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Immobilization of cells

Dr Suresh Solleti
Dr Suresh Solleti

Immobilization of cells-For JNTUA B Pharmacy students

Science
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Introduction to Immobilization of cells Dr SV Suresh Kumar Professor of Pharmacognosy CES College of Pharmacy, Kurnool Andhra Pradesh
Immobilization of cells  Immobilization of cells means the encapsulation of cells in culture by polymers like, sodium alginate, calcium alginate, collagen, poly styrene, agar or cellulose derivatives, so that cells are not able to divide but remain viable for so many weeks.  One of the major problems in cell culture based process for secondary metabolite production is high production cost due to slow growth of cells, low product yield, genetic instability of the selected cells and intra cellular accumulation of the product. Some of these problems can be reduced by immobilized cell culture.  In this technique cells are confined within a reactor system, preventing their entry into the mobile phase which carries the substrate and products/nutrients.
 Immobilization is only relevant where the production involves two stages; in the first stage conditions are optimized for biomass production by suspension culture and in the second stage conditions are optimized for product formation by immobilized cells.
The advantages of Immobilized cell culture are-  It may enable prolonged use of biomass;  By immobilization of cells the cell density in a bioreactor can be increased 2-4 times that in suspension cultures (10- 30 g/l) and this enables the use of small reactors, reducing the cost of medium, equipment installation and downstream processing;  The entrapped cells are protected against shear forces and, consequently, a simple bioreactor design may be used;  It separates the cells from the medium and, therefore, if the product is extracellular it can simplify downstream processing;  It uncouples growth and product formation which allows product optimization without affecting growth;
 The non-dividing immobilized cells are less prone to genetic changes and, therefore, provide a stable production rate;  It minimizes fluid viscosity, which in cell suspensions cause mixing and aeration problems; and  It promotes secondary metabolite secretion in some cases.  An immobilized system which could maintain viable cells over an extended.  period of time and release the bulk of the product into the extracellular medium in a stable form could dramatically reduce the cost of phytochemical production.
A wide range of bioreactors have been designed to culture immobilized cells.The best design to use depends on the method of immobilization.  Entrapment of cells in gel or behind semi-permeable membranes is the most popular method for immobilization of plant cells.  Some polymers used to entrap plant cells are alginate, agar, agarose and carrageenan. Of these, alginate has been most widely used because it can be polymerized at room temperature using Ca 2+.  Polyurethane foam has also been used to immobilize a range of plant cells. Alternatively, plant cells can be entrapped by inclusion within membrane reactors.
 A semi-permeable membrane is introduced between the cells and the recirculating medium so that the cells can be packed at a very high density under very mild conditions. Some designs of membrane reactors are shown in Figure. Fig: Flat plate membrane reactor with one side flow of nutrients
Fig B: Flat plate membrane reactor with two side flow of nutrients
Fig C:Multi membrane reactor system.Fig C:Multi membrane reactor system. Fig C:Multi membrane reactor system.
Immobilization of cells on the surface of an inert support, such as fibreglass mats and unwoven short fibre polyester, has also been examined for in vitro production of secondary metabolites.  For surface immobilization of cells, a bioreactor (air lift or mechanically agitated design), provided with the support matrix, is inoculated with a plant cell suspension of suitable density and operated for an initial period as a suspension bioreactor. During this period virtually all cells spontaneously adhere to the surface of the support.
Stirred tank rector and air lift reactor
 Binding of the cells to the immobilizing support is regarded as a two-step process. In the first stage, cells are spontaneously attracted to the support surface due to vanderWaal's force aided by entrapment of cells in pores or other irregularities on the surface of the support. Subsequently, the cells appear to secrete a mucilaginous substance which firmly cements them to the support surface.  The immobilized cells grow as a more or less continuous layer or tissue-like structure on the surface of the support matrix.  Surface immobilization promotes the natural tendency of plant cells to aggregate which may improve the synthesis and accumulation of secondary metabolites.
 special advantage of this method over the other methods of immobilization of cells is the absence of any physical restriction to mass transfer between the culture medium and the biomass surface.  Since the surface immobilized cells grow on the surface of the support matrix, it should facilitate visual monitoring of the conditions, distribution and extent of the biomass and to routinely sample the biomass, if desired.
Fig: Hollow fibre reactor for immobilized cell culture
 Surface immobilization promotes the natural tendency of plant cells to aggregate which may improve the synthesis and accumulation of secondary metabolites.  A special advantage of this method over the other methods of immobilization of cells is the absence of any physical restriction to mass transfer between the culture medium and the biomass surface.  Since the surface immobilized cells grow on the surface of the support matrix, it should facilitate visual monitoring of the conditions, distribution and extent of the biomass and to routinely sample the biomass, if desired.
Applications  The accumulation of serpentine by C. Roseus and anthraquinones by Morinda citrifolia were enhanced in the immobilized state when compared with cell suspensions.  Capsicum frutescens cells immobilized on polyurethane foam produced 50 times more capsaicin than suspension cultures.  Immobilization of the cells of Dioscorea deltoidea by passively entrapping them into polyurethane foam cubes and growing them in a medium containing 3% sucrose.This increased diosgenin production by 40% over the suspension cultures.  Immobilized cells can also serve as biocatalysts for biotransformation.  The immobilized cells of Digitalis lanata maintained their capability for enzymatic conversion of β-methyldigitoxin to β - methyldigoxin for a period of 61 days.
Some of the limitations of an immobilized cell system are:  Immobilization is normally limited to systems where production is decoupled from cell growth;  The initial biomass must be produced in suspension cultures;  Secretion of products into the external medium is imperative;  When secretion occurs there may be a problem of extracellular degradation of product; and  When gel entrapment is used, the gel matrix introduces an additional diffusion barrier.

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Immobilization of cells

  • 1. Introduction to Immobilization of cells Dr SV Suresh Kumar Professor of Pharmacognosy CES College of Pharmacy, Kurnool Andhra Pradesh
  • 2. Immobilization of cells  Immobilization of cells means the encapsulation of cells in culture by polymers like, sodium alginate, calcium alginate, collagen, poly styrene, agar or cellulose derivatives, so that cells are not able to divide but remain viable for so many weeks.  One of the major problems in cell culture based process for secondary metabolite production is high production cost due to slow growth of cells, low product yield, genetic instability of the selected cells and intra cellular accumulation of the product. Some of these problems can be reduced by immobilized cell culture.  In this technique cells are confined within a reactor system, preventing their entry into the mobile phase which carries the substrate and products/nutrients.
  • 3.  Immobilization is only relevant where the production involves two stages; in the first stage conditions are optimized for biomass production by suspension culture and in the second stage conditions are optimized for product formation by immobilized cells.
  • 4. The advantages of Immobilized cell culture are-  It may enable prolonged use of biomass;  By immobilization of cells the cell density in a bioreactor can be increased 2-4 times that in suspension cultures (10- 30 g/l) and this enables the use of small reactors, reducing the cost of medium, equipment installation and downstream processing;  The entrapped cells are protected against shear forces and, consequently, a simple bioreactor design may be used;  It separates the cells from the medium and, therefore, if the product is extracellular it can simplify downstream processing;  It uncouples growth and product formation which allows product optimization without affecting growth;
  • 5.  The non-dividing immobilized cells are less prone to genetic changes and, therefore, provide a stable production rate;  It minimizes fluid viscosity, which in cell suspensions cause mixing and aeration problems; and  It promotes secondary metabolite secretion in some cases.  An immobilized system which could maintain viable cells over an extended.  period of time and release the bulk of the product into the extracellular medium in a stable form could dramatically reduce the cost of phytochemical production.
  • 6. A wide range of bioreactors have been designed to culture immobilized cells.The best design to use depends on the method of immobilization.  Entrapment of cells in gel or behind semi-permeable membranes is the most popular method for immobilization of plant cells.  Some polymers used to entrap plant cells are alginate, agar, agarose and carrageenan. Of these, alginate has been most widely used because it can be polymerized at room temperature using Ca 2+.  Polyurethane foam has also been used to immobilize a range of plant cells. Alternatively, plant cells can be entrapped by inclusion within membrane reactors.
  • 7.  A semi-permeable membrane is introduced between the cells and the recirculating medium so that the cells can be packed at a very high density under very mild conditions. Some designs of membrane reactors are shown in Figure. Fig: Flat plate membrane reactor with one side flow of nutrients
  • 8. Fig B: Flat plate membrane reactor with two side flow of nutrients
  • 9. Fig C:Multi membrane reactor system.Fig C:Multi membrane reactor system. Fig C:Multi membrane reactor system.
  • 10. Immobilization of cells on the surface of an inert support, such as fibreglass mats and unwoven short fibre polyester, has also been examined for in vitro production of secondary metabolites.  For surface immobilization of cells, a bioreactor (air lift or mechanically agitated design), provided with the support matrix, is inoculated with a plant cell suspension of suitable density and operated for an initial period as a suspension bioreactor. During this period virtually all cells spontaneously adhere to the surface of the support.
  • 11.
  • 12. Stirred tank rector and air lift reactor
  • 13.  Binding of the cells to the immobilizing support is regarded as a two-step process. In the first stage, cells are spontaneously attracted to the support surface due to vanderWaal's force aided by entrapment of cells in pores or other irregularities on the surface of the support. Subsequently, the cells appear to secrete a mucilaginous substance which firmly cements them to the support surface.  The immobilized cells grow as a more or less continuous layer or tissue-like structure on the surface of the support matrix.  Surface immobilization promotes the natural tendency of plant cells to aggregate which may improve the synthesis and accumulation of secondary metabolites.
  • 14.  special advantage of this method over the other methods of immobilization of cells is the absence of any physical restriction to mass transfer between the culture medium and the biomass surface.  Since the surface immobilized cells grow on the surface of the support matrix, it should facilitate visual monitoring of the conditions, distribution and extent of the biomass and to routinely sample the biomass, if desired.
  • 15. Fig: Hollow fibre reactor for immobilized cell culture
  • 16.  Surface immobilization promotes the natural tendency of plant cells to aggregate which may improve the synthesis and accumulation of secondary metabolites.  A special advantage of this method over the other methods of immobilization of cells is the absence of any physical restriction to mass transfer between the culture medium and the biomass surface.  Since the surface immobilized cells grow on the surface of the support matrix, it should facilitate visual monitoring of the conditions, distribution and extent of the biomass and to routinely sample the biomass, if desired.
  • 17. Applications  The accumulation of serpentine by C. Roseus and anthraquinones by Morinda citrifolia were enhanced in the immobilized state when compared with cell suspensions.  Capsicum frutescens cells immobilized on polyurethane foam produced 50 times more capsaicin than suspension cultures.  Immobilization of the cells of Dioscorea deltoidea by passively entrapping them into polyurethane foam cubes and growing them in a medium containing 3% sucrose.This increased diosgenin production by 40% over the suspension cultures.  Immobilized cells can also serve as biocatalysts for biotransformation.  The immobilized cells of Digitalis lanata maintained their capability for enzymatic conversion of β-methyldigitoxin to β - methyldigoxin for a period of 61 days.
  • 18. Some of the limitations of an immobilized cell system are:  Immobilization is normally limited to systems where production is decoupled from cell growth;  The initial biomass must be produced in suspension cultures;  Secretion of products into the external medium is imperative;  When secretion occurs there may be a problem of extracellular degradation of product; and  When gel entrapment is used, the gel matrix introduces an additional diffusion barrier.