Cryopreservation of peripheral blood mononuclear cells for use in proliferation assays: First step towards potency assays.

Investigational cell-based therapeutics are rapidly heading towards pivotal clinical trials. The premise is that the scientific rationale is well defined, and that product quality reflects exactly this. In vitro potency assays are necessary tools for evaluating cell products, and with potency assays comes high demands for standardization and reproducibility of the methods involved. For demonstrating principles of cell therapeutics for allogeneic use or with claimed immunosuppressive efficacies, assays involving peripheral blood mononuclear cells (PBMC) are critical. Establishment of a cryopreserved bank of PBMC favors standardization, as it allows repeated use of a single donor and simultaneous testing of several donors. The first step to fulfil such potential is to ensure optimum conditions for preservation of PBMC function, and secondly to design assays which heightens the reproducibility. Emphasis should be put on application of the assay. The objective of the present study was to establish a methodological foundation for cell therapeutics to be tested, and several aspects were factored in, including cell concentrations and partial changes of medium. PBMC were isolated and cryopreserved in six formulations of cryoprotective medium consisting of fetal bovine serum (90%, 60%, and 30%) in combination with dimethyl sulfoxide (10% or 5%). The proliferative capacity of the cryopreserved cells was assayed by labeling with carboxyfluorescein succinimidyl ester and stimulation by phytohemagglutinin or in mixed lymphocyte reactions, analyzed by flow cytometry. To counter an eventual lag phase post thaw, the assays were designed to include two durations and to explore the possibility of reducing cell numbers, two cell concentrations. Qualitative and quantitative aspects of the staining were affected by formulation as well as design, stressing the importance of basic optimization for assay development. We conclude that the established methods allow for optimized preservation of function and will serve as a platform for further development of robust functional assays.