BACKGROUND: Natural killer (NK) cells, a subset of lymphocytes and part of the innate immune system, play a crucial role in defense against cancer and viral infection. Herein is a report on the experience of clinical-scale, good manufacturing practices (GMPs) production of NK cells to treat advanced cancer. STUDY DESIGN AND METHODS: Two types of NK cell enrichments were performed on nonmobilized peripheral blood mononuclear cell apheresis collections with a cell selection system (CliniMACS, Miltenyi): CD3 cell depletion to enrich for NK cells and CD3 cell depletion followed by CD56 cell selection to obtain a more pure NK cell product. After overnight incubation with interleukin-2 (IL-2), cells were washed, resuspended in 5 percent human serum albumin, and then released for infusion. RESULTS: A total of 70 NK cell therapy products have been manufactured for patient infusion since 2000. For the CD3 cell-depleted NK cell products, the mean purity, recovery, and viability were 38, 79, and 86 percent, respectively. For the CD3 cell-depleted/CD56 cell-enriched NK cell products, the mean purity, recovery, and viability were 90, 19, and 85 percent, respectively. Gram stain, sterility, and endotoxin testing were all within acceptable limits for established lot release. Compared to the resting processed cells, IL-2 activation significantly increased the function of cells in cytotoxicity assays. CONCLUSION: Clinical-scale production of NK cells is efficient and can be performed under GMPs. The purified NK cell product results in high NK cell purity with minimal contamination by T cells, monocytes, and B cells, but it requires more time for processing and results in a lower NK cell recovery when compared to NK cell enrichment with CD3 cell depletion alone. Additional laboratory studies and results from clinical trials will identify the best source and type of NK cell product.
BACKGROUND: Natural killer (NK) cells, a subset of lymphocytes and part of the innate immune system, play a crucial role in defense against cancer and viral infection. Herein is a report on the experience of clinical-scale, good manufacturing practices (GMPs) production of NK cells to treat advanced cancer. STUDY DESIGN AND METHODS: Two types of NK cell enrichments were performed on nonmobilized peripheral blood mononuclear cell apheresis collections with a cell selection system (CliniMACS, Miltenyi): CD3 cell depletion to enrich for NK cells and CD3 cell depletion followed by CD56 cell selection to obtain a more pure NK cell product. After overnight incubation with interleukin-2 (IL-2), cells were washed, resuspended in 5 percent human serum albumin, and then released for infusion. RESULTS: A total of 70 NK cell therapy products have been manufactured for patient infusion since 2000. For the CD3 cell-depleted NK cell products, the mean purity, recovery, and viability were 38, 79, and 86 percent, respectively. For the CD3 cell-depleted/CD56 cell-enriched NK cell products, the mean purity, recovery, and viability were 90, 19, and 85 percent, respectively. Gram stain, sterility, and endotoxin testing were all within acceptable limits for established lot release. Compared to the resting processed cells, IL-2 activation significantly increased the function of cells in cytotoxicity assays. CONCLUSION: Clinical-scale production of NK cells is efficient and can be performed under GMPs. The purified NK cell product results in high NK cell purity with minimal contamination by T cells, monocytes, and B cells, but it requires more time for processing and results in a lower NK cell recovery when compared to NK cell enrichment with CD3 cell depletion alone. Additional laboratory studies and results from clinical trials will identify the best source and type of NK cell product.
Authors: Hans Klingemann; Carrie Grodman; Elliott Cutler; Marvin Duque; Diane Kadidlo; Andreas K Klein; Kellie A Sprague; Kenneth B Miller; Raymond L Comenzo; Tarun Kewalramani; Neng Yu; Richard A Van Etten; David H McKenna Journal: Transfusion Date: 2012-06-28 Impact factor: 3.157
Authors: Scott A Koepsell; Diane M Kadidlo; Susan Fautsch; Jeffrey McCullough; Hans Klingemann; John E Wagner; Jeffrey S Miller; David H McKenna Journal: Transfusion Date: 2012-05-11 Impact factor: 3.157
Authors: Deborah Wood; Robin Wesselschmidt; Peiman Hematti; Adrian P Gee; Cliona Rooney; Leslie Silberstein; Myriam Armant; Larry Couture; John E Wagner; David H McKenna; Derek Hei; Traci Heath Mondoro; Lisbeth Welniak; Robert Lindblad Journal: Clin Transl Sci Date: 2014-03-21 Impact factor: 4.689
Authors: William Reed; Stephen J Noga; Adrian P Gee; Cliona M Rooney; John E Wagner; Jeffrey McCullough; David H McKenna; Theresa L Whiteside; Albert D Donnenberg; Acacia K Baker; Robert W Lindblad; Elizabeth L Wagner; Traci Heath Mondoro Journal: Transfusion Date: 2008-12-23 Impact factor: 3.157
Authors: Jeffrey S Miller; Cliona M Rooney; Julie Curtsinger; Ron McElmurry; Valarie McCullar; Michael R Verneris; Natalia Lapteva; David McKenna; John E Wagner; Bruce R Blazar; Jakub Tolar Journal: Biol Blood Marrow Transplant Date: 2014-05-09 Impact factor: 5.742
Authors: Natalia Lapteva; April G Durett; Jiali Sun; Lisa A Rollins; Leslie L Huye; Jian Fang; Varada Dandekar; Zhuyong Mei; Kimberley Jackson; Juan Vera; Jun Ando; Minhtran C Ngo; Elaine Coustan-Smith; Dario Campana; Susann Szmania; Tarun Garg; Amberly Moreno-Bost; Frits Vanrhee; Adrian P Gee; Cliona M Rooney Journal: Cytotherapy Date: 2012-08-17 Impact factor: 5.414
Authors: Jan Spanholtz; Marleen Tordoir; Diana Eissens; Frank Preijers; Arnold van der Meer; Irma Joosten; Nicolaas Schaap; Theo M de Witte; Harry Dolstra Journal: PLoS One Date: 2010-02-15 Impact factor: 3.240