X-Message-Number: 28537
From: "Basie" <>
Subject: Latest Research Supports Possibility Of Cyropreservation
Date: Fri, 29 Sep 2006 18:38:48 -0400

Slow-frozen People? Latest Research Supports Possibility Of Cyropreservation
The latest research on water - still one of the least understood of all 
liquids despite a century of intensive study - seems to support the 
possibility that cells, tissues and even the entire human body could be 
cyropreserved without formation of damaging ice crystals, according to 
University of Helsinki researcher Anatoli Bogdan, Ph.D.

He conducted the study, scheduled for the July 6 issue of the ACS Journal of 
Physical Chemistry B, one of 34 peer-review journals published by the 
American Chemical Society, the world's largest scientific society.

In medicine, cryopreservation involves preserving organs and tissues for 
transplantation or other uses. Only certain kinds of cells and tissues, 
including sperm and embryos, currently can be frozen and successfully 
rewarmed. A major problem hindering wider use of cyropreservation is 
formation of ice crystals, which damage cell structures.

Cyropreservation may be most familiar, however, as the controversial idea 
that humans, stricken with incurable diseases, might be frozen and then 
revived years or decades later when cures are available.

Bogdan's experiments involved a form of water termed "glassy water," or 
low-density amorphous ice (LDA), which is produced by slowly supercooling 
diluted aqueous droplets. LDA melts into highly viscous water (HVW). Bogdan 
reports that HVW is not a new form of water, as some scientists believed.

"That HVW is not a new form of water (i.e., normal and glassy water are 
thermodynamically connected) may have some interesting practical 
implications in cryobiology, medicine, and cryonics." Bogdan said.

"It may seem fantastic, but the fact that in aqueous solution, [the] water 
component can be slowly supercooled to the glassy state and warmed back 
without the crystallization implies that, in principle, if the suitable 
cyroprotectant is created, cells in plants and living matter could withstand 
a large supercooling and survive," Bogdan explained. In present 
cyropreservation, the cells being preserved are often damaged due to 
freezing of water either on cooling or subsequent warming to room 
temperature.

"Damage of the cells occurs due to the extra-cellular and intra-cellular ice 
formation which leads to dehydration and separation into the ice and 
concentrated unfrozen solution. If we could, by slow cooling/warming, 
supercool and then warm the cells without the crystallization of water then 
the cells would be undamaged."

The American Chemical Society -- the world's largest scientific society --  
is a nonprofit organization chartered by the U.S. Congress and a global 
leader in providing access to chemistry-related research through its 
multiple databases, peer-reviewed journals and scientific conferences. Its 
main offices are in Washington, D.C., and Columbus, Ohio.

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