Aseptic Upstream Bioprocessing 2022 Presented by Beth Zielinski-Habershaw, PhD
9:00am-9:30am
Introductions
What will this this course provide? Knowledge in methodologies and principles that underlie mammalian cell culture and aseptic upstream processing. Comprehensive education in • • • •
principles of clean room function and ISO standards proper aseptic technique in ISO 5 cell culture hoods inoculation of genetically modified cells in the aseptic suite cell scale up methods for the ultimate transfer of therapeutic material to downstream personnel
Understanding and integration of cell culture methodologies and techniques with performance indicators in order to optimize individual proficiencies.
After this course you will Be knowledgeable in the FDA guidance for clean room aseptic processing Have clear understandings of and technical acumen for aseptic upstream processing and scale up. Be prepared to work effectively in aseptic upstream bioprocessing suites which includes monitoring of clean room environments while culturing mammalian cells.
Table of Contents Cells used for industrial production FDA guidance The clean room environment Biosafety cabinets Monitoring for viable and nonviable particles Cell culture contamination Basic equipment and media Inoculation into spinner flasks Scale up
9:30am-11:00am Cells used for industrial production FDA guidance The clean room environment
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CELLS USED FOR INDUSTRIAL PURPOSES
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The big picture…..
Microbial Biomolecules: Properties, Relevance, and their Translational Applications 2020, Pages 69-89
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Flow of aseptic upstream bioprocessing
Inoculum
Harvest
Spinner Flasks( 100ml-500ml)
Precipitation
Bioreactor (3-20K L)
Centrifugation
Filtration
What are CHO (Chinese Hamster Ovary) cells?
Alcibiades -
Jamiri
Are these both CHO cell lines?
Creation of several CHO cell lines •
Mammalian systems are often preferred over other hosts, such as bacteria, plants, and yeast.
•
Capability for proper protein folding, assembly and posttranslational modification.
•
CHO systems have the added advantages • Can be grown in suspension at scales required to meet market demands • Genetically engineered to express high amounts of recombinant protein Grown in serum-free and chemically defined media • Less risks of propagating human viruses Wurm FM (2013) CHO quasispecies—implications for manufacturing processes. Processes 1:296–311
How are CHO cells genetically manipulated? from nucleofection to clone development Stable cell lines • High expression level of the gene of interest plasmids must integrate into transcriptionally active chromosomal regions. • Vector promoter elements drive the expression of recombinant protein and are derived from viruses, mice, and human
Biopharmaceutical Processing
What are the CHO cells producing? The cells that you are inoculating and maintaining have been genetically modified to produce a therapeutic monoclonal antibody A therapeutic monoclonal antibody is a protein that is capable of binding, in a specific manner, to another protein called a ligand. Once administered to the body, the therapeutic monoclonal antibody binds its complementary ligand and changes cell and gene function in order to combat disease
Monoclonal antibodies High specificity (low occurrence of cross reactivity) Lock and key mechanism Can be easily expressed in cell lines Favorable half life (compared to other molecules) Common production molecules
Ligand
Exquisite specificity with fewer off-target interactions and improved safety profiles! Cancer Research, UK
Are CHO cell lines always stable?
https://www.genscript.com/gsimages/news/why-are-cho-cells-critical-in-bioprocessing-1.jpg?=02
Screening
Please watch at leisure: https://vimeo.com/501897392
FOOD AND DRUG ADMINISTRATION (FDA)
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FDA: Guidance for drug and biopharmaceutical development Formed June 30, 1906 The FDA is a governmental body that provides guidance for bringing a drug, biologic or medical device to market The FDA enforces rules governing the process for bringing a drug, biologic or medical device to market Offices in Maryland and throughout the country
What is FDA 21 CFR - Code of Federal Regulations? “The Code of Federal Regulations (CFR) is a codification of the general and permanent rules published in the Federal Register by the Executive departments and agencies of the Federal Government. Title 21 of the CFR is reserved for rules of the Food and Drug Administration. Each title (or volume) of the CFR is revised once each calendar year. A revised Title 21 is issued on approximately April 1st of each year.” FDA.gov
Food and Drug Administration 21 CFR The regulations enable a common understanding of the regulatory process by describing the requirements to be followed by drug manufacturers, applicants, and FDA. 21 CFR Part 210. Current Good Manufacturing Practice in Manufacturing Processing, packing, or Holding of Drugs. 21 CFR Part 211. Current Good Manufacturing Practice for Finished Pharmaceuticals. 21 CFR Part 212. Current Good Manufacturing Practice for Positron Emission Tomography Drugs. 21 CFR Part 314 For FDA approval to market a new drug. 21 CFR Part 600. Biological Products: General. FDA.gov
What does 21 CFR 211 include?
https://www.plianced.com/compliance-wiki/wp-content/uploads/2019/11/FDA-CFR-1024x576.jpg
GUIDANCE DOCUMENT: Sterile Drug Products Produced by Aseptic Processing — Current Good Manufacturing Practice. Guidance for Industry. OCTOBER 2004. Content current as of 05/04/2020
“This guidance is intended to help manufacturers meet the requirements in the Agency's current good manufacturing practice (CGMP) regulations (2l CFR parts 210 and 211) when manufacturing sterile drug and biological products using aseptic processing. This guidance replaces the 1987 Industry Guideline on Sterile Drug Products Produced by Aseptic Processing (Aseptic Processing Guideline). This revision updates and clarifies the 1987 guidance.” FDA.gov
Litigation: Sanofi, Genzyme 'negligently allowed a virus contamination in the manufacturing facility' By Eric Palmer Mar 12, 2012 06:56pm
“An Idaho widow has sued Genzyme and parent Sanofi ($SNY), saying the viral contamination at a plant led to a shortage of Fabrazyme. The lawsuit, which can be accessed via a link from a Pharmalot story, says that in June 2009, the defendants "negligently allowed a virus contamination in the manufacturing facility where Genzyme makes Fabrazyme [leading] to a shortage of the drug, which resulted in Genzyme not meeting demand of Fabrazyme to Fabry disease patients." The situation was made worse in November 2009 after the FDA found more contamination in Fabrazyme, resulting in a further reduction in the drug's availability. "Due to this shortage, Genyzme began arbitrarily rationing Fabrazyme toward the end of 2009. The problems at the plant led Genzyme to sign a consent decree with the FDA, and it has been working to resolve the issues. ”
Viral contamination in biologic manufacture and implications for emerging therapies Nature. Published: 27 April 2020
Consortium on Adventitious Agent Contamination in Biomanufacturing (CAACB)—a biopharmaceutical industry consortium including more than 20 biotechnology companies housed at the Massachusetts Institute of Technology’s Center for Biomedical Innovation—collected comprehensive data on virus contaminations in cell culture operations from CAACB member companies36.
Viral contamination in biologic manufacture and implications for emerging therapies Nature. Published: 27 April 2020
1.Contaminating virus and host cell line are indicated where known. Note: some contamination events were reported publicly and in more detail to the CAACB. 2.CVV, Cache Valley virus; EHDV, epizootic hemorrhagic disease virus; MVM, minute virus of mice; PCV-1, porcine circovirus type 1; Reo3, reovirus type 3.
Factors influencing microbial contamination of manufacturing environment and therapeutic product Figure 2. Major factors that influence the microbiological contamination risk of biopharmaceuticals. The human factor might influence and dominate the other factors.
THE CLEAN ROOM ENVIRONMENT
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A few facts about aseptic processing standards Food and Drug Administration Title 21 CFR 211: Guidelines for aseptic processing in pharmaceuticals and biopharmaceuticals Specialized HVAC equipment Strictly regulated air pressure and humidity control for appropriate anteroom and clean-room environments that are low in particulate matter Clean-rooms constructed of nonporous materials ISO 7 standard
Aseptic processing is performed in enclosed environments (hoods) that maintain ISO 5 conditions
Aseptic Processing Areas: Big Picture
Easily cleanable floors, wall, and ceilings of smooth, hard surfaces
Temperature and humidity controls
Bioprocessinternational.org
High Efficiency Particulate Air Filters (HEPA)
Aseptic Processing Area: Clean Room An isolated environment, strictly controlled with respect to: Airborne particles of viable and nonviable nature Temperature Humidity Air pressure Air flow Air motion Lighting
ISO classifications
https://www.blue-line.com/cleanroom-fda-and-eu-classifications
ISO classifications The particulate matter in the corridors outside the aseptic processing area must be no greater than ISO Class 8 At the next level of stringency, particulate matter contained in room air within an aseptic processing area should be no more than the ISO Class 7 standard allowance Biosafety cabinets (BSCs) are located in an ISO 7 clean room suite The air within the BSC must be ISO Class 5
https://www.google.com/url?sa=i&url=https%3A%2F%2Fwww.prnewswire.com%2Fnews-releases%2Fsignaturebiologics
Aseptic Processing Areas: Clean Room Airflow Unidirectional or Laminar Airflow (FDA Guidance definition) An airflow moving in a single direction, in a robust and uniform manner, and at sufficient speed to reproducibly sweep particles away from the critical processing or testing area 9/2004 Guidance for Industry-Sterile Drug Products Produced by Aseptic Processing — Current Good Manufacturing Practice
https://lh3.googleusercontent.com/proxy/ zrcilm7Tk7oFDkcBGakBpc9McuNsjHaxKTGR0bDoLlM5JNsSPvkJsw_tplOoJRs5plBTNBUJO9ZIux-IygWmidF2XkzmYrbxgSxB9uKskKbhxZyx6PxWs6Ch0Wq-EBuN2914x1-k6wb_2bVHctVRzeMJg
Turbulent/Nonunidirectional Airflow Airflow which does not meet the definition of unidirectional airflow Edges, solid flat surfaces, person or equipment Moving
Air changes and flow patterns Air flow over critical areas should be uni-directional (laminar flow) at a velocity sufficient to sweep particles away from filling/closing area Non-viable air particles are monitored on a daily basis
ISO Class ISO 5 ISO 6 ISO 7 ISO 8 Conventi onal building
Average number of air changes per hour 240–360 air changes per hour (unidirectional airflow) 90–180 air changes per hour 30–60 air changes per hour 10–25 air changes per hour 2–4 air changes per hour Mecartcleanrooms.com
Aseptic processing areas: pressure differentials = prevent contaminations Positive air pressure used to prevent the ingress of contaminants from less clean areas Cleanroom person and materials enter from adjacent clean corridor or clean area Biopharmaceuticals
Negative air pressure effective in containing or preventing dispersion of sensitive or highly toxic materials Pharmaceuticals
https://www.achrnews.com/NEWS/Home/Images/ Alnor-Airflow%20Testing%20and%20Cert%201.jpg
ASSESSMENT QUESTIONS 37
11:00am-11:10am
Break 38
11:10am-12:10pm Biosafety cabinets Monitoring for viable and nonviable particles Cell culture contamination
39
BIOSAFETY CABINETS
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ISO classifications The particulate matter in the corridors outside the aseptic processing area must be no greater than ISO Class 8 At the next level of stringency, particulate matter contained in room air within an aseptic processing area should be no more than the ISO Class 7 standard allowance BSCs are located in an ISO 7 clean room suite The air within the BSC must be ISO Class 5
https://www.google.com/url?sa=i&url=https%3A%2F%2Fwww.prnewswire.com%2Fnews-releases%2Fsignaturebiologics
Laminar flow hoods
(Image Source: http://edgeqld.org.au/fringes/diy-laminar-flow-hood/) (Image Source: http://edgeqld.org.au/fringes/diy-laminar-flow-hood/)
Biosafety cabinet (BSC) Special hood for preparing hazardous compounds such as antineoplastic drugs and other chemotherapy medications Worker stands or sits behind the shield and places the hands into the cabinet to manipulate the sterile compound https://encrypted-tbn0.gstatic.com/images?q=tbn:ANd9GcRueyjZZ4diX3ftHbdvLJT54-D7rWZhARb46Q&usqp=CAU
BSC Classification Class 1 Cabinets Provides personal and environment protection. Used when working with low to moderate risk biological agents. Biosafety levels: 1, 2 and 3 Class 2 Cabinets Provides personnel, environment and product protection. Used when working with low to moderate risk biological agents. Biosafety Levels: 1, 2 and 3 Class 3 Cabinets A highly specialized laboratory “glovebox”. A Class 3 cabinet provides the same protection as a Class 2 but is designed for working with Biosafety Level 4 highly infectious agents and provides the highest level of protection for the environment, product and user. Used when you are working with very high risk biological agents. Biosafety Level: 4
Labogene.com
Biosafety cabinets Class I
(Image Source:https://www.unr.edu/ehs/policies-manuals/biosafetymanual/chapter-8)
Class II
Class III
(Image source:https://www.unr.edu/ehs/policies-manuals/biosafetymanual/chapter-8)
(Image Source: http://www.antechscientific.com/biosafety-cabinet-class-iii.html)
Starting Up Turn off the ultraviolet sterilizer (if so equipped) as soon as you enter the room. (Turn on all blowers) and cabinet illumination lights. Allow 5 minutes of operation to purge the system; check the flow alarm system and visual alarm function (if so equipped). Decontaminate readily accessible interior surfaces with a disinfectant appropriate for the agents or suspected agents present. (70% IPA) https://www.totalcleanair.com/wp-content/uploads/2020/06/Biological-Safety-Cabinet-5.jpeg
Basic rules for working in BSC Maintain vigilance about sanitizing items handed to you from outside the BSC Do not cross your arms or objects over open containers Minimize touching anything that is handed to you from outside the BSC and be sure to sanitize with 70% isopropyl alcohol (IPA) Work at least 4 inches from the inside edge of the front vent.
Technique
Technique
Thermo Fisher Scientific
Technique
MONITORING VIABLE AND NONVIABLE PARTICLES
51
https://pediaa.com/wp-content/uploads/2018/06/DifferenceBetween-Viable-and-Nonviable-Particles-Comparison52 Summary.jpg
Viable microbes travel on non-viable particulates Monitoring of non-viable particulates and viable microbes is performed daily to ensure aseptic environmental conditions
https://static01.nyt.com/images/2015/08/28/science/01obs-dust/01obs-dust-articleLarge.jpg? quality=75&auto=webp&disable=upscale
Non-viable (Particulate) monitoring In order to monitor air flow efficiency in regards to maintaining aseptic conditions in clean rooms, viable and nonviable particulate samples are taken daily. ISO 14644-1/2:2015; EU GMP, Annex 1; PIC/S, GMP Annex 1 (2017); FDA Aseptic processing cGMP:2004 Active Sampling Active monitoring indicates how many particles are in a m3 of air Measures different sized particles at .1 µm to 5.0 µm Performed in cleanrooms and BSC
Met One (Beckman Coulter) non-viable particle counter
Viable particulates: microbes
Common microbes
Low-temperature electron micrograph of a cluster of E. coli bacteria, magnified 10,000 times. Each individual bacterium is oblong shaped. Photo by Eric Erbe, digital colorization by Christopher Pooley, both of USDA, ARS, EMU.
Scanning Electron Micrograph of Staphylococcus epidermidis Photo Credit: Janice Carr Content Providers(s): CDC/ Segrid McAllister
Endotoxin Gram negative microbes shed endotoxin Endotoxins are large molecules consisting of a lipid and a polysaccharide composed of O-antigen, outer core and inner core found in the outer membrane of Gram negative bacteria. Effects include: Inflammation (TASS) Altered gene transcription Detectable Gel clot method Chromogenic method Turbidimetric method
https://abbkineau.files.wordpress.com/2016/11/image-34316.jpg
Viable particle monitoring Viable particle counting is performed in order to confirm that the microbial load or bioburden is negligible and aseptic conditions are maintained Testing is performed multiple times/day Combination of active air sampling and passive monitoring Active monitoring indicates how many microbes are in a m3 of air SAS microbial air sampling Settling plates indicate how many microbes could settle onto a surface Touch plates indicate how many microbes are in approximately 25cm2 area
2030lab.com
Americanpharmaceuticalreview.org
Touch plates for viable particle counting
SAS microbial air sampler for viable particle counting
Environmental monitoring data Viable EM requires QC personnel to qualify the media Typically challenged with ≤ 100 cfu of various microbes including: Aspergillus brasiliensis ATCC™ 16404 Bacillus subtilis ATCC™ 6633 Candida albicans ATCC™ 10231 Pseudomonas aeruginosa ATCC™ 9027 Staphylococcus aureus subsp. aureus ATCC™ 6538 Growth after 72 hours demonstrates the media can support microbial growth and can be used for EM monitoring activities.
Trending data Sensitivity Sensitivity of a bioburden tests used to detect the presence of microbes decreases with test volume size and decreases in bioburden density
Trends Charting trends overtime allows for visualization of the overall efficiency of the inspected process. Trends should show stability in the system; ie low bioburden levels. Consistency and compliance with cGMP guidelines
CELL CULTURE CONTAMINATION
66
Culture contamination with bacteria
Eppendorf
Culture contamination with bacteria
Eppendorf
Culture contamination with bacteria
Eppendorf
Culture contamination with mycoplasma
David M Phillips/ Science Source/ Getty Images
The presence of mycoplasma must be assayed for.
Detection of mycoplasma
Direct agar culture Indirect Hoechst DNA staining PCR-based methods
Over 190 mycoplasma species are known, but only eight are responsible for ~95% of cell culture contamination events. • Mycoplasma arginini • Mycoplasma fermentans • Mycoplasma hominis • Mycoplasma hyorhinis • Mycoplasma orale • Mycoplasma pirum • Mycoplasma salivarium • Acholeplasma laidlawii ATCC.ORG
Culture contamination with fungus
Eppendorf
Culture contamination with yeast
Eppendorf
ASSESSMENT QUESTIONS 74
12:10pm-1:10pm
LUNCH 75
1:10pm-2:10pm
Basic equipment and media Inoculation into spinner flasks
76
BASIC EQUIPMENT AND MEDIA
BASIC EQUIPMENT
Equipment for Large-Scale Mammalian Cell Culture (MassBiologics of the University of Massachussets Medical SchoolMattapanUSA)
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Equipment for Large-Scale Mammalian Cell Culture (MassBiologics of the University of Massachussets Medical SchoolMattapanUSA)
Early-stage cell culture
Fig. 2 Equipment used for seed train expansion: a T-flasks, b shaker flask, c roller bottles, d spinner flask, and e WAVE bioreactor on a rocking platform
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Equipment for Large-Scale Mammalian Cell Culture (MassBiologics of the University of Massachussets Medical SchoolMattapanUSA)
Late-stage cell culture Bioreactors Fig. 7 A stainless-steel bioreactor with instrumentation and piping for sterilization, gas flow, and fluid transfer
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Equipment for Large-Scale Mammalian Cell Culture (MassBiologics of the University of Massachussets Medical SchoolMattapanUSA)
Bioreactors Fig. 8 Disposable bioreactors from different vendors. The bag used in the stirred-tank disposable bioreactors contains an impeller and a sparger. The probes are either integrated as part of the bag or they are inserted using an aseptic method after the bag is in place
Equipment for Large-Scale Mammalian Cell Culture (MassBiologics of the University of Massachussets Medical SchoolMattapanUSA)
Bioreactor gassing Table 5 Mixing and aeration systems used in homogeneous bioreactors
Bubble-column and airlift bioreactors do not use an impeller, but rely on moving bubbles for mixing
Reactor type
Mixing mechanism
Aeration mechanism
Stirred tank
Impeller
Direct or indirect sparging
Bubble column
Bubbles
Sparging
Airlift
Bubbles, draft tube
Sparging
WAVE, rocking platform
Rocking
Surface aeration 83
Equipment for Large-Scale Mammalian Cell Culture (MassBiologics of the University of Massachussets Medical SchoolMattapanUSA)
Bioreactor spargers
Fig. 5 Types of spargers used in cell culture bioreactors: a macrosparger (arranged as a ring sparger), and b microspargers
A little more on sparging and gasses
Equipment for Large-Scale Mammalian Cell Culture (MassBiologics of the University of Massachussets Medical SchoolMattapanUSA)
Bioreactor connectors
Fig. 10 a Pall KleenPak connector and b its use to insert conventional probes to a disposable bioreactor [25]
MEDIA
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Cell media prep: Manufacture media for cell growth (inoculum through final bioreactor) A water-based nutrient solution that contains defined amounts of salts, buffers, sugars and proteins in which the cells live. Nutrient media is added to all single use systems and stainless-steel bioreactors
Thermo Fisher Scientific
Media • Types of Media: • MEM • MEM is a modification of Basal Medium Eagle (BME) which contains a higher concentration of amino acids and vitamins, as well as additional supplementary components • DMEM–Dulbecco's Modified Eagle Medium • Ham's F12 • Supplements: • Glutamax in place of glutamine • Protein source (plant Vs animal) • Cell and Gene Therapy vs. Large scale: • Bottles vs. prepared on site from powders • Both scenarios involve a hold period • For large volumes, media trains utilize filtrations as a means to sterilize the media (housings constructed of 316Lss)
This production suite relies on stainless steel bioreactors but integrates single-use technology for cell culture media storage and key transfer lines.
Genetic Engineering and Biotechnology News
Does the type of media make a difference?
Biotechnological products and process engineering Open Access Published: 07 April 2015
a Cell and b antibody concentrations as well as c lactate and d ammonium levels obtained with commercial CHO cell culture media in batch mode
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Amgen thaw and scale up media
Amgen thaw and scale up media process parameters
Amgen thaw and scale up media performance indicators
osmolarity is a measure considering the volume of a solution whereas osmolality is measured considering the mass of a solution
Osmolarity versus Osmolality
The concentration of a solution that shows osmotic activity. (measure in volume)
The unit for osmolality is osmol/kg. Osmolality gives the concentration of a solute in a solution in terms of the mass of the solution. (measure in mass)
https://pediaa.com/wp-content/uploads/2017/08/Difference-Between-Osmolarity-and-Osmolality-2.png
Amgen expansion bioreactor media
Amgen expansion media process parameters
Amgen expansion media performance indicators
Amgen N-1 feed media
Amgen N-1 media process parameters
Amgen N-1 media performance indicators
Amgen production bioreactor media
Amgen production bioreactor media process parameters
Amgen production bioreactor media performance indicators
Amgen production feed media
Amgen production feed media process parameters
Amgen production feed media performance indicators
INOCULATION AND EARLY SCALE UP
Cells Used for Industrial Purposes
Courtesy of Amgen
Inoculation
111
Inoculum Successfully initiate a culture- this is likely an “open system” and requires training.
Process parameters: Stage 1 (vial thaw into 250ml shake flask)
Courtesy of Amgen
Cell Thaw: Inoculum Open system (risk) Work is done in a Biological Safety Cabinet (ISO 5) or isolator
The BSC protects the user and the product in the cabinet from bacterial contamination. Note direction of airflow
High air changes/hour HEPA filtered air
Adherent
Protects operator and the product Use of flasks or other culture vessel (i.e. bottle, spinner) Suspension
Cell Thaw: Inoculum Thaw 1 ml microtube quickly in sterile water Freezing media contains a specialized antifreeze that prevents ice crystals from forming in the cell membranes during the freezing process. The freezing media must be diluted quickly in order to maintain optimal cell viability Immediately upon thawing the 1 ml of cells are transferred to a flask containing cell culture media.
Incubator
https://www.pipette.com/ GetContent.ashx? ctn=BrandImages/H3551-45POpen-WeRes.jpg
Cell count and viability Once cells have been transferred to sterile culture media, a sample is removed, and cell number is counted
Automated Cell Counter
Cell viability is then determined using an automated cell counter Cells are placed in an incubator that has gas, temperature and humidity levels set according to your company’s SOPs
Arrow points to dead cell stained with trypan blue stain. Living cells are clear
https://bitesizebio.s3.amazonaws.com /cellculture/files/2013/03/Figure-4.jpg
ASSESSMENT QUESTIONS 118
2:10pm-2:40pm
Lab 1: Thawing and inoculation
119
Inoculation: Lab video
2:40pm-2:50pm
Break 121
2:50pm-3:50pm
Scale up
122
Phases of normal cell growth
A: Lag Adaptation B: Log Exponential growth C: Plateau Rate of proliferation slows D: Death Rate of death exceeds proliferation rate
High yields obtained today result from the combination of improved host cells, expression vectors, screening methods, media optimization, and process development innovations
Modes of bioreactor operation: batch, fed batch and perfusion Systems Batch Add materials at the start, production is lower (1X) Dominated the industry Originally used for smaller quantities Fed Batch Media addition to culture increasing yield up to 2X-3X Increase production with modest increases in COGs Perfusion Perfusion cell culture to increase production up to 10X Cost effective
Source: https://www.semanticscholar.org
Critical factors for scale up “Change for the sensitive mammalian cells leads to shear stress and foaming issues, but nowadays these are quite well controlled due to the addition of antifoam and cell surfactants (Xing, Kenty, Li, & Lee, 2009).” Slow and gentle mixing Gassing system Foam prevention Accurate feeding Sterile sampling
https://www.researchgate.net/profile/ShuichiTakayama/publication/51046304/figure/fig6/ AS:277549058936843@1443184260593/Schematics-ofan-undisturbed-cell-cells-under-shear-stress-pressureand-their-gradients.png
Mixing
Minimum lateral shear
Typically, stirrer speeds for cell cultures are much slower than for microbial cultures. Most cell lines are stirred at around 100 rpm. Some robust cell lines can survive higher speeds, but yield of biomass suffers Xing, Kenty, Li, & Lee, 2009
Impact of mixing
Gassing in the bioreactor headspace Gas transfer occurs at gas/liquid interface No bubbles to cause foam Accumulation of CO2 in the headspace caused by the metabolism of the cells is prevented
Headspace
Dissolved oxygen and dissolved Dissolved oxygen and dissolved carbon dioxide carbon dioxide
Impact of pH on cell culture t of pH on cell culture
Gassing via the sparger This produces a steady stream of bubbles which can rise through the medium and exchange gas for as long as possible. Gassing via the sparger is more efficient but could cause foaming in cultures that have high levels of protein in the medium. (Add antifoam) Sparger
Foam formation in the 2L bioreactor Dense foam can entrap cells and pull them apart. Foam is due to proteins in the liquid medium and these can come from either protein rich media or protein secretion by cultured cells
Peter Czermak
2
Antifoaming agents Antifoaming agents have high surface activity that can lower the surface tension of local film when its micro droplet contacts liquid film. This local area of low surface tension will extend all around, losing elasticity and self-restoring ability, thus causing the rupture of liquid film.
Figure 7.15.. Oil drops in antifoaming/defoaming agents and their interaction with an air bubble. A is air, W is aqueous phase, O is oil. (a) Plain oil drop; difficult to achieve wetting of the drop by air. (b) Drop contains solid particles that are oriented in the O-W interface; a protruding particle can pierce the film between O and A. (c) The drop contains crystals that form a solid network; a protruding crystal can pierce the film. Vance Bergeron, Pieter Walstra, in Fundamentals of Interface and Colloid Science, 2005
133
Sampling
INFORS HT Super Safe Sampler
134
ASSESSMENT QUESTIONS 135
Introduction to scale up equipment
3:50pm-4:20pm
Lab: Scale up
136
BREAK 137
Cells Used for Industrial Purposes
Courtesy of Amgen
Flasks to flask transfer
How are cells transferred between flasks? Tubing can be cut and soft welded in an aseptic fashion Tubing can also be cut and clamped in an aseptic fashion
Mycap® CCX Cell Culture Shake Flask | Sartorius
Process parameters
Courtesy of Amgen
Process parameters
Courtesy of Amgen
Performance indicators
Courtesy of Amgen
Vial thaw and shake flask expansion calculations
Courtesy of Amgen
Cells Used for Industrial Purposes
Courtesy of Amgen
Flasks to expansion bags
Culture bag process parameters
Culture bag process parameters
Culture bag performance indicators
Expansion bag calculations
Courtesy of Amgen
Cells Used for Industrial Purposes
Courtesy of Amgen
Expansion bags to bioreactor
Courtesy of Amgen 153
154
Bioreactor to bioreactor
Courtesy of Amgen
Single Use Systems (SUS) Pros: Smaller carbon footprint Less water and energy use Higher cell densities possible per volume/size of culture Recyclable plastic???
Cons: Particulates (BioProcess International, April, 2019) Leachable (compromise cell viability and growth) “Close it up”….impact on COGs Leaks (manual connections)
Single Use Systems (SUS)
https://bioprocessintl.com/wp-content/uploads/2015/04/Rentschler_13468_600x400.jpg
https://www.pall.com/content/dam/pall/biopharm/segments/segment-singleuse2.jpg
Regardless of 316Lss or SUS….. Process parameters: Temperature (maintain 36°C) pH (maintain around pH 7.0) Nutrients (maintain [glucose], [protein], etc.) Dissolved oxygen Antifoam Target seed density Culture duration
Source: https://pediaa.com/difference-between-bioreactor-and-fermentor
Regardless of 316Lss or SUS….. Performance indicators: Final viable cell density Final viability
Source: https://pediaa.com/difference-between-bioreactor-and-fermentor
3:50pm-4:20pm
Lab 3: Transfer and scale up
4:20pm-4:40pm
Evaluations and Wrap up
QUESTIONS? THANK YOU THANK YOU