BACKGROUND AIMS: The Quantum® Cell Expansion System (Quantum; Terumo BCT, Inc, Lakewood, CO, USA) is a novel hollow fiber-based device that automates and closes the cell culture process, reducing labor intensive tasks such as manual cell culture feeding and harvesting. The manual cell selection and expansion processes for the production of clinical-scale quantities of bone marrow-derived human mesenchymal stromal cells (BM-hMSCs) have been successfully translated onto the Quantum platform previously. The formerly static, manual, in vitro process performed primarily on tissue culture polystyrene substrates may raise the question of whether BM-hMSCs cultured on a hollow fiber platform yields comparable cell quality. METHODS: A rigorous battery of assays was used to determine the genetic stability of BM-hMSCs selected and produced with the Quantum. In this study, genetic stability was determined by assessing spectral karyotype, micronucleus formation and tumorigenicity to resolve chromosomal aberrations in the stem cell population. Cell phenotype, adherent growth kinetics and tri-lineage differentiation were also evaluated. HMSC bone marrow aspirates, obtained from three approved donors, were expanded in parallel using T225 culture flasks and the Quantum. RESULTS: BM-hMSCs harvested from the Quantum demonstrated immunophenotype, morphology and tri-lineage differentiation capacity characteristics consistent with the International Society of Cell Therapy standard for hMSCs. Cell populations showed no malignant neoplastic formation in athymic mice 60 days post-transplant, no clonal chromosomal aberrations were observed and no DNA damage was found as measured by micronucleus formation. CONCLUSIONS: Quantum-produced BM-hMSCs are of comparable quality and demonstrate analogous genetic stability to BM-hMSCs cultured on tissue culture polystyrene substrates.
BACKGROUND AIMS: The Quantum® Cell Expansion System (Quantum; Terumo BCT, Inc, Lakewood, CO, USA) is a novel hollow fiber-based device that automates and closes the cell culture process, reducing labor intensive tasks such as manual cell culture feeding and harvesting. The manual cell selection and expansion processes for the production of clinical-scale quantities of bone marrow-derived human mesenchymal stromal cells (BM-hMSCs) have been successfully translated onto the Quantum platform previously. The formerly static, manual, in vitro process performed primarily on tissue culture polystyrene substrates may raise the question of whether BM-hMSCs cultured on a hollow fiber platform yields comparable cell quality. METHODS: A rigorous battery of assays was used to determine the genetic stability of BM-hMSCs selected and produced with the Quantum. In this study, genetic stability was determined by assessing spectral karyotype, micronucleus formation and tumorigenicity to resolve chromosomal aberrations in the stem cell population. Cell phenotype, adherent growth kinetics and tri-lineage differentiation were also evaluated. HMSC bone marrow aspirates, obtained from three approved donors, were expanded in parallel using T225 culture flasks and the Quantum. RESULTS: BM-hMSCs harvested from the Quantum demonstrated immunophenotype, morphology and tri-lineage differentiation capacity characteristics consistent with the International Society of Cell Therapy standard for hMSCs. Cell populations showed no malignant neoplastic formation in athymic mice 60 days post-transplant, no clonal chromosomal aberrations were observed and no DNA damage was found as measured by micronucleus formation. CONCLUSIONS: Quantum-produced BM-hMSCs are of comparable quality and demonstrate analogous genetic stability to BM-hMSCs cultured on tissue culture polystyrene substrates.
Authors: J J Montesinos; E Flores-Figueroa; S Castillo-Medina; P Flores-Guzmán; E Hernández-Estévez; G Fajardo-Orduña; S Orozco; H Mayani Journal: Cytotherapy Date: 2009 Impact factor: 5.414
Authors: Marileila Varella-Garcia; Lin Chen; Roger L Powell; Fred R Hirsch; Timothy C Kennedy; Robert Keith; York E Miller; John D Mitchell; Wilbur A Franklin Journal: Am J Respir Crit Care Med Date: 2007-06-28 Impact factor: 21.405
Authors: David A Castilla-Casadiego; Ana M Reyes-Ramos; Maribella Domenech; Jorge Almodovar Journal: Ann Biomed Eng Date: 2019-11-08 Impact factor: 3.934
Authors: Haifeng Wang; Lianyu Chen; Yang Liu; Bangzhen Luo; Nanzi Xie; Tao Tan; Lige Song; Pei Erli; Ming Luo Journal: Am J Transl Res Date: 2016-11-15 Impact factor: 4.060
Authors: Ayesha Aijaz; Matthew Li; David Smith; Danika Khong; Courtney LeBlon; Owen S Fenton; Ronke M Olabisi; Steven Libutti; Jay Tischfield; Marcela V Maus; Robert Deans; Rita N Barcia; Daniel G Anderson; Jerome Ritz; Robert Preti; Biju Parekkadan Journal: Nat Biomed Eng Date: 2018-06-11 Impact factor: 25.671
Authors: Patrick J Hanley; Zhuyong Mei; April G Durett; Maria da Graca Cabreira-Hansen; Marie da Graca Cabreira-Harrison; Mariola Klis; Wei Li; Yali Zhao; Bing Yang; Kaushik Parsha; Osman Mir; Farhaan Vahidy; Debra Bloom; R Brent Rice; Peiman Hematti; Sean I Savitz; Adrian P Gee Journal: Cytotherapy Date: 2014-04-13 Impact factor: 5.414