Interphase phenomena in a composite system based on methylsilica and crushed mushrooms Amanita muscaria

Authors

  • T.V. Krupska Chuiko Institute of Surface Chemistry
  • N.V. Yelahina Chuiko Institute of Surface Chemistry
  • I.S. Protsak Chuiko Institute of Surface Chemistry
  • V.V. Turov Chuiko Institute of Surface Chemistry

DOI:

https://doi.org/10.15407/dopovidi2020.11.061

Keywords:

Amanita muscaria fungus, composite system, methylsilica, weakly associated water

Abstract

1H NMR spectroscopy revealed that AM-1/Amanita composite systems are characterized by the significantly higher water binding energy than the starting materials, which can be used to create drug composites with increased retention time of biologically active substances that are a part of the fungus Amanita muscaria. It is in vestigated that the amount of weakly associated water is an order of magnitude smaller and is observed only at high temperatures (T > 270 K), whereas, in the chloroform medium, the number of weakly associated forms of water increases, and it is registered in the whole temperature range. It was found that, at temperatures T > 273 K in hydrophobic-hydrophilic systems AM-1/Amanita, the existence of a metastable solid state of water is possible.

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References

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Published

28.03.2024

How to Cite

Krupska, T. ., Yelahina, N. ., Protsak, I. ., & Turov, V. . (2024). Interphase phenomena in a composite system based on methylsilica and crushed mushrooms Amanita muscaria . Reports of the National Academy of Sciences of Ukraine, (11), 61–70. https://doi.org/10.15407/dopovidi2020.11.061