Replies to post #661 on Helicos Biosciences Corporation (fka HLCSQ)

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109 PATENTS


BACKGROUND

Generally, systems for analyzing a sample in a flow cell are pressure driven fluidic systems using pressure pumps. Pressure driven fluidics systems have several disadvantages. One disadvantage is that pressure driven systems require the sample vessel to be sealably engaged to the flow cell assembly. This makes removal of the flow cell more complicated, because removal of the flow cell can produce hazardous aerosols. Pressure systems are also known to develop system leaks due to the pressure and may require frequent replacement of lines and valves. Additionally, pressure driven systems can introduce contaminants into the sample. Another disadvantage of pushing fluid through the system is that air can become trapped in the system or air bubbles can be introduced into the sample. Introduction of air into the pump can cause cavitation resulting in shock to the system. Moreover, in pressure driven systems, it is difficult to adequately purge the lines after each sample has been tested. This can result in residual material being left in the system when the next test is performed. Also, purging the system using air pressure tends to cause bubbling or foaming in the samples, which may introduce inaccuracies to the analysis.

The prior art vacuum driven systems that have been used to analyze samples in a flow cell also have disadvantages. In these prior art systems, a vacuum pump is directly connected to the flow cell. Again, the use of a pump can cause air bubbles to be introduced into the sample and air trapped in the pump transmit shock to the system. Additionally, the continuous on and off cycle of the pump can result in uneven passage of a sample through the flow cell. Prior art vacuum systems are also generally suited for passing multi-cell samples through the flow cell. Having a pump directly connected to the flow cell can negatively impact single-cell samples, in part, because of the shock transmitted to the system.

In analyzing microfluidic volumes and related biological materials using a light source, . The excited fluorophores can be observed using, for example, an intensified CCD camera. Accurately maintaining the critit is desirable for the light source to hit the sample in such a way that results in total internal reflection fluorescence ("TIRF"). TIRF is an optical phenomenon that occurs when light propagating in a dense medium, such as glass, meets an interface with a less dense medium such as water. If the light meets the surface at a small angle, some of the light passes through the interface (is refracted) and some is reflected back into the dense medium. At a certain angle, known as the critical angle, all of the light is refracted. However, some of the energy of the beam still propagates a short distance into the less dense medium, generating an evanescent wave. The evanescent wave only penetrates about 100 nm into the medium. If this energy is not absorbed, it passes back into the dense medium. However, if a flourophore molecule is within the evanescent wave, it can absorb photons and be excitedical angle to obtain TIRF in a dynamic system is difficult.

SUMMARY OF THE INVENTION

The present invention involves using a vacuum source to pull microfluidic volumes through analytical equipment, such as flow cells and the like. Generally, the invention includes a passive vacuum source and one or more valves and sensors for operating and monitoring the apparatus and methods. Additionally, the invention involves using optical equipment in conjunction with the analytical equipment to analyze samples and control the operation thereof.

In one aspect, the invention relates to a lighting system including a first light source for analyzing a sample of interest and a second light source. The first light source defines a first optical path that intersects a sample of interest and the second light source operates with the first light source for determining a position of the first optical path.

In various embodiments of the foregoing aspect, the first light source and the second light source operate simultaneously. The second light source may define a second optical path at least partially coaxial with the first optical path. In one embodiment, the second light source is directed to a position sensor for sensing an angle of reflection of the first optical path relative to the sample of interest. The position of the first optical path can be adjusted to vary the angle of reflection in response to a signal from the position sensor. The position of the first optical path can be adjusted to obtain substantially total internal reflection of the first light source relative to the sample of interest.

Additionally, the first light source can have a wavelength from about 390 nm to about 780 nm. In one embodiment, the second light source is infrared light. The first light source and/or the second light source can be a laser, a light emitting diode, or a lamp. In one embodiment, the system includes an imaging device for imaging the sample of interest. Further, the system can include a third light source for analyzing the sample of interest. The third light source can define a third optical path at least partially coaxial with the first optical path. The first light source and the third light source can be operated simultaneously. The second light source may be used to continuously monitor the position of the first optical path. In one application, the light system can be adapted for use in a single molecule sequencing system.

In another aspect, the invention relates to a method of substantially maintaining total internal reflection for a sample of interest. The method includes the steps of providing a first beam of light for intersecting with the sample of interest, providing a second beam of light for determining a position of the first beam of light, directing the second beam of light onto a position sensor, and adjusting the position of the first beam of light in response to a signal from the position sensor to vary an angle of reflection of the first beam of light with respect to the sample of interest to substantially maintain total internal reflection.

In various embodiments, the first beam of light is at least partially coaxial with the second beam of light. The first beam of light is for analyzing the sample of interest. In one embodiment, the first light source has a wavelength from about 390 nm to about 780 nm. The second light source may be infrared light. The method may also include the steps of continuously monitoring the position of the first beam of light and adjusting the angle of reflection in response thereto to substantially maintain total internal reflection.

In another aspect, the invention relates to a system for analyzing a sample. The system includes a flow cell, a passive vacuum source for pulling a volume through the flow cell, a lighting system for illuminating the sample in the flow cell, and an optical instrument for viewing the sample in the flow cell. The lighting system can be of the type described hereinabove. In one embodiment, the volume includes the sample or agents for reacting with the sample, which may be predisposed on or within the flow cell. Alternatively or additionally, the sample may adhere to or come to rest within the flow cell while the volume passes therethrough. In one embodiment, the volume and/or sample is moved through the flow cell by gravity. For example, the head pressure on the volume within an inlet to the flow cell is sufficient to move the volume through the flow cell.

In various embodiments of the foregoing aspect, the system includes a stage for receiving the flow cell, where the stage is movable in at least one direction. In one embodiment, the stage is movable in two orthogonal directions. The system may also include an image capture device for capturing an image of the sample. The image capture device can be a charge coupled device (CCD), a complementary metal oxide semiconductor device (CMOS), a charge injection device (CID), or a video camera. Additionally, the system could include a processor for collecting and processing data generated by the system, storage for storing the data, and means for displaying at least one of the data and the sample.

In another aspect, the invention relates to an apparatus for handling microfluidic volumes, such as biological samples for analysis. The apparatus can include the aforementioned passive vacuum source and flow cell. The microfluidic volume is pulled through the flow cell by the passive vacuum source. In one embodiment, the passive vacuum source includes a pump, a pump driver, such as an electric motor, and a reservoir. The pump can be connected to the reservoir and then operated to evacuate the reservoir, thereby creating a vacuum within the reservoir. In one embodiment, the vacuum pressure is from about 1'' Hg to about 29'' Hg. The vacuum pressure can be adjusted to vary the speed at which the microfluidic volume passes through the flow cell.

In various embodiments of the foregoing aspects, the apparatus/system can be used for single molecule detection. In one embodiment, the flow cell includes a surface for receiving a nucleotide. For example, the flow cell can include a bound nucleotide and a primer bound to the nucleotide and/or the flow cell. In particular, the flow cell can include a slide and a coverslip, where the nucleotide and/or the primer are bound to at least one of the slide and the coverslip. Additionally, the flow cell can include a channel for pulling the microfluidic volume therethrough.

In some embodiments of the foregoing aspects, the ratio of a volume of the reservoir and the microfluidic volume is between about 1,000:1 and about 2,000,000:1, or between about 50,000:1 and about 1,000,000:1, or about 200,000:1. Further, the apparatus can include valving disposed between the various components thereof. For example, the apparatus can include a valve disposed between the vacuum source, for example the reservoir, and the flow cell, wherein the valve includes an open position to connect the flow cell to the vacuum source and a closed position to isolate the flow cell from the vacuum source. The apparatus can also include a vacuum pressure indicator connected to the reservoir. Moreover, the apparatus can further include optical equipment for analyzing material within the flow cell after exposure to the microfluidic volume.

In another aspect, the invention relates to a method of detecting single molecules. The method includes the steps of depositing a sample comprising single molecules into a flow cell, the flow cell treated to identify specific molecules; applying a vacuum to the flow cell; pulling the sample through a channel defined by the flow cell; and viewing the flow cell after exposure to the sample to identify the molecules exposed to the flow cell.

In another aspect, the invention relates to a method of detecting single molecules. The method includes the steps of providing a flow cell that defines a channel that is treated to identify specific molecules, applying a vacuum to the channel to pull a sample through the channel, the sample comprising single molecules, and viewing the sample in the channel to identify the single molecules.

Various embodiments of the foregoing methods include the step of removing the vacuum from the flow cell after pulling the sample through the channel. The step of applying a vacuum can include exposing the flow cell to a passive vacuum source. In various embodiments, the sample includes a microfluidic volume including nucleotides. Additionally, the flow cell can include at least one of a slide and a coverslip treated to bind with a specific nucleotide. Further, the step of viewing the flow cell can include illuminating the flow cell with a lighting system, such as that described hereinabove. The step of viewing the flow cell can also include using an image capture device. In one embodiment, a processor is used to control the operation of the method. The processor can be used for collecting and processing data generated during the method. The method can further include the step of displaying at least one of the flow cell and the data.

In another embodiment, single nucleotide detection is accomplished by attaching template nucleic acids to a flow cell in the presence of a primer for template-dependent nucleic acid synthesis. Using a device according to the invention, a vacuum is created across the flow cell for introduction of reagents for template-dependent nucleic acid synthesis. For example, once template/primer pairs are bound to the surface of the flow cell, reagents comprising labeled or unlabeled nucleotides and a polymerase to catalyze nucleotide addition are added via an entry port. The vacuum is switched on and the reagents are exposed to the flow cell and then exit via an exit port to the reservoir. After a wash step, complementary nucleotides added to primer are detected. Preferably, reagent nucleotides are labeled with, for example, a fluorescent dye. Such dyes are observed using light microscopy. For example, cyanine dyes (cyanine-3 or cyanine-5) are useful for optical detection of incorporated nucleotides. Using optically-detectable labels, nucleic acid sequencing is conducted on a single molecule level. This means that individual template nucleic acids are positioned on the flow cell such that each is individually optically resolvable. The location of the templates is determined by, for example, the use of dye-labeled primers that hybridize to individual templates. Labeled nucleotides are flowed across the flow channel using the mechanisms described herein under conditions that allow complementary nucleotide addition to the primer. Once incorporated, the label is detected by excitation of the dye at the appropriate wavelength and by using an emission filter for detection of the emission spectrum. Emissions that occur at a location known to contain a template indicate incorporation of the labeled base at that position. By conducting these steps multiple times, a sequence is completed. Single molecule sequencing techniques are described in Braslavsky, et al., PNAS (USA), 100: 3960-3964 (2003) and copending U.S. patent application Ser. No. 09/707,737, each of which is incorporated by reference herein.

In another aspect, the invention relates to a flow cell for analyzing single molecules, such as nucleotides. The flow cell includes a slide, a coverslip, and a gasket disposed between the slide and the coverslip. The slide, the coverslip, and the gasket define a microfluidic channel for passing single molecules under vacuum. In various embodiments, the flow cell includes a nucleotide bound to the slide and/or the coverslip. In addition, the flow cell can include a primer bound to at least one of the nucleotide, the slide, and the coverslip. In one embodiment, the slide includes a plurality of nucleotides bound thereto.

In another aspect, the invention relates to a slide for use with a flow cell. The slide can include at least one nucleotide bound to a surface of the slide. The slide can be disposed within the flow cell. The slide can further include a primer bound to at least one of the slide and the nucleotide. In addition, the slide can include a plurality of nucleotides bound thereto.

In another aspect, the invention relates to a coverslip for use with a flow cell. The coverslip includes at least one nucleotide bound to a surface of the coverslip. The coverslip can be disposed within the flow cell. The coverslip can further comprise a primer bound to at least one of the coverslip and the nucleotide. In one embodiment, the coverslip includes a plurality of nucleotides bound thereto.

These and other objects, along with advantages and features of the present invention herein disclosed, will become apparent through reference to the following description, the accompanying drawings, and the claims. Furthermore, it is to be understood that the features of the various embodiments described herein are not mutually exclusive and can exist in various combinations and permutations.