Peter Mazur

Q: What Schools Are Affiliated With Peter Mazur

Peter Mazur is affiliated with the following schools: University of Tennessee, Princeton University, Harvard University

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Peter Mazur

Chemistry

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Chemical Engineering

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World Rank

#89

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Chemistry

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Peter Mazur's Published Works

Number of citations in a given year to any of this author's works

Total number of citations to an author for the works they published in a given year. This highlights publication of the most important work(s) by the author

Published Works

Freezing of living cells: mechanisms and implications. (1984) (1902)
Cryobiology: the freezing of biological systems. (1970) (1502)
Kinetics of Water Loss from Cells at Subzero Temperatures and the Likelihood of Intracellular Freezing (1963) (997)
A two-factor hypothesis of freezing injury. Evidence from Chinese hamster tissue-culture cells. (1972) (825)
Survival of Mouse Embryos Frozen to -196� and -269�C (1972) (797)
The role of intracellular freezing in the death of cells cooled at supraoptimal rates. (1977) (718)
Studies on the reduction of 2,3,5-triphenyltetrazolium chloride as a viability assay for plant tissue cultures (1975) (385)
Prevention of osmotic injury to human spermatozoa during addition and removal of glycerol. (1995) (330)
Principles of Cryobiology (2004) (285)
Freezing Injury in Plants (1969) (261)
Effects of freezing on marrow stem cell suspensions: interactions of cooling and warming rates in the presence of PVP, sucrose, or glycerol. (1970) (242)
Equilibrium, quasi-equilibrium, and nonequilibrium freezing of mammalian embryos (1990) (222)
Interactions of cooling velocity, temperature, and warming velocity on the survival of frozen and thawed yeast. (1968) (203)
CAUSES OF INJURY IN FROZEN AND THAWED CELLS. (1965) (198)
Cryopreservation of the Germplasm of Animals Used in Biological and Medical Research: Importance, Impact, Status, and Future Directions (2008) (198)
THE ROLE OF CELL MEMBRANES IN THE FREEZING OF YEAST AND OTHER SINGLE CELLS * (1965) (192)
The dominance of warming rate over cooling rate in the survival of mouse oocytes subjected to a vitrification procedure. (2009) (182)
Hyperosmotic tolerance of human spermatozoa: separate effects of glycerol, sodium chloride, and sucrose on spermolysis. (1993) (168)
Cryobiological preservation of Drosophila embryos. (1992) (157)
Cryopreservation of human spermatozoa. IV. The effects of cooling rate and warming rate on the maintenance of motility, plasma membrane integrity, and mitochondrial function. (1993) (155)
Osmotic consequences of cryoprotectant permeability and its relation to the survival of frozen-thawed embryos (1984) (154)
Glycerol permeabilities of fertilized and infertilized mouse ova. (1980) (148)
Survival of mouse oocytes after being cooled in a vitrification solution to -196°C at 95° to 70,000°C/min and warmed at 610° to 118,000°C/min: A new paradigm for cryopreservation by vitrification. (2011) (146)
Relative contributions of the fraction of unfrozen water and of salt concentration to the survival of slowly frozen human erythrocytes. (1981) (145)
The role of cooling rates in low-temperature preservation. (1971) (140)
8 – Methods for the Preservation of Mammalian Embryos by Freezing (1978) (140)
Osmotic tolerance limits and properties of murine spermatozoa. (1996) (137)
Fundamental Cryobiology of Mammalian Spermatozoa (1997) (131)
VISUALIZATION OF FREEZING DAMAGE (1973) (124)
Survival of mouse embryos frozen to -196 degrees and -269 degrees C. (1972) (124)
Survival of hamster tissue culture cells after freezing and thawing. Interactions between protective solutes and cooling and warming rates. (1969) (121)
Survival of frozen-thawed human red cells as a function of cooling and warming velocities. (1976) (116)
Factors affecting survival of mouse embryos during freezing and thawing. (1974) (115)
PHYSICAL FACTORS IMPLICATED IN THE DEATH OF MICROORGANISMS AT SUBZERO TEMPERATURES * (1960) (113)
Theoretical and experimental effects of cooling and warming velocity on the survival of frozen and thawed cells. (1966) (106)
Effect of Warming Rate on the Survival of Vitrified Mouse Oocytes and on the Recrystallization of Intracellular Ice1 (2008) (105)
Depression of the ice-nucleation temperature of rapidly cooled mouse embryos by glycerol and dimethyl sulfoxide. (1983) (103)
Roles of unfrozen fraction, salt concentration, and changes in cell volume in the survival of frozen human erythrocytes. (1988) (102)
Extra- and intracellular ice formation in mouse oocytes. (2005) (101)
Mouse spermatozoa in high concentrations of glycerol: chemical toxicity vs osmotic shock at normal and reduced oxygen concentrations. (1998) (98)
Determination of water permeability coefficient for human spermatozoa and its activation energy. (1993) (95)
Contributions of unfrozen fraction and of salt concentration to the survival of slowly frozen human erythrocytes: influence of warming rate. (1983) (88)
Slow-freezing injury in mammalian cells. (1977) (87)
Ultra-Rapid Warming Yields High Survival of Mouse Oocytes Cooled to −196°C in Dilutions of a Standard Vitrification Solution (2012) (86)
Is Intracellular Ice Formation the Cause of Death of Mouse Sperm Frozen at High Cooling Rates?1 (2002) (85)
Kinetics of water loss and the likelihood of intracellular freezing in mouse ova (1984) (85)
The enhancement of the ability of mouse sperm to survive freezing and thawing by the use of high concentrations of glycerol and the presence of an Escherichia coli membrane preparation (Oxyrase) to lower the oxygen concentration. (2000) (84)
Characteristics and kinetics of subzero chilling injury in Drosophila embryos. (1992) (82)
Physical and temporal factors involved in the death of yeast at subzero temperatures. (1961) (79)
Fully hydrated yeast cells imaged with electron microscopy. (2011) (77)
Influence of cell concentration on the contribution of unfrozen fraction and salt concentration to the survival of slowly frozen human erythrocytes. (1985) (74)
Comparison of actual vs. synthesized ternary phase diagrams for solutes of cryobiological interest. (2007) (74)
Survivals of mouse oocytes approach 100% after vitrification in 3-fold diluted media and ultra-rapid warming by an IR laser pulse. (2014) (74)
Effect of osmolality and oxygen tension on the survival of mouse sperm frozen to various temperatures in various concentrations of glycerol and raffinose. (2000) (73)
Osmotic responses of preimplantation mouse and bovine embryos and their cryobiological implications (1986) (72)
High survival of mouse oocytes/embryos after vitrification without permeating cryoprotectants followed by ultra-rapid warming with an IR laser pulse (2015) (68)
Limits to life at low temperatures and at reduced water contents and water activities (1980) (68)
Influence of centrifugation regimes on motility, yield, and cell associations of mouse spermatozoa. (1998) (67)
Physical-chemical basis of the protection of slowly frozen human erythrocytes by glycerol. (1978) (66)
Permeability of the human erythrocyte to glycerol in 1 and 2 m solutions at 0 or 20 °C☆ (1976) (65)
High ice nucleation temperature of zebrafish embryos: slow-freezing is not an option. (2004) (57)
Effects of warming rate, temperature, and antifreeze proteins on the survival of mouse spermatozoa frozen at an optimal rate. (2002) (55)
SURVIVAL OF MOUSE EMBRYOS FROZEN TO -196 AND -269$sup 0$C (1972) (55)
The effect of the osmolality of sugar-containing media, the type of sugar, and the mass and molar concentration of sugar on the survival of frozen-thawed mouse sperm. (2002) (54)
Glycerol permeability of human spermatozoa and its activation energy. (1992) (53)
Stopping Biological Time (1988) (52)
MANIFESTATIONS OF INJURY IN YEAST CELLS EXPOSED TO SUBZERO TEMPERATURES I (1961) (52)
Interactions of cooling rate, warming rate, glycerol concentration, and dilution procedure on the viability of frozen-thawed human granulocytes. (1983) (51)
Studies on rapidly frozen suspensions of yeast cells by differential thermal analysis and conductometry. (1963) (51)
Fundamental aspects of the freezing of cells, with emphasis on mammalian ova and embryos. (1980) (51)
Water volume and osmotic behaviour of mouse spermatozoa determined by electron paramagnetic resonance. (1994) (50)
Effects of Cooling and Warming Rate to and from −70°C, and Effect of Further Cooling from −70 to −196°C on the Motility of Mouse Spermatozoa1 (2002) (50)
The effect of collection temperature, cooling rate and warming rate on chilling injury and cryopreservation of mouse spermatozoa. (1995) (50)
Survival of mouse embryos frozen to -196 deg and -269 deg C (1972) (49)
Osmotic tolerance of human granulocytes. (1984) (48)
Intracellular ice formation in yeast cells vs. cooling rate: predictions from modeling vs. experimental observations by differential scanning calorimetry. (2009) (41)
CHAPTER 14 – Survival of Fungi after Freezing and Desiccation (1968) (41)
Coral larvae conservation: physiology and reproduction. (2006) (40)
Toxic and osmotic effects of glycerol on human granulocytes. (1984) (40)
Survival of frozen-thawed human red cells as a function of the permeation of glycerol and sucrose. (1976) (40)
Survival of frozen-thawed fetal rat pancreases as a function of the permeation of dimethylsulfoxide and glycerol, warming rate, and fetal age. (1977) (40)
Analysis of intracellular ice nucleation in Xenopus oocytes by differential scanning calorimetry. (2006) (39)
Stopping biological time. The freezing of living cells. (1988) (38)
Human spermatozoa glycerol permeability and activation energy determined by electron paramagnetic resonance. (1994) (38)
Extreme rapid warming yields high functional survivals of vitrified 8-cell mouse embryos even when suspended in a half-strength vitrification solution and cooled at moderate rates to -196°C. (2014) (38)
Biological implications of the Viking mission to Mars (1978) (38)
Effect of osmotic shock and low salt concentration on survival and density of bacteriophages T4B and T4Bo1. (1966) (37)
Preliminary estimates of the permeability of mouse ova and early embryos to glycerol (1976) (36)
Interactions of Cooling Rate, Warming Rate and Protective Additive on the Survival of Frozen Mammalian Cells (2008) (36)
Factors affecting yield and survival of cells when suspensions are subjected to centrifugation (2007) (36)
Permeability of intact and dechorionated eggs of the Anopheles mosquito to water vapor and liquid water: a comparison with Drosophila. (1996) (36)
A biologist's view of the relevance of thermodynamics and physical chemistry to cryobiology. (2010) (35)
KINETICS OF THE ULTRAVIOLET‐INDUCED DIMERIZATION OF THYMINE IN FROZEN SOLUTIONS * (1966) (35)
Contributions of Cooling and Warming Rate and Developmental Stage to the Survival of Drosophila Embryos Cooled to -205°C (1993) (34)
Osmotic shrinkage as a factor in freezing injury in plant tissue cultures. (1976) (33)
Relation between ultrastructure and viability of frozen-thawed Chinese hamster tissue-culture cells. (1972) (33)
Relative influence of unfrozen fraction and salt concentration on the survival of slowly frozen eight-cell mouse embryos. (1987) (33)
Permeability of the 17-day fetal rat pancreas to glycerol and dimethylsulfoxide. (1981) (32)
Extra- and intra-cellular ice formation in Stage I and II Xenopus laevis oocytes. (2006) (31)
Survival of fetal rat pancreases frozen to -78 and -196 degrees. (1976) (30)
Intracellular ice formation in mouse oocytes subjected to interrupted rapid cooling. (2007) (30)
Permeabilization of eggs of the malaria mosquito Anopheles gambiae. (1996) (29)
Kinetics and activation energy of recrystallization of intracellular ice in mouse oocytes subjected to interrupted rapid cooling. (2008) (29)
Temperature dependence of the survival of human erythrocytes frozen slowly in various concentrations of glycerol. (1978) (28)
Critical factors affecting the permeabilization of Drosophila embryos by alkanes. (1992) (28)
Survival of Pasteurella tularensis in gelatin-saline after cooling and warming at subzero temperatures. (1957) (27)
Reversal of experimental diabetes by fetal rat pancreas. I. Survival and function of fetal rat pancreas frozen to--196 degrees C. (1977) (26)
Simple, inexpensive attainment and measurement of very high cooling and warming rates. (2010) (24)
Freezing of bacteriophage T4: temperature and rate effects as a function of salt concentration. (1969) (23)
Permeability of the bovine red cell to glycerol in hyperosmotic solutions at various temperatures (2005) (22)
Physical-Chemical Basis of Injury from Intracellular Freezing in Yeast (1967) (22)
STUDIES ON THE EFFECTS OF SUBZERO TEMPERATURES ON THE VIABILITY OF SPORES OF ASPERGILLUS FLAVUS (1956) (22)
MANIFESTATIONS OF INJURY IN YEAST CELLS EXPOSED TO SUBZERO TEMPERATURES II (1961) (21)
SURVIVAL OF PASTEURELLA TULARENSIS IN SUGAR SOLUTIONS AFTER COLLING AND WARMING AT SUB-ZERO TEMPERATURES (1957) (21)
PRESERVATION OF ANTIBODY-PRODUCING CELLS AT LOW TEMPERATURE: A METHOD OF STORAGE THAT ALLOWS COMPLETE RECOVERY OF ACTIVITY. (1963) (20)
Effects of hold time after extracellular ice formation on intracellular freezing of mouse oocytes. (2005) (20)
Permeation and toxicity of ethylene glycol and methanol in larvae of Anopheles gambiae (2003) (19)
Characterization of intraembryonic freezing in Anopheles gambiae embryos. (1996) (19)
The Temperature and Type of Intracellular Ice Formation in Preimplantation Mouse Embryos as a Function of the Developmental Stage1 (2010) (19)
The temperature of intracellular ice formation in mouse oocytes vs. the unfrozen fraction at that temperature. (2007) (19)
Effects of cooling and warming rate to and from -70 degrees C, and effect of further cooling from -70 to -196 degrees C on the motility of mouse spermatozoa. (2002) (19)
Physical parameters, modeling, and methodological details in using IR laser pulses to warm frozen or vitrified cells ultra-rapidly. (2015) (18)
Roles of intracellular ice formation, vitrification of cell water, and recrystallisation of intracellular ice on the survival of mouse embryos and oocytes. (2016) (18)
Relationship between intracellular ice formation in oocytes of the mouse and Xenopus and the physical state of the external medium--a revisit. (2008) (17)
Chill sensitivity of honey bee, Apis mellifera, embryos. (2006) (15)
Physiological Response of Neurospora Conidia to Freezing in the Dehydrated, Hydrated, or Germinated State (1978) (15)
The Viking mission: Implications for life on Mars (1979) (15)
Effect of the expression of aquaporins 1 and 3 in mouse oocytes and compacted eight-cell embryos on the nucleation temperature for intracellular ice formation. (2011) (14)
THE EFFECTS OF SPRAY-DRYING ON THE VIABILITY OF FUNGOUS SPORES (1956) (13)
Physical and chemical changes during freezing and thawing of cells, with special reference to blood cells. (1968) (13)
Effects of sugars on the kinetics of drying and on the survival of partially dehydrated larvae of Anopheles mosquitoes. (2003) (12)
Rectification of the Water Permeability in COS-7 Cells at 22, 10 and 0°C (2011) (12)
Approaches to the preservation of human granulocytes by freezing. (1980) (12)
Sperm preservation: Fundamental cryobiology and practical implications (1992) (11)
BASIC PROBLEMS IN CRYOBIOLOGY (1964) (11)
Contributions of cooling and warming rate and developmental stage to the survival of Drosophila embryos cooled to -205 degrees C. (1993) (11)
The kinetics of embryo drying in Drosophila melanogaster as a function of the steps in permeabilization: Experimental (1996) (10)
Chilling injury in intact Drosophila eggs at various stages of embryonic development between 0 and −25 °C in the absence of ice formation☆☆☆ (1988) (10)
Survival of frozen-thawed bovine red cells as a function of the permeation of glycerol and sucrose (2005) (10)
The survival of mouse oocytes shows little or no correlation with the vitrification or freezing of the external medium, but the ability of the medium to vitrify is affected by its solute concentration and by the cooling rate. (2013) (10)
Stability of mouse oocytes at -80 °C: the role of the recrystallization of intracellular ice. (2011) (9)
Centrifugal freezing. I. A system for rapid freezing of aqueous cell suspensions. (1966) (9)
Survival of frozen-thawed mouse embryos as a function of glycerol permeation☆ (1974) (9)
The use of permeability coefficients in predicting the osmotic response of human red cells during the removal of intracellular glycerol (1976) (9)
Determination of the water permeability (Lp) of mouse oocytes at -25 degrees C and its activation energy at subzero temperatures. (2009) (9)
Comparison between the temperatures of intracellular ice formation in fresh mouse oocytes and embryos and those previously subjected to a vitrification procedure. (2010) (8)
Effects on motility and aster formation of mouse spermatozoa from a reduction in oxygen concentration by oxyrase, an Escherichia coli membrane preparation (1997) (8)
The response of bovine red cells to freezing and thawing as a function of the permeation of glycerol. II. The effects of freezing (1971) (6)
Regulatory volume decrease in COS-7 cells at 22 °C and its influence on the Boyle van't Hoff relation and the determination of the osmotically inactive volume. (2012) (6)
A preliminary study of osmotic dehydration in zebrafish embryos: Implications for vitrification and ultra-fast laser warming. (2017) (6)
Chapter 10 Principles of medical cryobiology: The freezing of living cells, tissues, and organs (1996) (6)
Survival of intact Drosophila eggs at various stages of embryonic development as a function of the extent of dehydration and of intraembryonic freezing (1988) (5)
Role of solute composition and concentration vs channel size on slow-freezing injury in human red cells. I. Phase relations (1979) (5)
Permeability of the human erythrocyte to glycerol in 1 and 2 M solutions at 0 or 20 degrees C. (1976) (5)
Role of intracellular freezing in the death of cells cooled at supraoptimal rates. [Preservation of erythrocytes, bone marrow cells, and yeasts by freezing] (1976) (4)
Corrigendum to “Extra- and intra-cellular ice formation in Stage I and II Xenopus laevis oocytes” [Cryobiology 52 (2006) 401–416] (2006) (4)
Response of mammalian cells to freezing and thawing (1973) (4)
Mechanisms of Freezing Damage in Bacteriophage T4 (2008) (4)
Relative contributions of cryobiological and noncryobiological factors to “freezing” injury in human granulocytes (1982) (4)
Survival of whole fetal rat pancreases frozen to −78 and −196 °C☆ (1976) (3)
Vitrification-based cryopreservation of Drosophila embryos (1994) (3)
Responses of packed and suspended human red cells to hyperosmotic glycerol-NaCl solution at subzero temperatures in the absence of ice-formation☆☆☆ (1986) (3)
Critical tonicity determination of sperm using fluorescent staining and flow cytometry (1990) (3)
52. Sub zero water permeability, Lp, of mouse oocytes (2007) (3)
The detrimental effect of glycerol on granulocytes (1982) (3)
Ability of transplanted frozen-thawed fetal rat pancreases to reverse experimentally induced diabetes☆ (1977) (3)
Intracellular ice formation in mouse zygotes and early morulae vs. cooling rate and temperature-experimental vs. theory (2016) (3)
Invited commentary: Cryopreservation as a tool for the study of selectively bred lines in rodent behavioral genetics (1993) (3)
Procedure for the permeabilization and cryobiological preservation of Drosophila embryos (1993) (3)
Response of spermatozoa to hyposmotic stress reflects cryopreservation success (1992) (3)
Correlation between the survival of slowly frozen human red cells and the composition of the unfrozen portion of the extracellular medium at various subzero temperatures. II. Survival versus composition of extracellular medium (1976) (3)
Mechanisms of injury in frozen-thawed cells cooled at suboptimal and supraoptimal rates☆ (1976) (2)
Caspase inhibitors provide permanent protection against Fas-mediated hepatocellular injury in vivo (1998) (2)
The reduction in unfrozen fraction is more important than the increase in solute concentration as a cause of a slow-freezing injury: A position for (1985) (2)
Further studies on the survival of slowly frozen tissue culture cells as a function of the solidification of the extracellular medium (1974) (2)
2. Roles of intracellular ice formation, vitrification of cell water, and recrystallization of intracellular ice on the survival of mouse embryos and oocytes (2012) (2)
The physiological response of conidia of neurospora crassa to low temperature in the dehydrated, hydrated, or germinated state (1975) (2)
Contact between shrunken red cells as a factor in freezing injury (1988) (2)
Dehydration Preparation of Mouse Sperm for Vitrification and Rapid Laser Warming. (2016) (2)
Correlation between the survival of slowly frozen human red cells and the composition of the unfrozen portion of the extracellular medium at various subzero temperatures. I. Survival versus temperature (1976) (2)
Quantitative prediction of the osmotic response of bovine red cells during the removal of intracellular glycerol (1977) (2)
41. Regulatory volume decrease in COS-7 cells at 22 °C and it’s influence on the determination of the osmotically inactive volume Vb (2010) (2)
Comparison of the observed and calculated water loss from mouse ova at subzero temperatures (1977) (2)
Dissection of freezing injury (1971) (2)
Time-dependent sensitivity of bovine erythrocytes to changes in glycerol concentration at subzero temperatures: Simulation of freezing damage☆ (1972) (2)
DETERMINATION OF THE WATER PERMEABILITY (Lp) OF MOUSE OOCYTES AT −25°C AND ITS ACTIVATION ENERGY AT SUBZERO TEMPERATURES✰, ,+ (2013) (1)
Interactions of cooling and warming velocity on the survival of frozen-thawed human red cells (1974) (1)
The response of bovine red cells to freezing and thawing as a function of the permeation of glycerol. I. Kinetics of glycerol permeation (1971) (1)
Preservation of mammalian germ plasm by freezing (1978) (1)
93. Survival of mouse oocytes suspended in EAFS 10/10 vitrification solution after being cooled to −196 °C on Cryotops at rates ranging from 95 °C/min to 70,000 °C/min and warmed at 610 °C/min to 118,000 °C/min (2009) (1)
Cryopreservation of human granulocytes using glycerol (1979) (1)
Effect of plasma on the recovery and FDA survival of human granulocytes incubated at 37 degrees C after exposure to phosphate-buffered saline or glycerol. (1986) (1)
Survival of fetal rat pancreases frozen to-78 and-196 ° ( freezing of organs / transplantation of pancreas / diabetes / cryobiology ) (2003) (1)
94. The temperature of intracellular ice formation in mouse embryos as a function of the developmental stage (2009) (1)
The response of granulocytes to osmotic shrinkage (1982) (1)
17. Do biological cells and tissues cryopreserved in biorepositories and thawed differ significantly from the original materials (2010) (1)
ESR (electron spin resonance)-determined osmotic behavior of bull spermatozoa (1990) (1)
40. Rectification of the water permeability in COS-7 cells at 22 C, 10 C, and 0 C (2010) (1)
Mechanism-s: of injury in frozen and frc.zen-dried cells (1963) (1)
Stanley Paul Leibo – Cryobiologist. (2014) (1)
39. Simple, inexpensive measurement of very rapid cooling and warming rates (2009) (1)
Does the unfrozen water fraction play a role in freezing injury, or is water activity the main culprit?☆ (1988) (1)
Biophysical and biological factors determining the ability to achieve long-term cryobiological preservation (1997) (1)
Does the magnitude of the unfrozen fraction affect the survival of slowly frozen mouse eight-cell embryos? II. Experimental☆ (1984) (1)
Fundamental and cellular aspects of freezing and thawing (1980) (0)
C-1015: Implications of the consequences of laser-induced ultra-rapid warming of mouse oocytes and embryos to vitrification theory and to the successful vitrification of other cell types (2014) (0)
Visualization of structural alterations during the warming of frozen cells (1972) (0)
Toward the cryopreservation of Zebrafish embryos: Tolerance to osmotic dehydration (2016) (0)
037 Relative importance of cooling and warming rate in obtaining high survivals of mouse oocytes and embryos after vitrification (2013) (0)
Peter Mazur (1928–2015) (2021) (0)
Do embryos respond as ideal osmometers during slow freezing (1986) (0)
Erratum to abstract “Intracellular ice formation in mouse zygotes and early morulae vs. cooling rate and temperature–Experimental vs. theory” [Cryobiology 63(3) 2011 329] (2012) (0)
The role of water and solute permeability and of osmosis in the response of cells to freezing (1987) (0)
033 Survival of mouse oocytes shows little or no correlation with the vitrification or freezing of the external medium (2013) (0)
093 Ultra rapid warming of cryo samples using an IR laser pulse (2013) (0)
Corrigendum to “Simple, inexpensive attainment and measurement of very high cooling and warming rates” [Cryobiology 61 (2010) 231–233] (2012) (0)
C-1014: High survival of mouse oocytes and preimplantation embryos after vitrification in the absence of permeating cryoprotectants and ultra-rapid warming by an IR laser pulse (2014) (0)
43. Effect of warming rate on the survival of vitrified mouse oocytes and on the recrystallization of intracellular ice (2008) (0)
STUDIES ON THE EFFECTS OF SUBZERO TEMPERATURES ON T H E VIABILITY OF SPORES OF ASPERGILLUS FLAVUS I. Tm~ EFr~cr oF RAam Or WA~mG* BY PETER MAZUR~ (2003) (0)
The influence of cryoprotective agents on the structure of freeze-cleaved yeast (1971) (0)
Functional survival of mouse oocytes and 8-cell embryos after vitrification in 1×, 0.75×, 0.5×, and 0.33× EAFS vitrification media and warming at an exceedingly high rate of 117,500 °C/min (2011) (0)
80. The permeability to water of Stage I and II immature zebrafish oocytes (2010) (0)
Physiological Response ofNeurospora Conidia toFreezing in theDehydrated, Hydrated, orGerminated State (1978) (0)
95. Effect of the expression of aquaporins 1 and 3 in mouse MII oocytes on the nucleation temperature for intracellular ice formation (2009) (0)
Effects of low temperatures on biological membranes: Edited by G. J. Morris and A. Clarke. Academic Press, New York, 1981. 456 pp., $55.00☆ (1984) (0)
Calculation of water loss and intracellular freezing in cells frozen by two-step procedures☆ (1977) (0)
79. Mouse oocytes exhibit nearly 90% survival after cooling to −196 °C in diluted vitrification solutions, provided that they are warmed at exceedingly high rates (2010) (0)
PETER MAZUR Kinetics of Water Loss 349 logarithms of both sides and differentiating with respect to temperature , we obtain d In p ~ d In p ° d In (2003) (0)
W095 RISK FACTORS PREDISPOSING TO ABRUPTIO PLACENTAE. MATERNAL AND FETAL OUTCOME (2012) (0)
Preliminary attempts to assess the ability of fetal mouse thymuses to function after freezing and thawing (1979) (0)
Functional capacity and cryopreservation of fetal rat pancreas in streptozotocin-diabetes. [Effectiveness of transplantation of fetal pancreas for control of diabetes in adult rats] (1976) (0)
Response : Maternal Influences on Mouse Embryos and Preservation of Mutant Strains by Freezing (1973) (0)
C-1002: Survivals approach 100% for mouse oocytes suspended in one-third concentration of vitrification media, vitrified, and warmed ultra-rapidly by an IR laser pulse (2014) (0)
Computer-assisted techniques for the estimation of cell volumes during the permeation of glycerol into multicellular mouse embryos (1977) (0)
A06 Plenary Lecture 2 : Cryosurgery as the anti-christ of cryopreservation (2014) (0)
034 Survival of mouse oocytes after cooling in lower cryoprotectant concentrations by ultra rapid warming using an IR laser pulse (2013) (0)
48. Detection of intracellular ice formation in cells of the yeast Saccharomyces cerevisiae by differential scanning calorimetry (2008) (0)
87. The triad of evidence that intracellular ice is the cause of death in COS-7 tissue culture cells rapidly cooled to −70 °C. (I): The observed occurrence of intracellular ice as a function of temperature and cooling rate (2011) (0)

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