Testing Considerations for Novel Cell Substrates: A Regulatory Perspective

Transition in Cell Substrates

Different types of cell substrates such as animal tissues, primary cell cultures (PCCs), diploid cell strains (DCSs) or diploid cell lines, and continuous cell lines (CCLs) are used in U.S.-licensed vaccines (9–11). The history and challenges in the transition of cell substrates for use in biologics has been detailed previously (12, 13). PCCs were used from the 1950s for early viral vaccines (for example, primary monkey kidney cells). Human DCSs were introduced in the 1960s (for example, WI-38 and MRC-5) and later a fetal lung monkey diploid cell line (FRhL-2) was established and characterized for use in viral vaccines. The use of the Namalwa human cancer CCL in the 1970s to produce interferon along with the establishment of biotechnology in the 1980s led to the broader use of animal cells for highly purified therapeutic products such as recombinant proteins in Chinese hamster ovary (CHO) and baby hamster kidney (BHK) cells as well as in nonrodent cell lines such as human 293 cells, and monoclonal antibodies in mouse myelomas (NS0 and SP2/0). However, the introduction of CCLs in vaccines was met with greater caution related to the perceived risks associated with immortalized cells. These concerns included the potential transmission of tumorigenic and oncogenic activities and unknown adventitious viruses. The African green monkey Vero cell line was introduced in the 1980s due to its broad susceptibility to a variety of viruses, thereby making it a useful cell substrate for vaccine production as well as for biosafety testing. This was a result of extensive characterization and testing of Vero cells (14, 15) before being accepted by several control authorities for vaccine production. Licensed vaccines produced in Vero cells have been used in large populations in different countries with a demonstrated safety record (10). In the U.S., low-passage, non-tumorigenic Vero cells have been the only continuous animal cell line used in licensed viral vaccines (11). Guidance for cell substrate safety and product quality is provided by various national and international regulatory documents (3–8, 16–20).

Due to the need for novel vaccines against emerging and re-emerging diseases and bioterrorism agents, and the demand for large-scale production in a short timeframe, novel cell substrates are being introduced for the development of vaccines. Since 1998, the U.S. Food and Drug Administration (FDA) has been involved in public discussions related to the use of tumorigenic cells in viral vaccines (11). These scientific discussions helped identify additional safety issues pertaining to use of a novel cell substrate in vaccines and facilitated the use of tumorigenic cells for some investigational vaccines such as Madin-Darby canine kidney (MDCK) cells for influenza vaccines and genetically engineered human 293 and PER.C6 cell lines for defective, adenovirus-vectored vaccines.

Safety Issues Related to Novel Cell Substrates

Novel cell substrates currently being used for some investigational products or under consideration for future products can be broadly grouped into naturally occurring cells and genetically engineered cell lines (Table I). Naturally occurring cell substrates are generally selected based upon their susceptibility to vaccine viruses or vectors and high product yield. Currently, there are a variety of cell substrates for a variety of investigational products including viral vaccines, cancer vaccines, gene therapy vectors, and therapeutics. These include mammalian tumorigenic cell lines and tumor-derived cells, avian embryonic stem cells and cell lines, insects and insect cell lines, plants and plant cell lines, as well as bacteria. Genetically engineered cell lines were developed to meet unique production needs, for example, specific cell lines for complementation or packaging of defective, viral vectors or stable transfectants for high expression of protein products. Additionally, the lack of adequate documentation regarding cell passage history (discussed later) has resulted in the development of new-generation, well-characterized cell lines for high virus particle or protein yield or designed for specific viral vectors.

An important safety concern related to cell substrates is the presence of viral contaminants. These (1) may be introduced as exogenous viruses in the cell line during its derivation and passage in vitro; (2) may be present as indigenous viruses that are naturally occurring in the species of cell origin due to infection such as latent DNA viruses (such as adeno-associated viruses, adenoviruses, hepadenaviruses, herpesviruses, papillomaviruses, and polyomaviruses) and some RNA viruses (for example, arenaviruses such as lymphocytic choriomeningitis virus (LCMV) (21); or (3) may occur as endogenous retroviruses that exist as a normal part of the host cell DNA and can be present in a silent or active state. There may be additional safety concerns related to tumorigenic cells, such as tumorigenicity of intact cells and the perceived risk of oncogenicity of residual cellular DNA. Novel vectors such as adenovirus-associated viruses pose potential concerns related to integration into the host genome, and, in the case of genetically engineered cells, the generation of replication-competent viruses (RCVs), such as replication-competent retroviruses, adenoviruses, or lentiviruses, may be an added safety concern. Additionally, co-packaging of “unwanted” RNAs or DNAs may be a concern in case of virus-like particles and packaged virions.

Comprehensive Safety Scheme for Cell Substrate Testing

Cell substrate and product safety involves development of a comprehensive safety plan that includes testing for known and novel adventitious viruses and implementing steps and procedures to minimize the risk of virus contamination. General considerations for development of such a plan are two-fold: risk assessment of cell substrate contamination and evaluation of risk reduction. The risk of cell substrate contamination can be assessed by obtaining information regarding (a) the host species of origin (e.g., the donor health and any naturally occurring viruses or immunization with live, viral vaccines, if relevant); (b) the cell passage history (e.g., the potential of adventitious agent introduction due to the length and conditions used in cell line development, handling, raw materials, or use of other cell lines in the facility); and (c) cell characteristics such as genotype (diploidy vs aneuploidy or heteroploidy) and phenotype (nontumorigenic vs tumorigenic). Evaluation for risk reduction can be done by obtaining information related to (a) the susceptibility of the cells to known viruses; b) whether there are any inactivation or clearance steps during the manufacturing process; c) design of genetic modifications in the cells that may reduce the generation of RCVs; and d) the use of qualified biological starting materials (e.g., virus seed or vector virus stock) and reagents (e.g., serum, trypsin).

General Considerations for Product Safety

The development of a comprehensive testing regimen and implementation of a safety plan is critical for assuring product quality and safety. This may be achieved by developing comprehensive testing regimens for detection of known and unknown adventitious viruses to minimize the risk of virus contamination and by including steps in the manufacturing process to inactivate and/or remove contaminating viruses to maximize virus clearance. The salient features of designing safety in biologics include characterization of the cell substrate (e.g., the cell phenotype with regard to tumorigencity, which may be associated with oncogenic viruses or DNA), qualification of cell banks, virus seed/vectored virus and biological raw materials (by extensive testing using general and specific virus detection assays and using raw materials that are certified or tested to be free of detectable virus), in-process testing (based upon a comprehensive testing plan to evaluate bulk/production lots for known and novel virus contaminants), and process validation (efficiently designed to avoid risk of contamination, to eliminate or reduce potential adventitious viral load, and to inactivate potentially contaminating viruses). Additionally, steps need to be present in the manufacturing to reduce the residual host cell material in the final product such as removal of whole cells and removal/reduction of cellular DNA and proteins. The successful implementation of such a strategy will document the absence of contaminating viruses in the raw materials, or their introduction during the manufacture.