1. BIOMAN 2011 CHO-tPA Production System Downstream Processing
Mike Fino
MiraCosta College

2. Unit Operations
Many decisions to be made at each step in the process

3. Downstream Example

4. Harvest Separation (Clarification)
There are two technologies for removing the cell mass from the solution containing the target protein prior to loading onto columns:
Centrifugation (e.g. disk stack)
Filtration
Dead-ended filtration (aka normal flow: membrane + depth)
Crossflow membrane filtration (aka tangential flow)
Crossflow membranes are preferred for large scale operations and have many advantages

5. Media and Cells In, Clarified Media Out
CLARIFIED BROTH
SLUDGE
Continuous multichamber disc-stack centrifuge. The bowl contains a
number of parallel discs providing a large clarifying surface with a small sedimentation distance. The sludge (cells) is removed through a valve.

6. NORMAL FLOW FILTRATION (NFF):
Traps contaminants larger than the pore size on the top surface of the membrane. Contaminants smaller than the specified pore size pass through the membrane.
Used for critical applications such as sterilizing and final filtration.  
MEMBRANE
DEPTH

7. Sterilizing Filters: Industry/Regulatory standard
Capable of achieving an LRV >7 for a B. diminuta challenge using ASTM methodology (per FDA Guidelines)
> 7 LRV means <1 microbe / 107 microbe challenge
Doesn’t specify pore size or filter type
B. diminuta model organism
Sterilizing filters must be able to retain all challenge microorganisms at a maximum bioburden

9. Tangential Flow Filtration
Clarification/Purification
Concentration
Buffer Exchange
Uses Crossflow to reduce build up of retained components on the membrane surface
Allows filtration of high fouling streams or high resolution
TFF systems often use the same types of filter materials as NFF, but they are operated in at different manner. The feed stream is not pumped directly through the filter, but across the filter, or at a tangent to the filter surface, in order to provide a sweeping action or turbulent flow at the filter surface. Because the feedstream is under pressure, some fluid will still pass through the filter. The goal of TFF is to keep the retained material in the fluid stream and off the filter, to prevent filter plugging.
The advantage of TFF is the ability to control fouling allowing the processing of very dirty feedstreams, or the use of membranes with very small pore sizes.
The disadvantage of TFF is the requirement for additional process controls and the need to control to fine tolerance.

11. Different Size Pores in TFF

12. What is Membrane Integrity?
Integral Membrane
Non-Integral Membrane
Contaminants
larger than
pores upstream
Contaminants
larger than expected
pores upstream
Idealized look at bubble point. On the left the integral membrane pores a filled with liquid which is held there by capillary forces. This liquid and these forces present a barrier to air flow. On the right, the air pressure has exceeded the capillary forces of the largest pore, air flows freely through the pore, and can be seen downstream. Remember that this is an "idealized" model.
No downstream
contamination
Downstream
contamination

13. Principles of Integrity Testing
A benefit of membrane filters is the ability to perform a non-destructive integrity test.
Testing ensures filtration SYSTEM integrity before, during, or after filtration.
Membrane prefilters and depth filters cannot be integrity tested with precision or accuracy because of wide pore distribution.

14. Reasons to Integrity Test
Confirms manufacturers specifications
Assures integrity after steaming or autoclaving
Assures integrity before sterilization
Detects system leaks due to o-rings, gaskets, faulty seals
Assures the correct pore size filter
Part of corporate standard operating procedure
GMP requirement
Audit requirement

15. Two Basic Types of Integrity Test
Destructive
Provided as a manufacturers assurance of microbial retention.
Bacterial Challenge
Non-Destructive
Provided to allow in-situ testing
Pressure hold
Bubble Point
Diffusion

16. Basic Elements of a Bacterial Retention Test
Saline lactose media w/
B. Diminuta
Test Filter
0.22 or 0.1 m disc or filter cartridge
Assay Filter
(47mm MEC
disc)
47mm disc
on TSA
MEC = mixed esters of cellulose
TSA = tryptic soy agar

17. Non-Destructive Integrity Test
Bubble Point
Fully wetted membrane filters hold liquid in their pores by surface tension and capillary forces.
Bubble point pressure is inversely related to largest pore diameter
Open pore space
Water held with surface tension
View of the membrane cross-section

18. What is Pressure Hold/Bubble Point?
Water Wet
Integral Membrane
Non-Integral Membrane
Air pressure
upstream
greater than specification
Gas will flow through
large opening and is
easily observed downstream
Water in pores is a
barrier to gas flow:
No gas flow observed
downstream until upstream pressure exceeds critical value
less than specification
psi
Idealized look at bubble point. On the left the integral membrane pores a filled with liquid which is held there by capillary forces. This liquid and these forces present a barrier to air flow. On the right, the air pressure has exceeded the capillary forces of the largest pore, air flows freely through the pore, and can be seen downstream. Remember that this is an "idealized" model.

19. Inverse Relationship: Pore size v. Bubble Point
A sterilizing filter has a log reduction value of greater than 7
Decreasing pore size

20. TFF System

21. Retentate Flow Permeate Flow Feed Flow Outlet Pressure Hollow Fiber
Inlet Pressure

23. PERISTALTIC PUMP: Creates a gentle squeezing
In this example three rollers on rotating arms pinch the tube against an arc and move the fluid along. There are usually three or four sets of rollers
PERISTALTIC PUMP:
Creates a gentle squeezing
action to move fluid through
flexible tubing.

24. Introduction: TFF Layout & Operation
Operating Steps:
Flush
Clean Water Flux
Pump curve
Integrity Test
Buffer Flush
Microfilter
Or Concentrate
Or Diafilter
feed
pump
filter
retentate
diafiltrate
product
recovery
initial feed
reservoir
permeate

25. Key Parameters Feed Flow rate Transmembrane pressure (TMP)
Flow rate leaving the pump
Set by pump speed
Transmembrane pressure (TMP)
Average of inlet/outlet pressures
Set by backpressure (retentate)
Permeate control
Flow rate through the fibers
Set by backpressure (permeate)
We don’t use this control in this cllass
Membrane area
Scales linearly

26. Transmembrane Pressure (TMP)
Inlet Feed Pressure
Retentate Pressure
TMP = (Pin + Pout)/2 - Pperm
Pin = 30psi
Pout = 20psi
Permeate
Pressure
We leave this line unrestricted
Filter membrane
Pperm = 0psi
TMP = ( )/2 - 0 = 25 PSI

27. System Operation Steps Clean water flux Pump Curve Integrity Test
Initial Feed
Diafiltration Buffer
Steps
Clean water flux
Pump Curve
Integrity Test
Filtration
Flush
Retentate
Tank
Pump
Membrane
Feed
Permeate

28. Operation: Microfiltration
Trash
Collect and Keep

29. Operation: Microfiltration
Trash
Collect and Keep

30. Operation: Microfiltration
Trash
Collect and Keep

31. Operation: Microfiltration
Trash
Collect and Keep

32. Operation: Microfiltration
Trash
Collect and Keep

33. Operation: Microfiltration
Trash
Collect and Keep

34. Operation: Concentration
Diafiltration Buffer
Initial Feed
Retentate
Permeate
Feed
Tank
Pump
Membrane
Flush
Dewater the retained solutes
Procedures
Fill tank with process fluid
Start pump and adjust system to recommended flows/pressures
Remove permeate

35. Operation: Concentration

36. Operation: Concentration

37. Operation: Concentration

38. Operation: Concentration

39. Operation: Concentration

40. Operation: Concentration

41. Operation: Concentration

42. Operation: Concentration

43. Operation: Diafiltration
“Wash out” permeable solutes- product or contaminants
Procedure:
Add diafiltration buffer to the feed tank at the same rate that permeate is being removed from the system
Diafiltration Buffer
Initial Feed
Retentate
Permeate
Feed
Tank
Pump
Membrane
Flush

44. Operation: Diafiltration

45. Operation: Diafiltration

46. Operation: Diafiltration

47. Operation: Diafiltration

48. Operation: Diafiltration

49. Operation: Diafiltration

50. Operation: Diafiltration

51. Operation: Diafiltration

52. Background: Virus Safety Effective Clearance Steps
Virus Filtration
Large (enveloped) & small (non-enveloped) viruses
Smallest parvovirus is about 50% bigger than an antibody
Inactivation
Low pH or Solvent detergent (enveloped)
Chromatography
Protein A Affinity for MAbs (enveloped & non-enveloped)
Anion Exchange Flow through for MAbs (enveloped & non-enveloped)

53. Types of Chromatography

55. Column Chromatography

56. Commonly employed downstream processing methods
Attributes
Benefits
Limitations
Clarification:
Sedimentation based clarification
Continuous centrifugation
Capable of handling very large harvest volumes
Open process- contamination and safety issues
Normal flow Filtration
Microporous
Volume and throughput limited
Charged filter media
Cellulose pads
Tangential flow filtration
Contained systems
Capable of handling large harvest volumes
Capture:
Chromatography
Protein A Affinity
High throughput, high purity
High initial cost
Other affinity ligands
High throughput
Purity, regulatory acceptance
Cation exchange
Low cost media
Low throughput, feedstock preconditioning
Purification:
Ion exchange, HIC, IMAC,
hydroxyapatite
Variety of selectivities, high capacity, robust
Often flow rate limited
Adsorptive membrane
Charged membranes
High throughput, contained, suited to trace contaminant removal
Low capacities

57. Typical contaminant clearance values from each chromatography stage
Affinity load
Intermediate purification load
Polishing load
Host cell protein (ng/ml)
105
103 10
Endotoxin (EU/ml)
106
<1
DNA (pg/ml)
102

58. Common process constituents and methods of removal or purification
Component
Culture harvest level
Final product level
Conventional method
Therapeutic Antibody
g/l
1-10 g/l
UF/Cromatography
Isoforms
Various
Monomer
Chromatography
Serum and host proteins
g/l
< mg/l
Cell debris and colloids
106/ml
None MF
Bacterial pathogens
<10-6/dose
Virus pathogens
<10-6/dose (12 LRV)
virus filtration
DNA
1 mg/l
10 ng/dose
Endotoxins
<0.25 EU/ml
Lipids, surfactants
0-1 g/l
< mg/l
Buffer
Growth media
Stability media UF
Extractables/leachables
UF/ Chromatography
Purification reagents
<0.1-10mg/l

59. Downstream Design
95% yield/step
90% yield/step
85% yield/step

60. Ion Exchange Chromatography
If the charge on the bead is positive, it will bind negatively charged molecules.
This technique is called anion exchange.
If the beads are negatively charged, they bind positively charged molecules
This technique is called cation exchange.

61. IEC (cont’d)
Thus, a scientist picks the resin to used based on the properties of the protein of interest.
During the chromatography, the protein binds to the oppositely charged beads.
Once the contaminant protein is separated from the protein of interest, a high salt buffer is used to get the desired protein to elute from the column.

62. Ion Exchangers
Ion exchange chromatography is based on adsorption and reversible binding of charged sample molecules to oppositely charged groups attached to an insoluble resin
The pH value at which a biomolecule carries no net charge is called the isoelectric point (pI)

63. IEX (cont’d)
When exposed to a pH below its pI, the biomolecule will carry a positive charge and will bind to a cation exchanger.
At a pH above its pI, the protein will carry a negative charge and will to bind to an anion exchanger
Depending on what pH the biomolecule is more stable at will decide whether an anion or cation exchanger is used

64. Background for IEC of tPA
SP Sepharose is a cation resin, which means that positively charged molecules will bind to the negatively charged resin.
The extent of binding is dependent on the cationic strength of the protein of interest and can be manipulated by changing the pH and/or conductivity of the buffers used in the chromatography process.

65. The main proteins in the media used to grow tPA are tPA, Bovine serum albumin (BSA), insulin, and transferrin. Each protein has a specific isoelectric point called the pI.
BSA has a pI of 4.9
tPA is
transferrin is 5.9
insulin is 5.3

66. We are able to selectively bind the tPA to the resin by controlling the pH and ionic strength of the equilibration buffer (aka Buffer A).
At a pH of 6.0, tPA is more cationic (positively charged) than either BSA or Transferrin.
Therefore, the more positive charged tPA will bind to the resin and the others will flow through the column and out to waste.
tPA is then removed from the column using a high concentration of salt, which competitively "bumps" the protein off the resin as the sodium ions bind.

67. Steps in Chromatography
Prime and de-bubble the system
Condition the column resin with a solution that promotes the binding of your protein
Called Equilibration
Pump your sample solution over the column resin, which should bind as much of your protein as possible
Called Applying Sample
Everything that doesn’t bind goes to the drain.
At this point, your protein will stay bound to the resin indefinitely.
Now pump a solution over the resin that competes for binding on the resin with the proteins from your solution.
Called Elution
At some point, the competing solution will beat out the various proteins for position on the resin and they will let go of the resin.
You will collect fractions along the way that can be frozen and analyzed later.

70. ÄktaPrime Liquid Chromotography System

71. ÄktaPrime Flow Path