@article{jpbpc2021912,
author={{Tako, Masakuni and Teruya, Takeshi and Tamaki, Yukihioro and Uechi, Keiko and Konishi, Teruko},
title={Molecular Origin for Strong Agarose Gels: Multi-Stranded Hydrogen Bonding},
journal={Journal of Polymer and Biopolymer Physics Chemistry},
volume={9},
number={1},
pages={13--19},
year={2021},
url={http://pubs.sciepub.com/jpbpc/9/1/2},
issn={2373-3411},
abstract={Agarose gels are currently used in separation, purification, and<b> </b>characterization of DNA, RNA, proteins, and polysaccharides in gel electrophoresis, gel<b> </b>filtration, affinity chromatography, and ion chromatography techniques. Specifically, it is used in PCR (Polymerase Chain Reaction) test. Although, double stranded<b> </b>intermolecular hydrogen bonding between OH-2 and 3,6-ring oxygen atoms of<b> </b>1,4-linked anhydro-¦Á-L-galactopyranose residues on different molecules take place,<b> </b>triple- or multi-stranded secondary association occur with increasing concentration. The<b> </b>multi-stranded gelation mechanism of agarose molecules is the first to report. The<b> </b>associated agarose molecules play a dominant role in the centre of tetrahedral cavities<b> </b>that are occupied by ice-like hydrogen bonded water molecules which are caused<b> </b>thermodynamically by cage and hydrophobic effects. Many investigations the gelling<b> </b>properties of the polysaccharides have been undertaken to elucidate the<b> </b>structure-function relationship, but no other researchers have established the<b> </b>mechanisms at the molecular level including water molecules. There are structural and<b> </b>theoretical consistencies in our investigation. This paper provides important information<b> </b>not only academia, but also to industrial fields, such as bio-physicochemical analysis,<b> </b>food, cosmetics, agriculture, pharmaceuticals, drug delivery, drug storage, tissue<b> </b>engineering, and biotechnology.},
doi={10.12691/jpbpc-9-1-2}
publisher={Science and Education Publishing}
}