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Overview | Short
Courses | Day 1 |
Day 2 | Day 3 (Joint
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Joint Session
Protein Purification & Recovery and Protein Production
7:00am – 5:30pm Registration
7:30 Breakfast Workshop (Sponsorship Available)
OPTIMIZING PROCESSES
8:15 Chairperson’s Remarks
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Keynote Presentation
8:20 Fluorescent Protein G Methylcellulose Screening -- A More Predictive Approach to Isolate High-Producing Candidate Manufacturing Cell Lines?
 Dennis
Kraichely, Ph.D., Principal Research Scientist and Group Leader, Pharmaceutical Development & Marketed Product Support, Centocor Research and Development, Inc. (Johnson & Johnson)
This presentation will introduce many of the fundamental decisions that are encountered when developing high-producing cell lines using mammalian cell culture; including host cell type, expression system/selectable marker, and clone selection/screening approaches. The generation of candidate manufacturing cell lines for the production of therapeutic monoclonal antibodies entails the isolation of clones that express high levels of the recombinant protein. Use of an assay that can screen large numbers of transfectants and rank order for relative protein production greatly enables the identification of high-expressing clones. We have been working to develop a novel fluorescent Protein G screening assay to selectively identify and isolate clones that produce high levels of recombinant monoclonal antibodies. Data from a number of recent studies, using an automated ClonePix FL instrument, show a strong correlation between mean interior fluorescence intensity and protein production levels. In summary, this proprietary fluorescent Protein G assay provides increased predictability for the identification of high producing cell lines (vs. standard protocols), reduces the overall screening effort, and may shorten overall cell line development timelines. |
8:50 Cell Culture Process Development: From
Clone Selection to Large-Scale Production
Feng Li, Ph.D., Senior Engineer, Process Development, Genentech
9:20 Technologies to Improve Cell Line Development and Engineering
Susan Dana Jones, Ph.D., Vice President and Senior Consultant, BioProcess Technology Consultants, Inc.
One of the critical activities for decreasing the time for moving a biologic product from candidate selection to first in human clinical trials is the rapid generation of a stable high expressing production cell line. Technologies that can enable this rapid development include expression vectors with elements that increase transcription or translation of the linked recombinant gene, pre-adapted host cell lines, and high throughput screening methods for optimizing media composition to improve bioreactor performance and increase volumetric productivity. Strategies for achieving rapid cell line development and reducing overall development costs will be addressed along with an assessment of the risks and strategic impact of short cuts taken early in development on later stage production, partnering opportunities, product valuation, and regulatory acceptance.
9:50 Coffee Break in the Exhibit Hall
ANALYTICAL
APPROACHES
10:45 Global Biochemical Analysis for Cell Line Selection and Media Development
Michael Milburn, Ph.D., Chief Scientific Officer, Metabolon, Inc.
Maximizing production of biologicals from cultures is a stepped process often requiring multiple rounds of cause and effect experiments with analysis of production and quality as the end point drivers. From selection of clonal isolates to initial media formulations to scale up conditions there are many areas of experimentation which can be utilized for optimization of production. There has been a striking uptake in the use of metabolomics technology in cell line development and
bioprocessing. This technology has been shown to have the potential to truly impact the market and drive greater efficiencies.
11:15 Characterization of LucraTone Animal-Free Hydrolysates and the Impact of Ultra filtration on Mammalian Cell Culture Performance
Michael Cunningham, Ph.D., Senior Scientist, Bioprocess Division,
Millipore Corporation
Hydrolysates are used extensively in biopharmaceutical manufacturing to enhance efficient mammalian cell growth and protein production. Ultrafiltration is an effective method for removing large molecular weight entities, including
endotoxin, from hydrolysates. While the necessity of hydrolysate ultrafiltration prior to use in cell culture media has not been adequately established, some data suggest that ultrafiltration negatively impacts hydrolysate performance of cell growth and protein production in cell culture media. In this case study, multiple lots of ultrafiltered and
non-ultrafiltered LucraTone Soy P hydrolysates were evaluated to determine their impact on cell culture performance (mammalian and microbial cultures). Ultrafiltration of hydrolysate stock solutions by normal flow and tangential flow techniques were also analyzed.
11:45 Optimization of Cell Culture Conditions for Protein Production using Quantitative Targeted Metabolite Analysis
Denise Sonntag, Ph.D., Senior Scientist Biochemistry, Contract Research, BIOCRATES Life Sciences AG
Cell-based protein production requires optimal culture conditions to obtain a high yield of quality products. As the composition of the cell culture medium is a critical parameter in the fermentation process, efficient analysis methods that allow media control during fermentation are highly beneficial for culture optimization. Quantitative targeted metabolomic analysis of cell culture supernatants constitutes a rapid and comprehensive method to monitor changes in media composition that are relevant for cell growth and vitality. Consumption of supplied nutrients or accumulation of defined growth-inhibitory metabolites can be quantitatively recorded using sensitive and specific mass spectrometry methods (API-MS/MS). The enormous potential of a mass spectrometry-based approach to cell culture optimization, which covers several hundred metabolites of different classes, e.g. amino acids,
acylcarnitines, glycerophospholipids, sphingomyelins, total fatty acids, mono- and oligosaccharides and biogenic amines, will be highlighted. As an example of application, we will present data from mammalian cell fermentation to point out the feasibility and significance of metabolomics for the optimization of cell-based protein production.
12:15 Close of Morning Session
12:30 Luncheon Workshop (Sponsorship Available) or
Lunch on your Own
HIGHER
YEILDS
1:45 Chairperson’s Remarks
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Featured Presentation
1:50 Quantifying and Modulating Cell Growth, Death, Metabolism and Product Formation
 William M. Miller, Ph.D., Professor, Chemical & Biological Engineering, Northwestern University
Cell responses often vary greatly with changes in the culture environment including nutrient and byproduct concentrations, cell density and physicochemical parameters. The specific growth rate, cell-specific metabolic parameters, yield ratios, and population frequencies provide intensive measures of cellular activity that are useful for comparing different culture systems. This lecture will present several approaches for quantifying cell growth, death, metabolism and product formation. The effects of key environmental parameters on cell growth, metabolism, and product formation and glycosylation will also be discussed. Finally, several approaches will be presented to modulate cell metabolism and productivity.
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2:20 Intensifying CHO Cell Based Fed-Batch
Culture for High Yield Antibody Production
Thomas Ryll, Ph.D., Director, Cell Culture Development, Cell Culture Development, Biogen Idec Inc.
2:50 Embryonic Stem Cells for the Manufacturing of Biologics
Majid Mehtali, Ph.D., Chief Scientific Officer, Vice President, Research and Development, Vivalis SA
Primary cells and established continuous cell lines have been used since decades for the industrial production of vaccines and therapeutic proteins. However, such manufacturing systems are often limited by various drawbacks. Embryonic stem cells hold exceptional biological properties that could theoretically be exploited for the derivation of new generations of cell substrates that fulfil modern industrial and regulatory requirements. EBx® cell lines have been derived from avian embryonic stem cells using proprietary procedures. Such cells maintain most of the desirable features of ES cells
(ie. long-term genetic stability, indefinite cell proliferation…) but display new industrial- and regulatory-friendly characteristics
(ie. proliferation in stirred-tank bioreactors at high cell densities as suspension cells, growth in serum-free media, high susceptibility to various human and animal viruses, efficient genetic engineering and heterologous protein production…). EBx® cells constitute a unique alternative for the manufacturing of vaccines and therapeutic proteins, in particular monoclonal antibodies with enhanced ADCC (antibody-directed cell
cytotoxicity) activity. Fully controlled master and working cell banks (MCB &
WCB) are available and a biologic master file (BMF) was filed with the US. FDA. EBx® cells have already been licensed to over 22 Biotech and Pharma companies worldwide.
| 3:20 Production of
Animal-Free Recombinant Serum Proteins from Yeast for use in
Biopharmaceutical Manufacturing |
Sponsored by |
Chris Finnis, PhD. Molecular
Biology Manager, Novozymes Biopharma UK Ltd.
The use of animal-derived components in biomanufacturing carries a
risk of contamination with pathogenic prions and viruses. Novozymes has
used strains of the baker’s yeast, Saccharomyces cerevisiae, originally
engineered for the commercial production of recombinant human albumin (Recombumin®)
and albumin fusion proteins (e.g. Albuferon®), to produce the first
high-level microbial expression system for an animal-free recombinant
transferrin analogue. The transferrin product was functionally equivalent
to human serum transferrin and superior to commonly used iron salts in a
range of in vitro assays, including mammalian cell culture and IgG
productivity. This expression system has been scaled up for the cGMP
manufacture of an animal-free recombinant transferrin (CellPrime™
rTransferrin AF) from an FDA inspected facility, which is now available
for industrial cell culture applications. |
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3:35 Refreshment Break in the Exhibit Hall
4:15 Poster Awards in the Exhibit Hall
4:30 Title TBA
Gary Bright, Ph.D., Senior Director, Applications Development, Cyntellect,
Inc.
5:00 Effective Early Stage Clone Screening Using Flow Cytometry
Christine T. DeMaria, Ph.D., Senior Scientist, Therapeutic Protein
Expression, Genzyme Corporation
Flow cytometry was partnered with a non-fluorescent reporter protein for rapid,
early stage identification of clones producing high levels of a therapeutic
protein. A cell surface protein, not normally expressed on CHO cells, is
co-expressed, as a reporter, with the therapeutic protein and detected using a
fluorescently labelled antibody. The genes encoding the reporter protein and the
therapeutic protein are transcribed in the same mRNA but are translated
independently. Since they each arise from a common mRNA, the reporter protein’s
expression level accurately predicts the relative expression level of the
therapeutic protein for each clone. This method provides an effective process
for generating recombinant cell lines producing high levels of therapeutic
proteins, with the benefits of rapid and accurate 96-well plate clone screening
and elimination of unstable clones at an earlier stage in the development
process. Furthermore, because this method does not rely on the availability of
an antibody specific for the therapeutic protein being expressed, it can be
easily implemented into any cell line development process.
5:30 Close of Conference
Overview | Short
Courses | Day 1 |
Day 2 | Day 3 (Joint
Session) | Download Brochure
For more information, please contact:
Mary Ruberry, Conference Director
Phone: 781-972-5421
E-mail: mruberry@healthtech.com
For exhibit and sponsorship information, please contact:
Suzanne Carroll, Manager-Business
Development
Phone: 781-972-5452
E-mail: scarroll@healthtech.com
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