Your search keyword '"Petry, Florian"' showing total 4 results

1. Large-Scale Expansion of Human Liver Stem Cells Using Two Different Bioreactor Systems.

Author

Thorbow, Jan, Strauch, Andrea, Pfening, Viktoria, Klee, Jan-Philip, Brücher, Patricia, Boshof, Björn, Petry, Florian, Czermak, Peter, Herrera Sanchez, Maria Beatriz, and Salzig, Denise

Subjects

HUMAN stem cells, CELLULAR aging, LACTATES, DENSITY, CONSUMPTION (Economics)

Abstract

The assessment of human liver stem cells (HLSCs) as cell therapeutics requires scalable, controlled expansion processes. We first focused on defining appropriate process parameters for HLSC expansion such as seeding density, use of antibiotics, optimal cell age and critical metabolite concentrations in conventional 2D culture systems. For scale-up, we transferred HLSC expansion to multi-plate and stirred-tank bioreactor systems to determine their limitations. A seeding density of 4000 cells cm−2 was needed for efficient expansion. Although growth was not significantly affected by antibiotics, the concentrations of lactate and ammonia were important. A maximum expansion capacity of at least 20 cumulative population doublings (cPDs) was observed, confirming HLSC growth, identity and functionality. For the expansion of HLSCs in the multi-plate bioreactor system Xpansion (XPN), the oxygen supply strategy was optimized due to a low kLa of 0.076 h−1. The XPN bioreactor yielded a final mean cell density of 94 ± 8 × 103 cells cm−2, more than double that of the standard process in T-flasks. However, in the larger XPN50 device, HLSC density reached only 28 ± 0.9 × 103 cells cm−2, while the glucose consumption rate increased 8-fold. In a fully-controlled 2 L stirred-tank bioreactor (STR), HLSCs expanded at a comparable rate to the T-flask and XPN50 processes in a homogeneous microenvironment using advanced process analytical technology. Ultimately, the scale-up of HLSCs was successful using two different bioreactor systems, resulting in sufficient numbers of viable, functional and undifferentiated HLSCs for therapeutic applications. [ABSTRACT FROM AUTHOR]

Published

2024

2. The cultivation conditions affect the aggregation and functionality of β‐cell lines alone and in coculture with mesenchymal stromal/stem cells

Author

Petry, Florian, primary and Salzig, Denise, additional

Published

2022

3. Large-Scale Production of Size-Adjusted β-Cell Spheroids in a Fully Controlled Stirred-Tank Reactor

Author

Petry, Florian, primary and Salzig, Denise, additional

Published

2022

4. Bioprocess Development for Human Mesenchymal Stem Cell Therapy Products

Author

Salzig, Denise, Czermak, Peter, Zitzmann, Jan, Petry, Florian, and Barekzai, Jan

Subjects

Technology & Engineering / Agriculture

Abstract

Mesenchymal stem cells (MSCs) are advanced therapy medicinal products used in cell therapy applications. Several MSC products have already advanced to phase III clinical testing and market approval. The manufacturing of MSCs must comply with good manufacturing practice (GMP) from phase I in Europe and phase II in the US, but there are several unique challenges when cells are the therapeutic product. Any GMP-compliant process for the production of MSCs must include the expansion of cells in vitro to achieve a sufficient therapeutic quantity while maintaining high cell quality and potency. The process must also allow the efficient harvest of anchorage-dependent cells and account for the influence of shear stress and other factors, especially during scale-up. Bioreactors are necessary to produce clinical batches of MSCs, and bioprocess development must therefore consider this specialized environment. For the last 10 years, we have investigated bioprocess development as a means to produce high-quality MSCs. More recently, we have also used bioreactors for the cocultivation of stem cells with other adult cells and for the production of MSC-derived extracellular vesicles. This review discusses the state of the art in bioprocess development for the GMP-compliant manufacture of human MSCs as products for stem cell therapy.

Published

2022