Definition
Cryobiology
is the branch of biology that studies the effects of low and ultra-low
temperatures on living cells, tissues, organs, and biological systems. It
mainly deals with understanding cellular responses to freezing and thawing and
developing methods for long-term preservation of biological material at
sub-zero temperatures, especially using liquid nitrogen (−196°C).
Basic Principle of Cryobiology
At
extremely low temperatures, metabolic activities, enzymatic reactions, and
biochemical processes slow down or stop completely. This state allows cells
to remain viable for long periods without genetic or physiological changes,
provided freezing and thawing are properly controlled.
Cellular Events During Freezing
Freezing
causes both physical and biochemical stress in cells:
1.
Ice
Crystal Formation
o Extracellular ice forms first,
increasing solute concentration outside the cell.
o This creates an osmotic gradient,
causing water to move out of the cell.
o Intracellular ice formation is
lethal as it damages membranes and organelles.
2.
Osmotic
Stress
o Excessive dehydration or rapid
rehydration during thawing can rupture membranes.
3.
Solution
Effects Injury
o High solute concentration during
freezing can denature proteins and disrupt membranes.
Cryoprotectants
reduce freezing damage by preventing ice crystal formation.
Types:
- Penetrating cryoprotectants
- Glycerol
- Dimethyl sulfoxide (DMSO)
- Ethylene glycol
- Non-penetrating cryoprotectants
Functions:
- Reduce ice nucleation
- Stabilize proteins and
membranes
- Control osmotic balance
Cryopreservation Techniques
- Cooling rate: ~1°C/min
- Allows controlled dehydration
- Commonly used for plant
tissues, microorganisms, sperm, embryos
- Faster cooling, limited
dehydration
- Risk of intracellular ice
formation
3. Vitrification (High-Yield Topic ⭐)
- Ultra-rapid cooling with high
cryoprotectant concentration
- Water solidifies into a glass-like
amorphous state without ice crystals
- Widely used in embryo and
oocyte preservation
Storage
- Biological samples are stored
in:
- Liquid nitrogen (−196°C)
- Nitrogen vapor phase (−150°C
to −170°C)
Thawing Process
- Rapid thawing is preferred to
prevent recrystallization.
- Cryoprotectants must be removed
gradually to avoid osmotic shock.
Comparison: Slow Freezing vs Vitrification
|
Feature |
Slow Freezing |
Vitrification |
|
Definition |
Controlled
cooling method where cells are frozen gradually |
Ultra-rapid
cooling method converting solution into a glass-like state |
|
Cooling rate |
Slow
(≈ 0.5–1°C per minute) |
Extremely
fast (thousands of °C per minute) |
|
Ice crystal formation |
Small
extracellular ice crystals may form |
No ice crystals formed |
|
Mechanism |
Gradual
dehydration of cells before freezing |
Solidification
without crystallization |
|
Cryoprotectant concentration |
Low
to moderate |
Very high |
|
Type of cryoprotectants |
Glycerol,
DMSO (low concentration) |
DMSO,
ethylene glycol + sugars (high concentration) |
|
Cell dehydration |
Occurs
gradually |
Minimal
dehydration |
|
Risk of damage |
Osmotic
injury, ice crystal damage |
Cryoprotectant
toxicity |
|
Storage temperature |
−196°C
(liquid nitrogen) |
−196°C
(liquid nitrogen) |
|
Equipment required |
Programmable
freezer required |
Simple
equipment (no freezer needed) |
|
Technical complexity |
Technically
simpler |
Requires
high skill and precision |
|
Cell survival rate |
Moderate |
Very high |
|
Common applications |
Microorganisms,
plant tissues, sperm |
Embryos,
oocytes, stem cells |
|
Cost |
Relatively
low |
Relatively
high |
|
Suitability |
Large
sample volumes |
Small
sample volumes |
|
Recrystallization during thawing |
Possible |
Minimal |
Applications of Cryobiology
1.
Medical
& Clinical
o Cryopreservation of sperm, ova,
embryos
o Blood and bone marrow preservation
2.
Plant
Biotechnology
o Preservation of rare and endangered
species
o Storage of somatic embryos and
meristems
3.
Microbiology
o Long-term storage of bacteria,
fungi, and viruses
4.
Animal
Biotechnology
o Preservation of genetic material
o Conservation breeding programs
Advantages
- Long-term preservation without
genetic alteration
- Maintains cell viability and
metabolic integrity
- Reduces cost and labor of
continuous culture maintenance
Limitations
- Cryoprotectant toxicity
- Ice crystal damage
- Requires precise temperature
control and expertise
CSIR-NET Important Points (Quick Revision)
- Storage temperature: −196°C
- Most common cryoprotectants: DMSO,
glycerol
- Most lethal damage: intracellular
ice formation
- Best method to avoid ice
crystals: Vitrification
- Fast thawing > slow thawing
Conclusion
Cryobiology
plays a crucial role in biotechnology, medicine, conservation biology, and
reproductive science. Understanding cellular responses to freezing,
cryoprotectant action, and preservation techniques is essential for successful
cryopreservation, making cryobiology a high-scoring topic in CSIR-NET and other
competitive life-science examinations.
Good informative
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