Download - Immobilized Cells
Industrial Microbiology
INDM 4005
Lecture 15
24/03/04
Process variables
• Cell immobilisation
Introduction
• In 1995 the symposium,
Immobilised Cells: Basics and Applications
was organised under the auspices of the working party of applied catalysis of the European Federation of Biotechnology
• Symposium covered the path from basic physiological research to bioprocess applications
• Immobilised cells, Springer lab manual Wijffels, R.H
Introduction• In a previous lecture we learnt that higher dilution rates can lead to
- higher biomass productivity
But
- higher substrate concentrations in the effluent and lower biomass concentrations in the reactor
• When the dilution rate exceeds the critical dilution rate then washout occurs.
IntroductionThese factors result in a number of problems.
E.g in continuous wastewater treatment processes:
Minimum reactor volume is set by the critical dilution rate.
High dilution rates will lead to an effluent containing high concentrations of "substrate" and the effluent will therefore contain not have been treated properly.
Low cell concentrations at high dilution rates will also make the reactor sensitive to inhibitors in the feed. Inhibitors would cause the specific growth rate of the cells to drop and cause the cells to washout. The lower the concentration of cells, then the faster the cells will washout.
Introduction
• In chemostat processes similar consequences can occur. If the substrates are expensive, e.g animal cell culture, high dilution rates can dramatically affect process profitablility.
• Immobilizing cells in the fermenter ensures that cells do not washout when the critical dilution rate is exceeded.
• By immobilizing the cells in the fermenter, high cell numbers can be maintained at dilution rates which exceed µm.
• Therefore in an immobilised continuous fermenter system high cell counts can be maintained leading to higher biomass productivity as compared to a normal chemostat.
Advantages over suspension cultures
(1). Immobilisation provides high cell concentration
(2). Immobilisation provides cell reuse and eliminates the costly processes of cell recovery and cell recycle
(3). Immobilisation eliminates cell washout problems at high dilution rates
(4). Combination of high cell concentrations and high flow rates allows high volumetric productivities
(5). Favourable microenvironmental conditions
(6). Improves genetic stability
(7). Protects against shear damage
Advantages of immobilised cell reactors
• Being able to maintain high cell concentrations in the reactor at high dilution rates provides immobilised cell bioreactors with advantages over chemostats.
More biomass means that the fermenter contains more biocatalysts, thereby high bioconversion rates can be achieved.
Immobilised cell bioreactors are also more stable than chemostats.
Inhibitor enters inlet feed
Immobilised bioreactor
Chemostat
Time
Biomass
A higher cell concentration in the immobilised bioreactor prevents the microbial population from
completely washing out.
• In a chemostat, a temporary (transient) increase in the dilution rate will cause a rapid drop in cell numbers. The entry of a slug of toxic substances in the feed will have the same effect. It will take time for the cells numbers to build up again. Since the cells are not as easily washed out of an immobilized cell reactor, the recovery time will be more quicker and fall in biomass concentration will be smaller.
• If the toxic substance is a substrate (eg. in the waste treatment of toxic wastewaters), high cell concentrations will be able to more rapidly utilize any slug of toxins which may enter the reactor. The resultant sag in biomass concentration will be smaller and the rise in concentration of the inhibitory substance will also be much smaller with immobilized cell reactors.
• The higher productivity and greater stability of immobilized fermenters thus leads to smaller fermenter requirements and considerable savings in
capital and energy costs.
Limitations(1). Often the product of interest has to be excreted
from the cell
(2). Complications with diffusional limitations
(3). Control of microenvironment conditions is difficult due to heterogeneity in the system
(4). Growth and gas evolution can lead to mechanical disruption of the immobilised matrix
Types of immobilisation
• Active immobilisation
• Passive immobilisation
Active immobilisation
• Is entrapment or binding of cells by physical or chemical forces
• Physical entrapment within porous matrices is the most widely used method of cell immobilisation
• Immobilised beads should be porous enough to allow transport of substrates and products in and out of the beads
Active immobilisation
Beads can be prepared by
1) Gelation of polymers
2) Precipitation of polymers
3) Ion exchange gelation
4) Polycondensation
5) Polymerisation
6) Encapsulation
Passive immobilisation• Biological films
• The multilayered growth of cells on solid support surfaces
• The support material can be inert or biologically active
• Biofilm formation is common in natural and industrial fermentation systems, i.e biological wastewater treatment and mold fermentations
Description of support materialThe Hydrogels
Natural
Carrageenan
Alginate
Agar
Gelatin
Synthetic
Polyvinyl alcohol
Polyurethane
Polyethylene glycol
Carrageenan
• Extracted from seaweed and a gel is derived by stabilisation with K+ ions or by thermogelation (reducing the temperature at low ion concentration)
• Carrageenan consists of alternating structures of D-galactose 4-sulphate and 3,6-anhydro-D-galactose 2-sulphate
• Carrageenan matrix becomes weak when disturbing ions are present
The seaweed Chondrus crispus. Image width ca 15 cm.
Alginate
• Alginate is derived from algae and is stabilised by divalent cations
• It consists of 1-4 bonded D-mannuronic and L-guluronic acids groups
• Gels are formed due to binding of divalent metal cations to the guluronic acids groups
• Most commonly used cation is Ca2+
Laminaria hyperborea forest. Image width ca 3 m.
General characteristics of natural hydrogels
• Cells survive mild immobilisation methods• Cells grow easily in matrix• The diffusion coefficients of substrates are high• Relatively cheap• The matrixes are soluble• Relatively weak• Biodegradable
Synthetic gels
• Lately several gel-forming synthetic pre-polymers have been developed
• Polymerisation or crosslinking is carried out in the presence of the microorganism
• Rather hostile process leads to activity losses
General characteristics of synthetic gels
• Low or no solubility
• Low or no biodegradability
• Strong
• Diffusivity of substrates relatively low
• Recovery of immobilised cells relatively low
• Relatively expensive
Bioencapsulation or Gel Immobilised cells
Process intensification• results in high level of biomass which
improves productivity• cells recovered easily• higher flow-through rates in continuous
systems
Protection • cells protected from stress e.g. pH, temp etc.
useful in inoculum delivery
Immobilised vs free cells
• YEASTS - immobilised produce more ethanol
• RECOMBINANT CULTURE - plasmid stability improved on immobilisation
Bead entrapment - gel matrix and products
Non-toxic• Agarose• Calcium alginate• Carrageenan
can be toxic• Polyacrylamide -• Polyvinyl alcohol
PRODUCTS• antibiotics• ethanol• citric acid• penicillin• phenol degradation
Entrapment (beads) vs encapsulation (capsules)
Entrapment
• cells leak
• large beads, surface layer of growth
• biomass disrupts matrix (limits to 25% by volume)
• calcium alginate bead containing cells formed first
• then coated in poly-L-lysine crosslinked with sodium alginate
• finally calcium alginate core dissolved using sodium citrate method
Pregel dissolving 2 step method
Liquid-droplet one step method
Opposite of conventional bead formation• cells + curing solution (calcium chloride) dropped
into sodium alginate solution
• results in a gel skin formed on surface of the drop with cells contained in liquid centre
• cells are allowed to grow to increase level of biomass encapsulated
Mass production - industrial scale
Dropping methods have limitation - can be improved by
• increasing number of needles• liquid jet-based method - form drops by
– vibration – cut with wires
• Centrifugal force vs gravity• concentric - cells, polymer and air extruded separately
Types of immobilized cell reactors
• There are many types of immobilized cell reactors either in use or under development.
• In this section we will look at four major classes of immobilized cell reactors:
Cell recycle systems
Fixed bed reactors
Fluidized bed reactors
Flocculated cell systems
Cell recycle systems
• In a fermenter with cell recycle the cells are separated from the effluent and then recycled back to the fermenter; thus minimising cell removal from the fermenter:
Effluent
Biomass recycle
Fermenter
Fresh feed
Biomass separation system
Cell recycle system
Cell recycle systems• Cell recycle is used in activated sludge systems. A portion
of the cells are separated in a settling tank and returned to the activated sludge fermenter.
• Biomass recycling for product or biomass production is more difficult due to the need for maintaining sterility during cell separation. Centrifugation which is a faster process than settling would be used to separate the cells.
• Biomass recycle systems can be easily modelled.
Fixed bed reactors• In fixed bed fermenters, the cells are immobilized by
absorption on or entrapment in solid, non-moving solid surfaces.
Fixed bed reactors• In one type of fixed bed fermenter, the cells are immobilized
on the surfaces of immobile solid particles such as
plastic blocks
concrete blocks
wood shavings or
fibrous material such as plastic or glass wool.
• The liquid feed is either pumped through or allowed to trickle over the surface of the solids where the immobilized cells convert the substrates into products.
Fixed bed reactors
• Once steady state has been reached there will be a continuous cell loss from the solid surfaces. These types of fermenters are widely used in waste treatment
• In other types of fixed-bed fermenters, the cells are immobilized in solidified gels such as agar or carrageenin
Fixed bed reactors• In these fermenters, the cells are physically trapped inside
the pores of the gels and thus giving better cell retention and a large effective surface area for cell entrapment.
• In order to increase the surface area for cell immobilization, some researchers have investigated the use of hollow fibres and pleated membranes as immobilization surfaces.
• Industrial applications of fixed bed reactors include
waste water treatment
production of enzymes and amino acids
steroid transformations
Fixed bed reactors
• One advantage fixed bed reactors is that non-growing cells can be used.
• In such systems, the cells enzymatically act on substrates in the feed.
• The cells can be either inactivated or not fed nutrients required for growth.
Fluidised bed reactors
• In fluidized-bed fermenters the cells are immobilized on or in small particles.
• The use of small particles increases the surface area for cell immobilization and mass transfer.
• Because the particles are small and light, they can be easily made to flow with the liquid (ie. fluidised).
Small moving particles
Fluidised bed reactors
Fluidized bed reactors
• The fluidisation of the particles in the reactor leads to the surface of the particles being continuously turned over. This also increases the mass transfer rate.
• Fluidised beds are typically categorized as either being a
2 phase system which are not aerated and
3 phase system which is aerated by sparging
• Fluidized bed bioreactors are used widely in wastewater treatment.
Fluidized bed reactors
• Fluidized bed bioreactors are also used for animal cell culture.
• Animal cells are trapped in gels or on the surface of special particles known as "microcarriers".
• Fluidized bed reactors are one example of perfusion culture technology used for animal cell culture.
Comparing fluidised bed and fixed reactors
• Fluidised bed reactors are considerably more efficient than fixed bed reactors for the following reasons:
1) A high concentration of cells can be immobilized in the reactor due to the larger surface area for cell immobilization is available
2) Mass transfer rates are higher due to the larger surface area and the higher levels of mixing in the reactor.
3) Fluidised bed reactors do not clog as easily as fixed bed reactors.
Comparing fluidised bed and fixed reactors
• Fluidised bed reactors are however more difficult to design than fixed bed reactors.
• Design considerations include:
Setting the flow rate to achieve fluidisation
Ensuring that bubble size remains small during the fermentation.
Prevention of the cells from falling or "sloughing" off the particles.
Minimising particle damage.
Flocculated cell reactors
• In flocculated cell reactors, the cells are trapped in the reactor due to an induced or natural flocculation process. In flocculation cells tend to group together causing them to come out of solution and to sink towards the base of the reactor.
• Flocculated cell reactors are used widely in anaerobic waste treatment processes.
• In these reactors, the methanogenic and other bacteria form natural flocs. The flocs move due to the release of methane and carbon dioxide by the cells.
Flocculated cell reactors
• Large scale anaerobic flocculated cell systems, known as Upflow Anaerobic Sludge Blanket processes are widely used in Europe for the anaerobic digestion of high strength industrial wastewaters.
• The reactors are typically egg-shaped.
Flocculated cell reactors
Cells form flocs which gently fall and rise with
gases they produce
Some applications
• ENCAPSEL - retained antibody plus mamalian cells in capsule during growth in bioreactor
• Artificial seeds - polymer coating protects plant embryo
Artifical cells/organs
• Leukocytes & antibodies cannot penetrate into membranes immunological rejection avoided
• Encapsulated hepatocytes placed into rat with defect in bilirubin uridine diphosphate glucuronyltransferase
• Genetically engineered encapsulated E. coli into rats with renal failure (lowered plasma urea)
Biosorbents
Remove heavy metals
• AlgaSORB - immobilised algae cells in silica gel beads
• S. cerevisiae and Zoogleoa ramigera immobilised in calcium alginate capsules used in removal of lead and cadmium
RECOMBINANT DNA TECHNOLOGY and PROCESS
INSTABILITY• Smallest unit of reaction is gene / plasmid
• Specialist cultures have been developed
• Non-robust nature e.g. plasmid instability
• “Generalist cultures” represent the competing “contamination”
BIOLOGICAL PROCESSES AND DYNAMIC ENVIRONMENTS
(changing environmental conditions)
• Waste-treatment, Bioremediation
• Biological control
• Oil-breakdown
• Agricultural e.g. rhizobium, mycorrhiza, silage
• Food e.g. meat fermentation, yogurt
CONVENTIONAL STRATEGY FOR STABILIZATION OF
BIOTECHNOLOGICAL PROCESSES (e.g. STR)
• Eliminate contamination / competition
• Regulate process environment
HOMOGENEITY PARADIGM OFTEN DOMINATES MICROBIOLOGY
STRATEGIES TO OVERCOME PERTURBATIONS
1. Modification of cell physiology And biochemistry to produce a Supercompetitor
= Genetic
2. Create microenvironments to help the inocula
= Microbial ecology
ECOLOGICAL COMPETENCE OF ANY INOCULA is influenced by
• INTRACELLULAR PERTURBATION
Modification of replicon
Modification of extrinsic factors e.g nutrient limitation, selective agents etc.
• EXTRACELLULAR PERTURBATIONS
Modification of process factors
– Growth in bioreactor
– Harvesting, storage and transport conditions
– Delivery to ultimate site of action
COMBINED STRATEGIES TO OVERCOME PERTURBATIONS
• Modification of cell physiology
• Create microenvironments
- to optimize activity of desired culture
= Protect
- to optimize adaptation and release to new environment
= Controlled / sustained delivery
CONSIDER SPATIALLY ORGANIZED MICROBIAL POPULATIONS and STABILITY
(in nature) DIMENSIONS MAY BE;
Vertical– peat, soil, water etc.
Horizontal– colony formation
Radial– activated sludge flocs, yeast flocs
STABILISATION FROM ICT
• Protective effect from encapsulation within a matrix
• Manipulation of diffusion rates
• Co-immobilization of different phases, food sources, selective chemicals and/or protectants
• Cell release in defined / controlled patterns
GEL-IMMOBILIZED CELLS AND ARTIFICIAL MICROCOSMS / MICROENVIRONMENTS
Combine ecological mechanisms based on;• enhanced stress resistance• juxtapositioning of cells• protection afforded within aggregates/flocs
Are based on space and/or time dimensions• targeted delivery• controlled release
PROFILE INFLUENCED BY;
• Removal rate and diffusivity of molecules
• Bead characteristics;
• Matrix properties
• Homogeneity of matrix
• Diameter
• Microbial characteristics
• Morphology
• Biomass density
• Biomass activity
MICRONICHES existing in ALGINATE GELS
CHARACTERISTICS OF GEL
• PROPERTIES OF BOTH LIQUID AND SOLID
Shape retention,
Resistance to mechanical stress.
• PHYSICALLY IMMOBILIZED WATER
Similar to semi-permeable membrane,
Water soluble molecules can diffuse,
Water moves in / out (dry) depending on external environment.
SUSTAINED / CONTROLLED DELIVERY
DEGREE OF PROTECTION• Profiles of substrate, end-products, metabolites• Co-immobilisation of beneficial cultures, complex nutrients,
protectants, selective chemicals and pH or osmotic regulators.
DEGREE OF CELL RELEASE• Rate of outgrowth, polymer characteristics, gelation process,
particle characteristics, biomass activity, macroenvironment.
(McLoughlin, A.J., Adv. Biochem. Eng. / Biotechnol., 1994)
Summary
• Why use immobilisation; advantages over suspension cultures
• Some limitations of ICT
• Types of immobilisation
• Immobilisation matrixes
• Types of immobilised cell reactors
• Applications of immobilised cells
ConclusionsICT ADVANTAGES
1. Increased reaction rates e.g. higher flow rates
2. Higher cell densities
3. Repeated use of biocatalyst
4. Minimal cost for cell separation
