research does suggest the skin could provide an improved route to rev up the immune system, perhaps allowing doctors to use lower vaccine doses.

"It may be that the expectations for vaccine patch technology are now slowly bearing fruit," says Dr. William Schaffner of Vanderbilt University, a vaccine expert who has long monitored the field.

"It is what I would call an alluring technology."

If it works against one disease, a patch likely could be tweaked to deliver numerous kinds of vaccines. Iomai also has Defense Department funding to help develop an anthrax vaccine patch.

"The approach is novel and may be the way many vaccines are given in the future," says Dr. Herbert DuPont of the University of Texas Health Sciences Center in Houston. A specialist in diarrheal diseases, he is helping Iomai test the travelers' diarrhea patch in U.S. tourists headed for Mexico.

Most of today's vaccines are shots into muscle. But doctors have long known that getting vaccine just inside the skin is deep enough. History's first crude inoculations, against smallpox, merely involved scratching pus from a related but milder virus into the skin. And recent research using small needles to push flu vaccine just inside the skin found lower doses could be as protective as full-strength muscle shots.

The question is how to do skin vaccination without actually breaking the skin. Patches frequently deliver medications, such as nicotine or birth control. But [those] drugs are very small molecules that can fairly easily penetrate skin to reach the bloodstream. Vaccines typically contain much larger proteins.

Iomai's method, discovered by one of its founders at the Walter Reed Army Institute of Research: Just get past a thin outer layer of dead skin to the epidermis, the first living skin layer. There, specialized cells called Langerhans cells can recognize a pathogen and speed to the lymph nodes to alert the immune system.

In Iomai's laboratory in Gaithersburg, Md., outside Washington, CEO Stanley Erck demonstrates: He brushes his skin with a gadget bearing a bit of sandpaper, like the kind used for filing fingernails. The round patch then is stuck to the scuffed spot for several hours.

"We're not inventing anything new, just exposing pathogens the way humans have seen them all their life," Erck says.

Now come the tests:

--Furthest along are patches designed to protect against an E. coli strain called ETEC, a leading cause of travelers' diarrhea. DuPont's study aims for up to 300 participants to spend at least two weeks in Mexico or Guatemala, visiting pre-specified clinic sites there if they do get diarrhea to see if the patch failed or if the culprit was some other germ. In an initial challenge study at Johns Hopkins University last year, patch recipients who drank the bacteria suffered significantly less diarrhea than their unvaccinated counterparts, Erck said.

--Last month, Iomai began first-stage testing of flu vaccine patches in 270 volunteers, to track the patches' safety and whether recipients develop as many flu-fighting antibodies as those given standard flu shots.

--Another goal is immune-stimulating patches to boost a vaccine's effects. The elderly are less protected by today's flu shots than young people. And studies of bird-flu vaccine show that a huge dose will be required regardless of age, unless immune-boosters can help stretch supplies.

Iomai's travelers' diarrhea patch also seems to give the immune system a general boost. In a small study last year, giving elderly volunteers that patch plus a standard flu shot spurred a greater immune response than the shot alone. The company now is preparing a larger study, and competing for a government contract to add immune-boosting patches to a federal stockpile of flu pandemic supplies.

"There definitely is promise to that idea," says Dr. David S. Cho of the NIH's flu product development office, who monitors the patch project -- although he cautions that Iomai must prove if the immune booster works with a variety of flu strains.
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