GMP production and testing of Xcellerated T Cells for the treatment of patients with CLL.

BACKGROUND: Pre-clinical studies suggest Xcellerated T Cells have the potential to produce a potent anti-tumor effect, restore broad immune function and reduce the risk of infectious complications in patients with CLL. Unlike other cancer settings, T cells constitute only a small fraction of CLL patients' PBMC. To generate large numbers of Xcellerated T Cells of high purity from CLL patients' PBMC, a reproducible, streamlined and cost-effective good manufacturing process (GMP) is required. METHODS: The 10-L volume Wave Bioreactor-based Xcellerate III Process using Xcyte Dynabeads in a single custom 20-L Cellbag container was adapted, qualified and implemented for GMP operations. RESULTS: For n=17 CLL patients, starting with approximately 1.34 x 10(9) CD3+ T cells at 6.8+/-7.5% purity in the PBMC leukapheresis products, using the 10-L volume Wave Bioreactor-based Xcellerate III Process, it was feasible to manufacture 137.0+/-34.3 x 10(9) Xcellerated T Cells at 98.5+/-1.0% CD3+ T-cell purity. An average 400-fold clearance of malignant B cells was documented during the manufacturing process. The Xcellerated T Cells produced from the Xcellerate III Process exhibited high in vitro biologic activity and have their T-cell receptor repertoire restored to a normal diversity. In-process T-cell activation was reproducibly robust, as measured by increase in cell size, up-regulation of CD25 and CD154 expression and the secretion of IL-2, IFN-gamma and tumor necrosis factor (TNF)-alpha. DISCUSSION: A low-volume, high-yield bioreactor-based process has been developed, qualified and implemented for the reproducible, GMP manufacture of high purity, biologically active Xcellerated T Cells for the treatment of CLL patients in clinical trials.

CD19 selection improves the sensitivity of B cell lymphoma detection.

Reinfusion of residual tumor cells into B cell non-Hodgkin's lymphoma (B-NHL) patients during autologous transplantation may be an important cause of disease relapse. Determining the extent to which B-NHL cells are present in autologous progenitor cell products and if the presence of residual B-NHL cells is predictive of relapse will require extremely sensitive methods of detecting rare B-NHL cells. We attempted to improve the sensitivity of polymerase chain reaction (PCR)-based detection of rare B-NHL cells by preselecting CD19+ cells using an immunomagnetic column. To measure detection sensitivity, we prepared samples containing different levels of B-NHL cell contamination by mixing B-NHL cell lines containing the chromosomal translocation t(14;18) bcl-2/JH) with control leukapheresis samples. DNA extracted from each CD19-selected sample and from each matched nonselected sample was added to a PCR to amplify the bcl-2/JH breakdown junction. CD19 preselection improved the sensitivity of detection of t(14;18)-positive B-NHL cells 115-fold, so that B-NHL cells at a concentration of 1 tumor cell per 1 x 10(6) hematopoietic cells were detected in every specimen evaluated. t(14;18)-positive cells were not detected in any of 13 control leukapheresis specimens. We conclude that a combination of CD19 preselection and PCR amplification may improve the sensitivity of detection of rare lymphoma cells by two orders of magnitude without a significant decrease in specificity.

Comparison of retroviral-mediated gene transfer into cultured human CD34+ hematopoietic progenitor cells derived from peripheral blood, bone marrow, and fetal umbilical cord blood.

Genetic alteration of stem cells ex vivo followed by bone marrow transplantation could potentially be used in the treatment of numerous diseases and malignancies. However, there are many unanswered questions as to the best source of hematopoietic cells for long-term reengraftment and the most effective way to introduce foreign genes into this target cell. We have compared retroviral-mediated gene transfer into CD34+-enriched cells derived from peripheral blood (PB), bone marrow (BM), or fetal umbilical cord blood (CB). Cells from all three sources that had been expanded ex vivo in the presence of stem cell factor (SCF), interleukin-3 (IL-3), IL-6, and granulocyte colony-stimulating factor (G-CSF) showed transduction efficiencies ranging from 5-45%, as measured by acquisition of G418 resistance. The average efficiencies of gene transfer from multiple experiments for PB, BM, and CB were not statistically different. To determine the effect of ex vivo expansion on gene transfer into CB CD34+ cells, we compared the transduction efficiencies of cells exposed to virus immediately after harvest and CD34 selection or after 6 days of culture CD34+ CB cells were more effectively transduced after expansion in culture, showing gene transfer efficiencies 3- to 5-fold higher on day 6 compared with day 0. Last, we examined retroviral transduction via spinoculation of CB CD34+ cells and found it to be approximately as effective as our standard transduction with no significant loss of cell viability as measured by colony formation in semi-solid medium.