Application of human mesenchymal and pluripotent stem cell microcarrier cultures in cellular therapy: Achievements and future direction

AbstractMesenchymal stem cells (MSCs) have recently made significant progress with multiple clinical trials targeting modulation of immune responses, regeneration of bone, cartilage, myocardia, and diseases like Metachromatic leukodystrophy and Hurler syndrome. On the other hand, the use of human embryonic and induced pluripotent stem cells (hPSCs) in clinical trials is rather limited mainly due to safety issues. Only two clinical trials, retinal pigment epithelial transplantation and treatment of spinal cord injury were reported. Cell doses per treatment can range between 50,000 and 6billion cells. The current 2-dimensional tissue culture platform can be used when low cell doses are needed and it becomes impractical when doses above 50million are needed. This demand for future cell therapy has reinvigorated interests in the use of the microcarrier platform for generating stem cells in a scalable 3-dimensional manner.Microcarriers developed for culturing adherent cell lines in suspension have been used mainly in vaccine production and research purposes. Since MSCs grow as monolayers similar to conventional adherent cell lines, adapting MSCs to a microcarrier based expansion platform has been progressing rapidly. On the other hand, establishing a robust microcarrier platform for hPSCs is more challenging as these cells grow in multilayer colonies on extracellular matrices and are more susceptible to shear stress.This review describes properties of commercially available microcarriers developed for cultivation of anchorage dependent cells and present current achievements for expansion and differentiation of stem cells. Key issues such as microcarrier properties and coatings, cell seeding conditions, medium development and improved bioprocess parameters needed for optimal stem cell systems are discussed

CELL CULTURE MEDIA FOR ENHANCED PROTEIN PRODUCTION

EP0973867A1Published Applicatio

Industrially compatible transfusable iPSC-derived RBCs: Progress, challenges and prospective solutions

10.3390/ijms22189808International Journal of Molecular Sciences2218980

Critical attributes of human early mesenchymal stromal cell-laden microcarrier constructs for improved chondrogenic differentiation

Abstract Background Microcarrier cultures which are useful for producing large cell numbers can act as scaffolds to create stem cell-laden microcarrier constructs for cartilage tissue engineering. However, the critical attributes required to achieve efficient chondrogenic differentiation for such constructs are unknown. Therefore, this study aims to elucidate these parameters and determine whether cell attachment to microcarriers throughout differentiation improves chondrogenic outcomes across multiple microcarrier types. Methods A screen was performed to evaluate whether 1) cell confluency, 2) cell numbers, 3) cell density, 4) centrifugation, or 5) agitation are crucial in driving effective chondrogenic differentiation of human early mesenchymal stromal cell (heMSC)-laden Cytodex 1 microcarrier (heMSC-Cytodex 1) constructs. Results Firstly, we found that seeding 10 × 103 cells at 70% cell confluency with 300 microcarriers per construct resulted in substantial increase in cell growth (76.8-fold increase in DNA) and chondrogenic protein generation (78.3- and 686-fold increase in GAG and Collagen II, respectively). Reducing cell density by adding empty microcarriers at seeding and indirectly compacting constructs by applying centrifugation at seeding or agitation throughout differentiation caused reduced cell growth and chondrogenic differentiation. Secondly, we showed that cell attachment to microcarriers throughout differentiation improves cell growth and chondrogenic outcomes since critically defined heMSC-Cytodex 1 constructs developed larger diameters (2.6-fold), and produced more DNA (13.8-fold), GAG (11.0-fold), and Collagen II (6.6-fold) than their equivalent cell-only counterparts. Thirdly, heMSC-Cytodex 1/3 constructs generated with cell-laden microcarriers from 1-day attachment in shake flask cultures were more efficient than those from 5-day expansion in spinner cultures in promoting cell growth and chondrogenic output per construct and per cell. Lastly, we demonstrate that these critically defined parameters can be applied across multiple microcarrier types, such as Cytodex 3, SphereCol and Cultispher-S, achieving similar trends in enhancing cell growth and chondrogenic differentiation. Conclusions This is the first study that has identified a set of critical attributes that enables efficient chondrogenic differentiation of heMSC-microcarrier constructs across multiple microcarrier types. It is also the first to demonstrate that cell attachment to microcarriers throughout differentiation improves cell growth and chondrogenic outcomes across different microcarrier types, including biodegradable gelatin-based microcarriers, making heMSC-microcarrier constructs applicable for use in allogeneic cartilage cell therapy

Selection of human induced pluripotent stem cells lines optimization of cardiomyocytes differentiation in an integrated suspension microcarrier bioreactor

10.1186/s13287-020-01618-6STEM CELL RESEARCH & THERAPY11

Establishing efficient siRNA knockdown in mouse embryonic stem cells

10.1007/s10529-006-9223-3Biotechnology Letters292261-265BILE

A serum free approach towards the conservation of chondrogenic phenotype during in vitro cell expansion

10.1080/08977190903137595Growth Factors275321-33