the water is not only normal water, it´s special. I oversaw that first. But it seems to be something interesting so
Question remains, how much it cost and if people are willing to spend it and if they belief it will work
The Golden Ally Lifetech (“GALTG”) AQP Active Water project is a derivative of an academic inspiration from the 2003 Nobel Laureates in Chemistry, Peter Agre, for the discovery and pioneering research of water channels, also called aquaporins (“AQP”), in cell membranes.
The AQP active water technology roots from Japan, where the founder Prof. Kitagawa uncovered that water treated by an exclusive proprietary material offered enhanced biological effects. He proposed that the structure of water cluster altered by this proprietary water technology fundamentally distinguishes the AQP water with other functional waters.
His exclusive partnership with a U.S.-based engineering team aims to mass-produce proprietary AQP water, firstly offering the distinctive water products in the U.S. GALT’s mission is to advance human health through our proprietary water technology. Cells are the basic structural and functional units of life, consisting of a cytoplasm enclosed with a cell membrane. Cell membrane provides a protective barrier around the cell while regulates which materials or molecule can pass in or not. Like ionic channels, such as calcium ion (Ca2+) channel, potassium ion (K+) channel, sodium ion (Na+) channel, and proton (H+) channel, that regulate the transport of ions across the cell membrane, the transport of water across the cell membrane is mediated through water channels, also called aquaporins, and driven by the osmosis pressure across the cell membrane
Aquaporin
From Wikipedia, the free encyclopedia Jump to navigationJump to search Aquaporin Aquaporin-Sideview.png Crystallographic structure of aquaporin 1 (AQP1) PDB 1j4n Identifiers Symbol Aquaporin Pfam PF00230 InterPro IPR000425 PROSITE PDOC00193 SCOP2 1fx8 / SCOPe / SUPFAM TCDB 1.A.8 OPM superfamily 7 OPM protein 2zz9 Available protein structures: Aquaporins, also called water channels, are channel proteins from a larger family of major intrinsic proteins that form pores in the membrane of biological cells, mainly facilitating transport of water between cells.[1] The cell membranes of a variety of different bacteria, fungi, animal and plant cells contain aquaporins through which water can flow more rapidly into and out of the cell than by diffusing through the phospholipid bilayer.[2] Aquaporins have six membrane-spanning alpha helical domains with both carboxylic and amino terminals on the cytoplasmic side. Two hydrophobic loops contain conserved asparagine-proline-alanine ("NPA motif") which form a barrel surrounding a central pore-like region that contains additional protein density.[3] Because aquaporins are usually always open and are prevalent in just about every cell type, this leads to a misconception that water readily passes through the cell membrane down its concentration gradient. Water can pass through the cell membrane through simple diffusion because it is a small molecule, and through osmosis, in cases where the concentration of water outside of the cell is greater than that of the inside. However, because water is a polar molecule this process of simple diffusion is relatively slow, and in tissues with high water permeability the majority of water passes through aquaporin.[4][5]
The 2003 Nobel Prize in Chemistry was awarded jointly to Peter Agre for the discovery of aquaporins[6] and Roderick MacKinnon for his work on the structure and mechanism of potassium channels.[7]
Genetic defects involving aquaporin genes have been associated with several human diseases including nephrogenic diabetes insipidus and neuromyelitis optica.
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