Upstream Bioprocessing

Question 1

What are the products of traditional bioprocessing?

Answer 1

• Antibiotics
• Vaccines / viruses
• Antibodies
• Recombinant therapeutic proteins (i.e. MAb) (Global market worth £30 billion/year)

Question 2

What are the applications for (Stem) Cell bioprocessing?

Answer 2

• Cells and Tissues
• Banking/Drug screening programmes
• Larger scale healthcare applications →Stem cell therapies (potential to cure diseases, not just to treat/address symptoms)

Question 3

Describe bioprocessing complexity

Answer 3

Question 4

Draw a diagtam of therapeutic agent production

Answer 4

Question 5

Draw a table of cell requirements

Answer 5

Question 6

Describe the INDUSTRIAL SCALE meaning for biotherapeutics

Answer 6

• >10,000 Litres – Monoclonal antibodies (MAbs) and proteins
• 2,000 Litres – Viral vaccines
• 50 Litres – Human mesenchymal stem cells for therapies

(Lawson et al, 2017)

Question 7

Scaled out production

Answer 7

Question 8

Scaled Up production

Answer 8

Question 9

Advantages of scale-up

Answer 9

• Is the current industrial standard.
• It is well established.
• Cost effective.
• Appropriate for Allogeneic approaches

Question 10

Advantages of scale-out

Answer 10

• Allows for parallel runs.
• In case of contamination or failure, only minimal loss.
• Appropriate for Autologous approaches.

Question 11

Disadvantages of Scale up

Answer 11

• Many engineering challenges (e.g. mixing, gradients, temperature and pH maintenance).
• In case of contamination or failure, maximal loss.
• Equipment scale challenges.

Question 12

Disadvantages of scale-out

Answer 12

• Highly laborious unless automation is used.
• Less cost effective.

Question 13

What are the biological and engeineering considerations for scaling up production?

Answer 13

• Scale-up is usually the final step of any R&D programme
• Biologists usually don’t fully understand the challenges of a scalable process
• Engineers don’t always understand the biology
• Engineers don’t get involved soon enough
• Scaling up a bioprocess requires important engineering aspects that have to be considered early in the process => DETRIMENTAL effect on the overall manufacturing process

Question 14

Inefficient scale up: Lower economic performance

Answer 14

• Lower yield
• Lower capacity
• Lower product quality

Question 15

Inefficient scale up: Operational instability

Answer 15

• Mechanical instabilities
• Genetic instability
• Variability

Question 16

Name some planar culture vessels

Answer 16

• T-flasks
• Multilayer plates
• Cell factoreies
• Roller bottlesCompacT SelectT– automated cell culture platform

Question 17

What are the advantages of planar culture vessels?

Answer 17

• Well accepted and well understood
• Reproducible and standardised
• Option to be completely automated (e.g. TAP CompacT SelecT)

Question 18

What are the disadvantages of planar culture vessels?

Answer 18

• Static systems → heterogeneous culture environment (Note: except roller bottles that provide a slightly more homogeneous environment, but with mass and energy transfer gradients)
• Poor surface area-to-volume ratio
• Surface limitation and labour intensive →Unfeasible for the production of large cell lot sizes (10⁹/10¹² cells)

Question 19

What is a bioreactor?

Answer 19

A vessel in which a bio-based process takes place

Question 20

What is a reactor?

Answer 20

A vessel in which a chemical reaction takes place

Question 21

Which vessels are cells grown (e.g. bacteria, yeast)?

Answer 21

Fermenter

Question 22

Give a brief history of bioreactors

Answer 22

•1918 - Biochemist and former Israeli President Chaim Weizmann developed a bacteria fermenter for the production of acetone.

•1944 - De Beeze and Liebmann used the first large scale (>20 litre capacity) fermenter for yeast production.

•1970s – First commercial fermenters, autoclaves, freeze dryers, colony counters were developed.

• 1980s – First benchtop bioreactor was designed for animal cell culture.
• 1990s – Microprocessor controlled shakers, provide precision control of set-points, alarms, running time, agitation, pCO2 and temperature.

•2001 – Benchtop system can control up to 4 bioreactors.

•2005 – Disposable cell culture flasks.

Question 23

Draw a diagram of bioreactor designs

Answer 23

Question 24

Explain how a Pneumatic bioreactor works: Airlift (bubble column)

Answer 24

• Aeration and mixing is achieved by gas sparging
• Less energy than mechanical stirring
• Satisfactory heat and mass transfer performance
• Low shear→ suitable for plant or animal cell culture
• Absence of any moving parts →reduced contamination and easy maintenance
• DO and pH control achieved by varying the composition and the rate of the gas flow through the column
• Challenge: foaming

Question 25

Explain how a Hydraulic bioreactor works: Packed (fixed) /fluidised bed

Answer 25

• Used for immobilised cells in high density cultures intended for protein production in long term cultures
• Cells grow on macro-porous beads (e.g. glass, ceramic)
• Mass transfer is achieved by recirculating the medium in a loop for oxygen enrichment
• Low shear rates, simple medium exchange and cell /product separation
• As particles are in constant motion, channelling and clogging is avoided (only Fluidised Bed)
• Non-homogeneous cell distribution (only Fixed Bed), difficult cell harvest.

Question 26

Explain how a Hydraulic bioreactor works: Hollowfibre

Answer 26

• Anchorage-dependent / independent cells
• Cartridge of capillary-like tubules with perfusable membrane walls
• Provides a 3D environment for cell growth
• Enhanced mass transfer
• Used with hepatocytes as an artificial liver (Bio-Artificial Liver-BAL)
• Bio-Artificial Kidney – BAK

Question 27

Explain mechanical bioreactor: Stirred Tank (STR)

Answer 27

• Mixing is achieved by mechanical means using an agitator (e.g. impeller)
• Baffles can be used to reduce vortexing
• Relatively high input of energy
• Heating/cooling mantles
• Gasing options: headspace or purging
• Multiple impellers improve mixing within tall bioreactors
• Impellers with different sizes and shapes are used to produce different flow patterns inside the vessel

Question 28

Mixing in STR: flow patterns

Answer 28

Question 29

STR: impellers

Rushton

Answer 29

• Radial flow
• Flat blades
• Suitable for high cell density cultures (e.g. bacteria, yeast, some fungi)

Question 30

STR: impellers

Pitched-blade

Answer 30

• Flat blades, 45°
• Simultaneous axial and radial flow
• Suitable for mammalian cell cultures

Question 31

STR: impellers

Marine

Answer 31

• Axial flow
• Gentle mixing
• Suitable for mammalian cells

Question 32

What are the characteristics of microcarriers?

Answer 32

Small: to maximize cell culture surface area (high area-to-volume ratio)

Light: to allow easy suspension in culture medium

Density: slightly higher than medium to allow for fast settling when required

Transparent: to allow easy observation of cell attachment and growth

Appropriate surface chemistry: to promote cell attachment

Question 33

Scalable culture systems - microcarriers

Answer 33

• 1^st developed microcarrier in 1967 by Van Wezel (dextran-based)
• Micrometer sized particles made typically from polymers such as polystyrene, modified dextran, gellan
• Commercially available from multiple manufacturers
• Different surface chemistries available that determine physico-chemical properties
• Suitable for adherent-dependent cells
• Allow cell attachment and proliferation in suspension cultures
• Increased surface area-to-volume ratio compared to planar systems

Question 34

Name some scalable culture systems - microcarriers

Answer 34

• Plastic (polystyrene)
• Cytodex 1 (dextran)
• Collagen
• Cytopore (gelatin)
• Hillex II (modifies polystyrene)
• NUNC 2D MiroHex (polystyrene)

Question 35

Bioreactor operation modes: Batch

Answer 35

• Reactants (nutrients and cells) are introduced at the start of the culture
• Products are recovered at the end (batch wise)

Question 36

Bioreactor operation modes: FED BATCH / REPEATED

Answer 36

• Reactants are fed semi-regularly (semi-continuously
• Products are recovered at the end (batch wise)

Question 37

Bioreactor operation modes: CONTINUOUS (PERFUSION):

Answer 37

• Reactor contents is mixed and homogeneous
• Reactants are fed in and product is removed constantly
• Volume of the reactor is constant

Question 38

Single use bioreactors

Answer 38

Solid trend: disposable bags for media storage, process development, for inoculation, actual bioreactor vessels

Question 39

What are the advanatges of single use bioreactors?

Answer 39

Advantage: quicker turn-around times, no steam sterilization or cleaning needed, substantially decreases overall timelines and operational complexity.

Question 40

Single use bioreactors: Two types based on medium agitation

Answer 40

1. Stirrers integrated into the plastic bag
2. Agitated by a rocking motion (e.g. WAVE bioreactor)

• Both up to a scale of 1000 Liters volume
• Both pre-sterilized.