Advanced therapy medicinal products (ATMPs) require evaluation by the European Medicines Agency’s Committee for Advanced Therapies prior to being placed on the European market, subject to a Marketing Authorisation granted by the European Commission. In common with other medicinal products, various regulatory pathways are available for taking ATMPs through clinical trials to market authorisation, and the regulatory pathway taken will depend on a product’s characteristics and the target patient population. With the industry poised to deliver more late-stage clinical and commercial ATMPs for serious diseases with high unmet medical need (e.g., T cell immunotherapies for cancer), bringing medicines to patients through optimized regulatory strategies and expedited pathways is assuming greater importance. The European Medicines Agency’s priority medicines (PRIME) scheme was introduced in 2016 specifically to enable this, and eligibility has been granted to 19 ATMPs as of the fourth quarter (Q4) 2018. Furthermore, two chimeric antigen receptor (CAR) T cell therapies, Yescarta and Kymriah, have recently completed their journeys through the scheme to Marketing Authorisation. This review discusses how the regulatory pathway for any particular ATMP, with or without PRIME designation, is determined and navigated.
The quality attributes of advanced therapy medicinal products (ATMPs) that correlate with safety and efficacy in patients are determined not only by manufacturing process inputs such as starting and raw materials, but also by how the manufacturing process itself is designed and controlled. To ensure regulatory compliance, the manufacturing process should therefore be developed based on thorough characterization of the ATMP during all stages of process and analytical development; this ensures that the critical quality attributes that correlate with safety and efficacy are identified and that their specifications can be met during routine manufacturing. In the European Union, the regulatory approval of ATMPs for use in patients requires that data demonstrating their quality, safety and efficacy are submitted in dossiers to regulatory agencies for review. Indeed, such dossiers have a specific format that, in the case of quality data in particular, is informative for the manufacturing process development strategy. This manuscript describes how dossier requirements can be implemented into the design of industrialized ATMP manufacturing processes and fulfilled to enable effective regulatory submissions.
Human mesenchymal stromal cells (hMSCs) are excellent candidates for cell therapy but their expansion to desired clinical quantities can be compromised by ex vivo processing, due to differences between donor material and process variation. The aim of this article is to characterize growth kinetics of healthy baseline "reference" hMSCs using typical manual processing. Bone-marrow derived hMSCs from ten donors are isolated based on plastic adherence, expanded, and analyzed for their growth kinetics until passage 4. Results indicate that hMSC density decreases with overall time in culture (p < 0.001) but no significant differences are observed between successive passages after passage 1. In addition, fold increase in cell number dropped between passage 1 and 2 for three batches, which correlated to lower performance in total fold increase and expansion potential of these batches, suggesting that proliferative ability of hMSCs can be predicted at an early stage. An indicative bounded operating window is determined between passage 1 and 3 (PDL < 10), despite the high inter-donor variability present under standardized hMSC expansion conditions used. hMSC growth profile analysis will be of benefit to cell therapy manufacturing as a tool to predict culture performance and attainment of clinically-relevant yields, therefore stratifying the patient population based on early observation.
The basic functional responses of MSCs required for retention and engraftment alter rapidly even over a relatively short expansion period. This needs careful consideration when expanding cells to achieve clinical quantities for therapy.
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