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.
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 CLLpatients' PBMC. To generate large numbers of Xcellerated T Cells of high purity from CLLpatients' 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 CLLpatients, 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 CLLpatients in clinical trials.
Authors: Aaron P Rapoport; Nicole A Aqui; Edward A Stadtmauer; Dan T Vogl; Hong-Bin Fang; Ling Cai; Stephen Janofsky; Anne Chew; Jan Storek; Gorgun Akpek; Ashraf Badros; Saul Yanovich; Ming T Tan; Elizabeth Veloso; Marcela F Pasetti; Alan Cross; Sunita Philip; Heather Murphy; Rita Bhagat; Zhaohui Zheng; Todd Milliron; Julio Cotte; Andrea Cannon; Bruce L Levine; Robert H Vonderheide; Carl H June Journal: Blood Date: 2010-10-28 Impact factor: 22.113
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Authors: Nicole J Piscopo; Katherine P Mueller; Amritava Das; Peiman Hematti; William L Murphy; Sean P Palecek; Christian M Capitini; Krishanu Saha Journal: Biotechnol J Date: 2017-09-18 Impact factor: 4.677
Authors: Aaron P Rapoport; Nicole A Aqui; Edward A Stadtmauer; Dan T Vogl; Yin Yan Xu; Michael Kalos; Ling Cai; Hong-Bin Fang; Brendan M Weiss; Ashraf Badros; Saul Yanovich; Gorgun Akpek; Patricia Tsao; Alan Cross; Dean Mann; Sunita Philip; Naseem Kerr; Andrea Brennan; Zhaohui Zheng; Kathleen Ruehle; Todd Milliron; Scott E Strome; Andres M Salazar; Bruce L Levine; Carl H June Journal: Clin Cancer Res Date: 2014-02-11 Impact factor: 12.531
Authors: Aaron P Rapoport; Edward A Stadtmauer; Nicole Aqui; Dan Vogl; Anne Chew; Hong-Bin Fang; Stephen Janofsky; Kelly Yager; Elizabeth Veloso; Zhaohui Zheng; Todd Milliron; Sandra Westphal; Julio Cotte; Hong Huynh; Andrea Cannon; Saul Yanovich; Gorgun Akpek; Ming Tan; Kristen Virts; Kathleen Ruehle; Carolynn Harris; Sunita Philip; Robert H Vonderheide; Bruce L Levine; Carl H June Journal: Clin Cancer Res Date: 2009-06-09 Impact factor: 12.531
Authors: Dawn A Maier; Andrea L Brennan; Shuguang Jiang; Gwendolyn K Binder-Scholl; Gary Lee; Gabriela Plesa; Zhaohui Zheng; Julio Cotte; Carmine Carpenito; Travis Wood; S Kaye Spratt; Dale Ando; Philip Gregory; Michael C Holmes; Elena E Perez; James L Riley; Richard G Carroll; Carl H June; Bruce L Levine Journal: Hum Gene Ther Date: 2013-03-06 Impact factor: 5.695