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Sterlization in Bioprocess Engineering

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S t e r i l i s a t i o n • Commercial fermentations typically require thousands of litres of liquid medium and millions of litres of air. • For processes operated with axenic cultures, these raw materials must be provided free from contaminating organisms. • Of all the methods available for sterilisation including chemical treatment, exposure to ultraviolet, gamma and X-ray radiation, sonication, filtration and heating, only the last two are used in large-scale operations.
Batch Heat S t e r i l i s a t i o n o f L i q u i d s • Liquid medium is most commonly sterilised in batch in the vessel where it will be used. • The liquid is heated to sterilisation temperature by introducing steam into the coils or jacket of the vessel; • alternatively, steam is bubbled directly into the medium, or • the vessel is heated electrically. • If direct steam injection is used, allowance must be made for dilution of the medium by condensate which typically adds 10-20% to the liquid volume; • quality of the steam must also be sufficiently high to avoid contamination of the medium by metal ions or organics.
• A typical temperature-time profile for batch sterilisation is shown in Figure 13.35(a). • Depending on the rate of heat transfer from the steam or electrical element, raising the temperature of the medium in large fermenters can take a significant period of time. • Once the holding or sterilisation temperature is reached, the temperature is held constant for a period of time thd. • Cooling water in the coils or jacket of the fermenter is then used to reduce the medium temperature to the required value.
• For operation of batch sterilisation systems, we must be able to estimate the holding time required to achieve the desired level of cell destruction. • As well as destroying contaminant organisms, heat sterilisation also destroys nutrients in the medium. • To minimise this loss, holding times at the highest sterilisation temperature should be kept as short as possible. • Cell death occurs at all times during batch sterilisation, including the heating-up and cooling- down periods. • The holding time thd can be minimised by taking into account cell destruction during these periods.
• Rate of heat sterilisation is governed by the equations for thermal for first-order death kinetics, in a batch vessel. • where cell death is the only process affecting the number of viable cells: • where N is number of viable cells, t is time and – k d is the specific death constant. • Eq. (13.95) applies to each stage of the batch sterilisation cycle: heating, holding and cooling.
• where thd is the holding time, • N 1 is the number of viable cells at the start of holding, and • N 2 is the number of viable cells at the end of holding, • k d is evaluated as a function of temperature using the Arrhenius equation:
• where • A is the Arrhenius constant or frequency factor, • E d is the activation energy for the thermal cell death, • R is the ideal gas constant and • T is absolute temperature. • N1 and N2 are determined by considering the extent of cell death during the heating and cooling periods when the temperature is not constant. Combining Eqs (13.95) and (11.46) gives:
• Integration of Eq. (13.98) gives for the heating period: • where • t 1 is the time at the end of heating, • t 2 is the time at the end of holding and • t f is the time at the end of cooling. • We cannot complete integration of these equations until we know how the temperature varies with time during heating and cooling.
Continuous Heat Sterilisation of Liquids • Continuous sterilisation, particularly a high- temperature, short-exposure-time process, can significantly reduce damage to medium ingredients while achieving high levels of cell destruction. • Other advantages include improved steam economy and more reliable scale-up. • The amount of steam needed for continuous sterilisation is 20-25% that used in batch processes; • the time required is also significantly reduced because heating and cooling are virtually instantaneous.
• Typical equipment configurations for continuous sterilisation are shown in Figure 13.37. • In Figure 13.37(a), raw medium entering the system is first pre-heated by hot, sterile medium in a heat exchanger; • this economises on steam requirements for heating and cools the sterile medium. • Steam is then injected directly into the medium as it flows through a pipe; • The liquid temperature rises almost instantaneously to the desired sterilisation temperature. • The time of exposure to this temperature depends on the length of pipe in the holding section of the steriliser. • After sterilisation, the medium is cooled instantly by passing it through an expansion valve into a vacuum chamber; further cooling takes place in the heat exchanger where residual heat is used to pre-heat incoming medium.
• Figure 13.37(b) shows an alternative sterilisation scheme based on heat exchange between steam and medium. • Raw medium is pre-heated with hot, sterile medium in a heat exchanger then brought to the sterilisation temperature by further heat exchange with steam. • The sterilisation temperature is maintained in the holding section before being reduced to the fermentation temperature by heat exchange with incoming medium. • Heat-exchange systems are more expensive to construct than injection devices; • fouling of the internal surfaces also reduces the efficiency of heat transfer between cleanings. • On the other hand, a disadvantage associated with steam injection is dilution of the medium by condensate; • foaming from direct steam injection can also cause problems with operation of the flash cooler.
• As indicated in Figure 13.38, rates of heating and cooling in continuous sterilisation are much more rapid than in batch; • accordingly, in design of continuous sterilisers, contributions to cell death outside of the holding period are generally ignored. • An important variable affecting performance of continuous sterilisers is the nature of fluid flow in the system. • Ideally, all fluid entering the equipment at a particular instant should spend the same time in the steriliser and exit the system at the same time; • unless this occurs we cannot fully control the time spent in the steriliser by all fluid elements. • No mixing should occur in the tubes; if fluid nearer the entrance of the pipe mixes with fluid ahead of it, there is a risk that contaminants will be transferred to the outlet of the steriliser.
• The type of flow in pipes where there is neither mixing nor variation in fluid velocity is called plug flow • Plug flow is an ideal flow pattern; in reality, fluid elements in pipes have a range of different velocities.
Sterlization in Bioprocess Engineering
Sterlization in Bioprocess Engineering
Sterlization in Bioprocess Engineering
Sterlization in Bioprocess Engineering
Sterlization in Bioprocess Engineering
Sterlization in Bioprocess Engineering
Sterlization in Bioprocess Engineering
Sterlization in Bioprocess Engineering
Sterlization in Bioprocess Engineering
Sterlization in Bioprocess Engineering
Sterlization in Bioprocess Engineering

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Sterlization in Bioprocess Engineering

  • 1. S t e r i l i s a t i o n • Commercial fermentations typically require thousands of litres of liquid medium and millions of litres of air. • For processes operated with axenic cultures, these raw materials must be provided free from contaminating organisms. • Of all the methods available for sterilisation including chemical treatment, exposure to ultraviolet, gamma and X-ray radiation, sonication, filtration and heating, only the last two are used in large-scale operations.
  • 2. Batch Heat S t e r i l i s a t i o n o f L i q u i d s • Liquid medium is most commonly sterilised in batch in the vessel where it will be used. • The liquid is heated to sterilisation temperature by introducing steam into the coils or jacket of the vessel; • alternatively, steam is bubbled directly into the medium, or • the vessel is heated electrically. • If direct steam injection is used, allowance must be made for dilution of the medium by condensate which typically adds 10-20% to the liquid volume; • quality of the steam must also be sufficiently high to avoid contamination of the medium by metal ions or organics.
  • 3. • A typical temperature-time profile for batch sterilisation is shown in Figure 13.35(a). • Depending on the rate of heat transfer from the steam or electrical element, raising the temperature of the medium in large fermenters can take a significant period of time. • Once the holding or sterilisation temperature is reached, the temperature is held constant for a period of time thd. • Cooling water in the coils or jacket of the fermenter is then used to reduce the medium temperature to the required value.
  • 4.
  • 5. • For operation of batch sterilisation systems, we must be able to estimate the holding time required to achieve the desired level of cell destruction. • As well as destroying contaminant organisms, heat sterilisation also destroys nutrients in the medium. • To minimise this loss, holding times at the highest sterilisation temperature should be kept as short as possible. • Cell death occurs at all times during batch sterilisation, including the heating-up and cooling- down periods. • The holding time thd can be minimised by taking into account cell destruction during these periods.
  • 6. • Rate of heat sterilisation is governed by the equations for thermal for first-order death kinetics, in a batch vessel. • where cell death is the only process affecting the number of viable cells: • where N is number of viable cells, t is time and – k d is the specific death constant. • Eq. (13.95) applies to each stage of the batch sterilisation cycle: heating, holding and cooling.
  • 7. • where thd is the holding time, • N 1 is the number of viable cells at the start of holding, and • N 2 is the number of viable cells at the end of holding, • k d is evaluated as a function of temperature using the Arrhenius equation:
  • 8. • where • A is the Arrhenius constant or frequency factor, • E d is the activation energy for the thermal cell death, • R is the ideal gas constant and • T is absolute temperature. • N1 and N2 are determined by considering the extent of cell death during the heating and cooling periods when the temperature is not constant. Combining Eqs (13.95) and (11.46) gives:
  • 9. • Integration of Eq. (13.98) gives for the heating period: • where • t 1 is the time at the end of heating, • t 2 is the time at the end of holding and • t f is the time at the end of cooling. • We cannot complete integration of these equations until we know how the temperature varies with time during heating and cooling.
  • 10.
  • 11. Continuous Heat Sterilisation of Liquids • Continuous sterilisation, particularly a high- temperature, short-exposure-time process, can significantly reduce damage to medium ingredients while achieving high levels of cell destruction. • Other advantages include improved steam economy and more reliable scale-up. • The amount of steam needed for continuous sterilisation is 20-25% that used in batch processes; • the time required is also significantly reduced because heating and cooling are virtually instantaneous.
  • 12.
  • 13. • Typical equipment configurations for continuous sterilisation are shown in Figure 13.37. • In Figure 13.37(a), raw medium entering the system is first pre-heated by hot, sterile medium in a heat exchanger; • this economises on steam requirements for heating and cools the sterile medium. • Steam is then injected directly into the medium as it flows through a pipe; • The liquid temperature rises almost instantaneously to the desired sterilisation temperature. • The time of exposure to this temperature depends on the length of pipe in the holding section of the steriliser. • After sterilisation, the medium is cooled instantly by passing it through an expansion valve into a vacuum chamber; further cooling takes place in the heat exchanger where residual heat is used to pre-heat incoming medium.
  • 14. • Figure 13.37(b) shows an alternative sterilisation scheme based on heat exchange between steam and medium. • Raw medium is pre-heated with hot, sterile medium in a heat exchanger then brought to the sterilisation temperature by further heat exchange with steam. • The sterilisation temperature is maintained in the holding section before being reduced to the fermentation temperature by heat exchange with incoming medium. • Heat-exchange systems are more expensive to construct than injection devices; • fouling of the internal surfaces also reduces the efficiency of heat transfer between cleanings. • On the other hand, a disadvantage associated with steam injection is dilution of the medium by condensate; • foaming from direct steam injection can also cause problems with operation of the flash cooler.
  • 15. • As indicated in Figure 13.38, rates of heating and cooling in continuous sterilisation are much more rapid than in batch; • accordingly, in design of continuous sterilisers, contributions to cell death outside of the holding period are generally ignored. • An important variable affecting performance of continuous sterilisers is the nature of fluid flow in the system. • Ideally, all fluid entering the equipment at a particular instant should spend the same time in the steriliser and exit the system at the same time; • unless this occurs we cannot fully control the time spent in the steriliser by all fluid elements. • No mixing should occur in the tubes; if fluid nearer the entrance of the pipe mixes with fluid ahead of it, there is a risk that contaminants will be transferred to the outlet of the steriliser.
  • 16. • The type of flow in pipes where there is neither mixing nor variation in fluid velocity is called plug flow • Plug flow is an ideal flow pattern; in reality, fluid elements in pipes have a range of different velocities.