Vitrification as an approach to cryopreservation☆
References (78)
- et al.
Biochemical effects on kidney of exposure to high concentrations of dimethyl sulfoxide
Biochem. Pharmacol
(1971) Stability of the amorphous state in the system water-1, 2-propanediol
Cryobiology
(1979)- et al.
Stability of the amorphous state in the system water-glyceroldimethyl sulfoxide
Cryobiology
(1978) - et al.
Factors influencing renal cryopreservation. II. Toxic effects of three cryoprotectants in combination with three vehicle solutions in nonfrozen rabbit cortical slices
Cryobiology
(1984) - et al.
Induction of anhydrobiosis: Membrane changes during drying
Ciyobiology
(1982) - et al.
Stabilization of biological membranes at low water activities
Cryobiology
(1983) - et al.
Effects of electrolyte composition and pH on the structure and function of smooth muscle cooled to −79 °C in unfrozen media
Cryobiology
(1972) Cooling of rabbit kidneys permeated with glycerol to subzero temperatures
Cryobiology
(1979)Electronic techniques for controlling thawing of major organs
Cryobiology
(1984)- et al.
Survival of dog kidneys subjected to high pressures: Necrosis of kidneys after freezing
Cryobiology
(1970)
The toxicities of various solute moderators used in hypothermia
Cryobiology
(1965)
Glutathione in the isolated perfused rabbit kidney
J. Surg. Res
(1974)
Investigation into subzero non-freezing storage of rabbit kidney
Resumption of activity in frog hearts after freezing to low temperatures
Biodynamica
(1970)
Effect of concentration of ethylene glycol on the recovery of frog hearts after freezing to low temperatures
Cryobiology
(1974)
Complimentary study of some non-equilibrium phase transitions in frozen solutions of glycerol, ethylene glycol, glucose and sucrose
Biodynamica
(1969)
The glass transition in amorphous water: Application of the measurements to problems arising in Cryobiology
J. Phys. Chem
(1971)
Pressure-induced depolymerization of brain microtubules in vitro
Science
(1975)
Experimental investigations of the cellular resistance ranges of marine temperate and tropical bivalues: results of the Indian Ocean Expedition of the German Research Association
Physiol. Zool
(1967)
Living with water stress: Evolution of osmolyte systems
Science
(1982)
Pressure effects on morphology and life processes of bacteria
Water, in the liquid and five solid forms, under pressure
Engineering considerations in hypothermic and cryogenic preservation
Redox control of lysosomes in human synovia
Nature (London)
(1969)
Comparative evaluation of a new low ionic strength, hyperkalemic flush solution
Fracture of glass
Glass Science
Controlled nucleation and quasi-ordered growth of ice crystals from low temperature electrolyte solutions
Nature (London)
(1982)
Prevention of toxicity from high concentrations of cryoprotective agents
Viability concepts in organ preservation
Cryoprotectant toxicity neutralizers reduce freezing injury
Cryo-Letters
(1983)
Cryoprotectant toxicity: Biochemical or osmotic?
Cryo-Letters
(1984)
Prospects for organ preservation by vitrification
Mechanism of cell damage during freezing and thawing and its prevention
Nature (London)
(1965)
The influence of hydrostatic pressure and urethane on the thermal inactivation of bacteriophage
J. Gen. Physiol
(1949)
Perfusion of canine kidneys with dimethyl sulphoxide: techniques and toxicity
Aeration under pressure and the question of free radicals
Sci. Rep. 1st. Super. Sanita
(1961)
Effect of ATP-MgCl2 treatment on kidney preservation and on recovery of graft function
Res. Exp. Med. (Berlin)
(1980)
Cited by (990)
Fast and furious: pregnancy outcome with one-step rehydration in the warming protocol for human blastocysts
2024, Reproductive BioMedicine OnlineAn entropic theory of homogeneous ice nucleation in non-ionic aqueous solutions
2024, Journal of Chemical PhysicsHuman Natural Killer Cells Cryopreserved without DMSO Sustain Robust Effector Responses
2024, Molecular Pharmaceutics
- ☆
Presented at the symposium on Organ Cryopreservation at the 20th Annual Meeting of the Society for Cryobiology, August 1983, Cambridge, United Kingdom. Supported in part by Grants GM 17959 and BSRG 2 507 RR05737 from NIH and the American Red Cross. Contribution No. 602 from the American Red Cross, Blood Services Laboratories.
- 3
Current address: Department of Chemistry, Monash University, Clayton, Victoria 3168, Australia.
Copyright © 1984 Published by Elsevier Inc.