cGMP Compliance: What Does It Mean for Your Cell Lines?

As the promise for cell-based therapy grows, the interest in making clinically relevant cell lines has skyrocketed for industrial and academic researchers alike. For translation into human therapies, cell-based products must be made following current Good Manufacturing Practice (cGMP). Many groups have already claimed to generate cell lines that are “cGMP-compliant,” “cGMP-ready,” or “certifiable under cGMP.” But what does it take to be truly cGMP-compliant, and what practices can you introduce in your lab to comply with cGMP standards?

A common misconception in the United States is that a facility is granted a ‘cGMP license’ from the government to manufacture cGMP-grade products. Rather, the Food and Drug Administration (FDA) evaluates the manufacturing process for each product to determine if it is compliant with cGMP standards. The primary concern when it comes to deriving cell-based products for therapies is making sure that the product is derived in a safe and reproducible manner. To ensure maximum quality assurance, researchers should

• choose reliable, xenogeneic-free raw materials,
• establish and monitor a clean environment,
• qualify all equipment and software,
• remove variation in laboratory procedures by creating detailed Standard Operating Procedures (SOPs) and by providing rigid process validation at each step.

Nevertheless, even establishing robust quality assurance does not imply that the process is scalable for commercial production. In the world of biologics, “the product is the process.” A requisite step to ensure a smooth transition to cGMP practice is to ensure that the process of manufacturing is not altered due to changes in production scale. For example, depending on the therapy, millions or billions of cells may be required for a single patient. Therefore, it is in the best interest of the researchers to develop a scalable method at the beginning to avoid revamping the entire process (e.g., changing from adherent cells to suspension). Along these lines, the quality control (QC) requirements of cell-based products should be carefully considered and not have to include difficult-to-assay tests. For example, some cell lines have been qualified as cGMP-compliant upon conversion from research-grade conditions to cGMP quality standards. Rigorous tests were performed on the converted lines to ensure that the cells were free of contamination. Even though strict measures were carried out to ensure cGMP compliancy, deriving cell lines in this manner makes scalability and reproducibility a challenge. Ideally, the entire process of deriving cell products for clinical use should be performed under cGMP conditions: from the acquisition of human tissue to the manufacturing, testing, and storage of derivative cell products.

Another important consideration when instituting cGMP-compliance is documentation. Each process must be described with rigorous SOPs, the training of individual manufacturing operators must be well-documented, and the entire established process must be validated and well noted. Failure to document—in the eyes of the FDA—is often equated with failure to perform the underlying activity. It is equally important to remain ‘current.’ The FDA expects manufacturing processes to stay up-to-date with current regulations, even as policies change.

For an academic lab, closely aligning with cGMP standards can ensure that the resulting cell lines are comparable to other truly cGMP-produced products used during clinical trials. It is in the best interest of academic researchers to establish rigorous SOPs and use qualified reagents and equipment, even if it is not possible to carry out all steps in a certified cleanroom. Whenever possible, it is advisable to acquire truly cGMP cell lines from appropriate sources for preclinical projects; if prohibited by costs or other reasons, it is recommended to use a protocol that is as close to cGMP as possible.

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Allele Biotechnology & Pharmaceuticals Forming Cell Banking Business for Personalized Medicine

Allele to Generate Human iPS Cells under Good Manufacturing Practice for Private Individuals for Potential Therapeutic Use and Future diagnostics; Cell Banking Scientific Advisory Board formed

October 06, 2015 11:25 AM Eastern Daylight Time
SAN DIEGO–(BUSINESS WIRE)–Allele Biotechnology & Pharmaceuticals, Inc. (“Allele”), a leader in the development of specialized cells for regenerative medicine and pharmaceutical drug discovery, today announced plans to form a commercial business for the banking of human induced pluripotent stem cells (iPSCs) by private individuals.

Allele is pleased to have Drs. Mahendra Rao and Joseph Paulauskis as the first members of its Scientific Advisory Board (SAB) for iPSC banking and cGMP production. Dr. Rao is a world-renowned scientist in the fields of stem cells and medicine, having served as the VP of Regenerative Medicine at Invitrogen, founding Director of the NIH Center for Regenerative Medicine, Chair of the Biological Response Modifiers Committee (BRMAC, now CTAGT) of the FDA, and he is currently Chief Strategy Officer at Q Therapeutics. Dr. Paulauskis is the Chief Operating Officer of Paradigm Dx as well as the Vice-President of Research and Biobanking for the International Genomics Consortium, and has previously held senior positions in pharmacogenomics at Pfizer. Allele plans to make additional appointments to the SAB as individuals with world-class experience and expertise are identified.

Human iPSCs are cells that can be grown to virtually infinite numbers and can become any cell in the human body, features which hold great promise for therapies that can alleviate or cure human disease. Allele’s business model recognizes that an individual can have their own cells ready for future therapeutic use via the generation and storage of iPSCs from that individual’s skin cells. While this is similar to what is done with newborn cord blood, iPSCs can be generated from humans of any age. The banking of human iPSCs for potential future therapeutic use is a relatively new industry with unprecedented potential, and Allele is benefitting from expert opinions internally and from current and future SAB members, ensuring a solid scientific and ethical foundation for this business.

In addition to serving its customers, Allele’s iPSC bank will be an unparalleled resource for biomedical research. Proper consent and privacy guardianship will allow thousands of iPSC lines with accompanying sequence database and health information to be made available from the bank to scientists and clinicians. Currently, iPSC banks are funded by government agencies at multi-million dollar costs per project; Allele’s model does not rely on tax dollars and provides potentially a larger bank of iPSCs of higher quality to aid research and treatment efforts. To this end, NIH Director Dr. Francis Collins recently announced the implementation of the Precision Medicine Initiative (PMI), the goal of which is for health care professionals to have the resources to take into account individual differences in genes, environments, and lifestyles that contribute to disease when providing treatments in the new era.

“We are happy to have the guidance from world leading experts in stem cells, biobanking, and cell therapy fields such as Drs. Rao and Paulauskis”, said Jiwu Wang Ph.D., President and CEO of Allele. “We believe that setting the bar high will be ultimately beneficial to future customers, fellow researchers, industry partners, and regulatory agencies alike. We are happy to see the recent release by the International Society for Stem Cell Research of a draft of ‘Guidelines for the Clinical Translation of Stem Cells’, whose principals we plan to follow closely. We also intend to obtain certification by the cord blood banking association AABB, if possible, and abide by other regulatory rules as they become public, such as the “Stem Cell Clinical Research Management (tentative)” by the Health Commission of China, if and when we move to operate under that jurisdiction”.

Towards the establishment of this business effort, Allele has recently purchased an 18,000 square-foot facility, located near its headquarters in San Diego, California. This new facility will be the center of cGMP-production of human iPSCs using Allele’s proprietary synthetic mRNA platform, a technology that generates cells with neither the random integration of foreign DNA nor the use of viruses or virus-based elements, drawbacks common to other technologies for making hiPSCs; thus, the “footprint-free” cells generated by Allele’s synthetic mRNA platform are optimally suited for therapeutic use, and Allele’s technology has been licensed for clinical trials by companies such as Ocata Therapeutics (formerly ACT). This effort received strong support from Yuan Capital and Yifang Ventures.

About Allele Biotechnology & Pharmaceuticals, Inc.

Allele Biotechnology and Pharmaceuticals, Inc. is a private, San Diego-based company that explores the mechanisms of biological processes to develop technologies and products for biomedical researchers. Allele utilizes proprietary non-integrating cellular reprogramming methods to generate human and non-human primate iPS cells, GMP-grade human iPS cells and their derivatives, and differentiated cell types. With additional expertise in genome modification and cell-based sensors/reporters, Allele provides advanced cell-based assays for drug discovery. Allele also has developed a wide variety of reagents including superior fluorescent proteins and camelid antibodies. The company has also been a leader in the RNAi field with its patents in Pol III promoter-driven siRNA, shRNA, and miRNA.

Allele Biotechnology & Pharmaceuticals, Inc.
Matthew A. Singer, Ph. D.
Director of Business Development and Strategic Alliances
+1 858-587-6645, ext. 1

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