Regulation of cell-based therapeutic products intended for human applications in the EU.

AIMS: Recent developments in the field of cell-based therapeutic products (CBTPs) have forced the EU to revise its legislation on therapeutic products by enacting several new legal instruments. In this study, we investigate how CBTPs are regulated and what determines their regulatory classification. Furthermore, we compare the regulatory burden between CBTPs in different product categories. MATERIALS & METHODS: Product categories covering CBTPs were identified and characteristics critical for the regulatory classification of a CBTP were determined in each category. The effect of the critical characteristics on the classification was evaluated by constructing a decision tree that covers all possible combinations of the critical characteristics. Differences in the regulatory burden between CBTPs were evaluated by comparing regulations crucial for placing a therapeutic product on the EU market between the product categories. RESULTS: Regulation of CBTPs has been divided between the main product categories of the EU legal framework for therapeutic products on the basis of the characteristics of the cells that the CBTPs contain. The regulatory burden is lowest for CBTPs regulated as blood, cells or tissues, and highest for CBTPs regulated as medicinal products. CONCLUSION: CBTPs exist in all product categories of the EU legal framework for therapeutic products. However, the current framework does not cover all possible CBTPs. Furthermore, our results indicate that the regulatory burden of a CBTP is related to the risk it may pose to the health and safety of recipients.

Monitoring mitochondrial inner membrane potential for detecting early changes in viability of bacterium-infected human bone marrow-derived mesenchymal stem cells.

INTRODUCTION: One of the most challenging safety issues in the manufacture of cell based medicinal products is the control of microbial risk as cell-based products cannot undergo terminal sterilization. Accordingly, sensitive and reliable methods for detection of microbial contamination are called for. As mitochondrial function has been shown to correlate with the viability and functionality of human mesenchymal stem cells (hMSCs) we have studied the use of a mitochondrial inner membrane potential sensitive dye for detecting changes in the function of mitochondria following infection by bacteria. METHODS: The effect of bacterial contamination on the viability of bone marrow-derived mesenchymal stem cells (BMMSCs) was studied. BMMSC lines were infected with three different bacterial species, namely two strains of Pseudomonas aeruginosa, three strains of Staphylococcus aureus, and three strains of Staphylococcus epidermidis. The changes in viability of the BMMSCs after bacterial infection were studied by staining with Trypan blue, by morphological analysis and by monitoring of the mitochondrial inner membrane potential. RESULTS: Microscopy and viability assessment by Trypan blue staining showed that even the lowest bacterial inocula caused total dissipation of BMMSCs within 24 hours of infection, similar to the effects seen with bacterial loads which were several magnitudes higher. The first significant signs of damage induced by the pathogens became evident after 6 hours of infection. Early changes in mitochondrial inner membrane potential of BMMSCs were evident after 4 hours of infection even though no visible changes in viability of the BMMSCs could be seen. CONCLUSIONS: Even low levels of bacterial contamination can cause a significant change in the viability of BMMSCs. Moreover, monitoring the depolarization of the mitochondrial inner membrane potential may provide a rapid tool for early detection of cellular damage induced by microbial infection. Accordingly, mitochondrial analyses offer sensitive tools for quality control and monitoring of safety and efficacy of cellular therapy products.

Mitochondrial function determines the viability and osteogenic potency of human mesenchymal stem cells.

Advanced therapies medicinal products (ATMPs) have introduced innovative cell-based products. However, the regulatory demands for characterization of ATMPs are currently unable to adequately address the safety of such products. As recent studies have emphasized the role of mitochondria in the osteogenic differentiation of human mesenchymal stem cells (hMSCs), we have studied in detail the viability and osteogenic differentiation potency of the hMSCs intended for use as ATMPs based on analyses of the mitochondrial inner membrane potential (DeltaPsi(m)). Flow cytometric measurement of 5,5',6,6'-tetrachloro-1,1',3,3'-tetraethylbenzimidazolcarbocyanine iodide (JC-1), propidium iodide fluorescence, and AnnexinV was employed to determine DeltaPsi(m), plasma membrane integrity, and organization of phosphatidylserine in plasma membrane, respectively, in cultured hMSCs. Apoptosis was induced by incubating cells at critical concentration (20 muM) of menadione. 3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) was used as an indicator for cell proliferation and alkaline phosphatase activity and calcium deposition as indicators of osteogenic differentiation. Based on JC-1 fluorescence, cell morphology, organization of phosphatidylserine, and plasma membrane integrity, we could sort cells into four categories that represented different cell quality. A strong correlation between JC-1 and osteogenic differentiation was demonstrated for the first time and thus this analytical tool is suitable not only to determine cell viability but also to predict osteogenic differentiation of hMSC.

Manufacturing, regulatory and commercial challenges of biopharmaceuticals production: a Finnish perspective.

Biopharmaceuticals product development is a broad and multidisciplinary field. Science and technology are combined with new manufacturing, regulatory and commercial challenges. However, although there is ample literature on the molecular biology and biochemistry of products, the implementation of processes from test tube to commercial scale has not received similar attention. Consequently, the present study aims to highlight, from practical point of view, some of the key issues involved with manufacturing technologies of biopharmaceuticals at a commercial scale. Regulatory requirements and investments are also addressed based on the practical experiences of start-up and small companies. Finland is used as a case-example of such companies as this is a EU-member state with strong technological growth and rapidly increasing number of biotech companies.