Cryopreservation: Principle, Process, limitations and precautions




Principle of Cryopreservation:

  • Cryopreservation is a process of preserving or storing cells, tissues, organs or any other biological materials from any potential damage by maintaining the materials at very low temperature (typically -80 °C using solid CO2 or −196 °C using liquid Nitrogen.
  • In cryopreservation, very low temperatures is used to preserve living cells and tissues and maintain their viability. Unprotected freezing is normally lethal.
  • Cryopreservation is based on the conversion of water present in the cells from a liquid to a solid state.
  • When cooling below 0°C, the biological effects are dominated by the freezing of water, which typically constitutes at least 80% of the tissue mass.
  • The cell water requires much lower temperature to freeze (even up to -68°C) due to the presence of salts and organic molecules in the cells, in comparison to the freezing point of pure water (around 0°C).
  • The metabolic processes and biological divisions in the cells/tissues are almost stopped when stored at low temperature.

Process of Cryopreservation:

  • The cryopreservation of plant cell culture followed by the regeneration of plants involves the following steps:
    • 1. Development of sterile tissue cultures
    • 2. Addition of cryoprotectants and pre-treatment
    • 3. Freezing
    • 4. Storage
    • 5. Thawing
    • 6. Re-culture
    • 7. Measurement of viability
    • 8. Plant regeneration

The features of the above steps are described as follows:

step I: Development of sterile tissue culture:

  • One of the important steps is the selection of plant species with reference to morphological and physiological characters .
  • It directly influence the ability of explant to survive cryopreservation.
  • Any tissue from a plant can be employed for cryopreservation e.g. meristems, endosperms, embryos, ovules, seeds, cultured plant cells, calluses, protoplasts.
  • Out of these, meristematic cells and suspension cell cultures which are in the late lag phase or log phase are most appropriate.

step II: Addition of cryoprotectants and pre-treatment:

  • The compounds that can prevent the damage caused to cells by freezing or thawing are called as cryoprotectants.
  • Cryoprotectants reduce the freezing point and super-cooling point of water.
  • As a result, the ice crystal formation is delayed during the process of cryopreservation.
  • Cryoprotectants used are dimethyl sulfoxide (DMSO), glycerol, ethylene, propylene, sucrose, mannose, glucose, proline and acetamide.
  • Among them, DMSO, sucrose and glycerol are most commonly used.
  • Generally, a mixture of cryoprotectants instead of a single one is preferred for more effective cryopreservation without damage to cells/tissues.

step III: Freezing:

  • The sensitivity of the cells to low temperature is variable and largely relies on the plant species.
  • The different types of freezing methods used are as follows:
  • 1. Slow-freezing method:
    • The tissue or the essential plant material is allowed to slowly freeze at a slow cooling rates of 0.5-5°C/min from 0°C to -100°C.
    • Then it is transferred to liquid nitrogen.
    •  Slow-freezing method facilitates the flow of water from the cells to the outside.
    • This avoids intracellular freezing and promotes extracellular ice formation.
    • Because of this, the plant cells are partially dehydrated and can survive better.
    • The slow-freezing technique is successfully employed for the cryopreservation of suspension cultures.
  • 2. Rapid freezing method:
    • This process is quite simple.
    • In this technique, the vial containing plant material is plunged into liquid nitrogen.
    • During rapid freezing,  reduction in temperature from -300° to -1000°C/min occurs.
    • The freezing process occurs so quickly that small ice crystals are formed within the cells.
    •  In addition to it, the growth of intracellular ice crystals is also minimum.
    • Rapid freezing technique is applied for the cryopreservation of shoot tips and somatic embryos.
  • 3. Stepwise freezing method:
    • This technique is a combination of slow and rapid freezing procedures having the advantages of both, and occurs in a stepwise manner.
    • Firstly, the plant material is cooled to an intermediate temperature.
    • Then it is kept there for about 30 minutes.
    • Finally, it is rapidly cooled by plunging it into liquid nitrogen.
    • Stepwise freezing method has been successfully applied for cryopreservation of suspension cultures, shoot apices and buds.
  • 4. Dry freezing method:
    • It has been reported that the non-germinated dry seeds can survive freezing at very low temperature in comparison to water-imbibing seeds which are sensitive to cryogenic injuries.
    •  In a similar way, dehydrated cells are observed to have a better survival rate after cryopreservation.

step IV: Storage:

  • The frozen cultures should be maintained at the specific temperature.
  • Generally, the frozen cells/tissues are maintained at temperatures in the range of -70 to -196°C for storage.
  • Although, with temperatures above -130°C, ice crystal growth may take place inside the cells which decreases viability of cells.
  • The ideal storage is done in liquid N2 refrigerator at 150°C in the vapour phase, or at   -196°C in the liquid phase.
  • The final aim of storage is to halt all the cellular metabolic activities and preserve their viability.
  • The temperature at -196°C in liquid nitrogen is regarded as ideal for long term storage.
  • A regular and constant supply of liquid nitrogen to the liquid nitrogen refrigerator is necessary.
  • It is essential to check the viability of the germplasm time and again in some samples.
  • Proper documentation of the germplasm storage should be done.

step V: Thawing:

  • Thawing is usually performed by plunging the frozen samples in ampoules into a warm water (temperature 37-45°C) bath with robust swirling.
  • By this process, rapid thawing (at the rate of 500- 750°C min-1) takes place, and this preserves the cells from the damaging effects from ice crystal formation.
  • As soon as the thawing occurs (ice completely melts), the ampoules are transferred to a water bath at temperature 20-25°C at the same instant.
  • The cells get damaged if left in warm (37-45°C) water bath for long time.
  • For the cryopreserved material (cells/tissues) where the water content has been decreased to an optimal level before freezing, the process of thawing becomes less vital.

step VI: Re-culture:

  • To remove cryoprotectants, the thawed germplasm is washed various times.
  • Following standard procedures, this material is then re-cultured in a fresh medium.
  • In some cases, the direct culture of  the thawed material is preferred without washing.
  •  It is so because certain vital substances, released from the cells during freezing, are assumed to enhance in vitro cultures.

step VII: Measurement of viability:

  • The measurement of survival or viability of the frozen materials can be performed at any stage of cryopreservation or after thawing or re-culture.
  • The techniques used to determine viability of cryopreserved cells are the same as applied for cell cultures.
  • The commonly used techniques are staining techniques using triphenyl tetrazolium chloride (TTC), Evan’s blue and fluorescein diacetate (FDA).
  • The entry of cryopreserved cells into cell division and regrowth in culture is the best indicator to measure the viability of them.
  • This can be evaluated by the using following expression.

step VIII: Plant regeneration:

  • The regeneration of the desired plant is the ultimate purpose of cryopreservation of germplasm.
  • The cryopreserved cells/tissues have to be carefully nursed, and grown for appropriate plant growth and regeneration .
  • Along with maintenance of proper environmental conditions, addition of certain growth promoting substances is often essential for successful plant regeneration.

Limitations for Cryopreservation:

  • An individual with good technical and theoretical knowledge of living plant cells as well as cryopreservation method is required.

Precautions for cryopreservation:

  • The formation of ice crystals inside the cells should be prevented as they are responsible for causing injury to the organelles and the cell.
  • Cells might be damaged if the intracellular concentration of solutes is high.
  • Leakage of certain solutes from the cell during freezing should be checked.
  • The physiological status of the plant material is also essential.

Cryopreservation: Principle, Process, limitations and precautions