Project description:BACKGROUND: Cell-based regeneration therapies hold great promise and potential for new area in clinical medicine, although some obstacles still remain to be overcome for a wide range of clinical applications. One of the major impediments in this field is difficulties in large-scale production of cells of interest with reproducibility. Current protocol of cell therapy requires a long-time laborious manual process. To solve this problem, we focused on the robotics of automated and high throughput cell culture system. To date, an automated robotic cultivation of stem or progenitor cells in clinical trials has not been reported. METHODS: The system, AutoCulture®, used in this study can automatically replace the medium, centrifuge cells, split the cells, and take a photograph for their morphology. We examined the feasibility to use it in the clinical field by comparing the growth rate and the characteristics of cardiac stem cells (CSCs) cultivated by AutoCulture and the manual handling culture, which protocol is the exact same as current performing clinical trial in our institute. RESULTS: We demonstrated similar characteristics in both culture methods, in terms of growth rates, gene expression profiles, cell surface profiles by FACS, carbon hydrate structures on the cell surface, and genomic DNA stability. IMPLICATIONS: The results of this study showed that AutoCulture is feasible to cultivate human cells for regenerative medicine. An automated cell-processing machine for cell therapy will play more important role, as it will be widespread from multi-center trials to off-the-shelf cell products. The cells were cultured by manual handling or by the automatic cell culture apparatus. Total RNA was extracted from these cells at day 7 by the RNeasy Plus Mini Kit (QIAGEN). Gene expression analysis was performed using the Agilent Whole Human Genome Microarray chips G4112F (Agilent). Raw data were normalized and analyzed by GeneSpring GX11 software.

Project description:Ex vivo activation and expansion of natural killer (NK) cells is a strategy to produce sufficient numbers of these effector cells for adoptive immunotherapy. Therefore we aimed at the development of an automated, clinical scale NK cell expansion process and compared NK cells after manual and automated expansion.We found only a small subset of 124 genes that significantly varied between both sample groups. These genes were associated with movement of leukocytes were identified including a group of genes for NK cell movement (CMKLR1, CX3CR1, S1PR5, GNLY and CXCR1) which were slightly higher expressed after automated compared to manual expansion. Nevertheless, the expansion profiles of NK cells after automated or manual expansion were rather similar in comparison to the remarkable difference between primary and expanded NK cells in general represented by the vast majority of regulated genes between the analyzed sample groups. Pathway analysis revealed that most of regulated genes upon expansion were associated with cell cycle regulation, DNA replication, DNA recombination and DNA repair, regulation of apoptosis and cell survival as well as cytokine signaling. Furthermore, the expression of many NK cell relevant markers was changed upon expansion with the strongest effects on up regulation of TRAIL and FASL, inhibitory TIGIT and chemokine receptors CCR2, CCR5 and CXCR6. In addition, granzyme M was down regulated but other important effector molecules like TNFa, perforin and granzymes A, B and K were up regulated. In summary we could show that manual and automatically expanded NK cells show a similar expansion profile while the differ significantly from primary NK cells. Up regulation of many NK cell relevant markers indicate for an enhanced NK cell functionaility after ex vivo activation and expansion.

Project description:Abstract The therapeutic properties of extracellular vesicles (EVs) derived from stem cells and stem-like cells make them promising cell-free alternative to regenerative medicine. However, clinical translation of this technology relies heavily on the ability to manufacture EVs in a scalable, reproducible, cGMP-compliant manner. The choice of cell culture media is a critical component for EV manufacturing. In this study, we used human amniotic epithelial cells (hAECs) as a cell model system to explore the effect of chemically defined serum-free media on EV production. Here we showed that different culture media and different cell culture supplements have variable effects on EV production including culture parameters, EV yield, and EV biogenesis. Cell viability and proliferation rate are not reliable quality indicators of EV manufacturing. The levels of common EV tetraspanins and epitope makers can be impacted by different culture media formulations even when culture parameters are maintained, and EV yield are comparable. This study has uncovered some critical aspects regarding EV production culture media that need to be considered in clinical-grade scalable EV manufacturing.

Project description:Induced pluripotent stem cells (iPSCs) have become an essential tool for both modeling how causal genetic variants impact cellular function in disease, as well as being an emerging source of tissue for transplantation medicine. Unfortunately the preparation of somatic cells, their reprogramming and the subsequent verification of iPSC pluripotency are laborious, manual processes that limit the scale and level of reproducibility of this technology. Here we describe a modular, robotic platform for iPSC reprogramming that enables automated, high-throughput conversion of skin biopsies into iPSCs and differentiated cells with minimal manual intervention. Using this platform, we demonstrate that automated reprogramming and the pooled selection of pluripotent cells results in high quality, stable, iPSCs. These lines display less line-to-line variation than either manually produced lines or lines produced through automation followed by single colony-subcloning. The robotic platform we describe will enable the application of iPSCs to population-scale biomedical problems including the study of complex genetic diseases and the development of personalized medicines.

Project description:Ex vivo activation and expansion of natural killer (NK) cells is a strategy to produce sufficient numbers of these effector cells for adoptive immunotherapy. Therefore we aimed at the development of an automated, clinical scale NK cell expansion process and compared NK cells after manual and automated expansion.We found only a small subset of 124 genes that significantly varied between both sample groups. These genes were associated with movement of leukocytes were identified including a group of genes for NK cell movement (CMKLR1, CX3CR1, S1PR5, GNLY and CXCR1) which were slightly higher expressed after automated compared to manual expansion. Nevertheless, the expansion profiles of NK cells after automated or manual expansion were rather similar in comparison to the remarkable difference between primary and expanded NK cells in general represented by the vast majority of regulated genes between the analyzed sample groups. Pathway analysis revealed that most of regulated genes upon expansion were associated with cell cycle regulation, DNA replication, DNA recombination and DNA repair, regulation of apoptosis and cell survival as well as cytokine signaling. Furthermore, the expression of many NK cell relevant markers was changed upon expansion with the strongest effects on up regulation of TRAIL and FASL, inhibitory TIGIT and chemokine receptors CCR2, CCR5 and CXCR6. In addition, granzyme M was down regulated but other important effector molecules like TNFa, perforin and granzymes A, B and K were up regulated. In summary we could show that manual and automatically expanded NK cells show a similar expansion profile while the differ significantly from primary NK cells. Up regulation of many NK cell relevant markers indicate for an enhanced NK cell functionaility after ex vivo activation and expansion. 24 samples were analyzed in total. 6 biological replicates represented by cells from different donors. 4 different samples per donor: freshly isolated NK cells (d0) and NK cells expanded for 14 days under 3 different conditions: in co-culture with EBV-LCL feeder cells and 500 U/mL IL2 either cultivated manually in T75 flasks (T) or automatically using the CliniMACS Prodigy system (P); NK cells cultured with 500 U/ml IL2 without feeder cells (I)

Project description:We present AutoRELACS, an automated implementation of the RELACS protocol using the Biomek i7 automated workstation (Beckman&Coulter). We test the performance of AutoRELACS by assessing 1) the scalability of the chromatin barcode integration step, 2) the quality of the generated data in comparison to the benchmark set by the manual protocol, and 3) the sensitivity of the automated method when working with low (≤ 25.000 cells/sample) and very low (≤ 5.000 cells/sample) cell numbers.

Project description:Although tandem mass tag (TMT)-based isobaric labeling has become a powerful technique for multiplexed protein quantitation, it has not been easy to automate the workflow for widespread adoption. This is because preparation of TMT labeled peptide samples involves multiple steps ranging from protein extraction, denaturation, reduction and alkylation to tryptic digestion, desalting, labeling with TMT reagents and cleanup, all of which require a high level of proficiency. The variability resulting from multiple processing steps is inherently problematic especially with large-scale studies such as clinical studies that involve hundreds of samples where reproducibility is critical for quantitation. Here, we sought to compare the performance of a recently introduced platform, AccelerOme, for automated proteomics workflows for TMT-labeling experiments with manual processing of samples. Cell pellets were prepared and subjected to a 16-plex experiment using the automated platform and a conventional manual protocol. Single shot LC-MS/MS analysis revealed a higher number of proteins and peptides identified using the automated platform. Efficiencies of tryptic digestion, alkylation and TMT labeling were similar both in manual and automated process. In addition, comparison of quantitation accuracy and precision showed similar performance in automated workflow compared to manual sample preparation. Overall, we demonstrated that the automated platform performs at a level similar to manual process in TMT-based proteomics. We expect that the automated workflow will increasingly replace manual work and be applied to large-scale TMT-baed studies providing robust results and high sample throughput.

Project description:Adoptive T cell therapy with gene-modified T cells expressing chimeric antigen receptor (CAR) is a rapidly growing field of translational medicine and recently has shown dramatic therapeutic success in the treatment of B-cell malignancies. However, challenges to achieve similar response in patients harboring solid tumour are still considerable. To achieve anti-tumor efficacy, these cells must survive, expand and persist after infusion into patients. An important lesson has been derived from clinical trials using CAR technologies: the relevance of the CAR design to enhance signaling and sustain T cell proliferation and survival. Here, we prove that third generation CARs specific for GD2 antigen incorporating CD28.4-1BB costimulatory domains improves T cell immunotherapy in a neuroblastoma (NB) pre-clinical model, as compared to a CAR with the same specificity but including CD28.OX40 costimulation. Indeed, we test the anti-tumor activity of polyclonal T cells genetically modified with third generation CAR.GD2 incorporating either CD28.4-1BB or CD28.OX40 in frame with the safety switch inducible Caspase 9 (iC9). We prove a significant in vitro and in vivo amelioration of the approach by the presence of 4.1BB signaling in terms of: 1) less T cell exhaustion, 2) lower basal T cell activation, 3) higher in vivo tumor control and 4) T cell persistence. In addition, the fine tuning of T cell culture conditions with the use of IL7 and IL15 show to be synergic with the third generation CAR.GD2 design to optimize CAR T immunotherapy for NB. Our results provide a proof-of-concept for the need to optimize not only CAR construct design but also T cell culture conditions in order to boost T cell activity in vivo.

Project description:Therapeutic benefits of mesenchymal stem/stromal cells (MSCs) are now widely believed to come from their paracrine signalling, i.e. secreted factors such as cytokines, chemokines, and extracellular vesicles (EVs). Cell-free therapy using EVs is an active and emerging field in regenerative medicine. The cellular environment of MSCs is of critical importance when directing paracrine activity. Typical 2D cultivation of stem cells on tissue culture plastic is far removed from the physiological environment of MSCs. The application of 3D cell culture allows MSCs to adapt to their cellular niche environment which, in turn, influences their paracrine signalling activity. In this study we evaluated the impact of 3D MSCs culture on EVs secretion and cargo proteome composition and functional assessment. The outcome highlights critical differences between MSC-EVs obtained from different culture microenvironments, which should be considered when scaling up MSC culture for clinical manufacturing.

Project description:Induced pluripotent stem cells (iPSCs) are usually clonally derived. The selection of fully reprogrammed cells generally involves picking of individual colonies with morphology similar to embryonic stem cells (ESCs). However, successfully reprogrammed cells are highly proliferative and escape from cellular senescence - it is therefore conceivable that they outgrow non-pluripotent and partially reprogrammed cells during culture expansion without the need of clonal selection. In this study, we have reprogrammed human dermal fibroblasts (HDFs) with episomal plasmid vectors. Colony frequency and size was higher when using murine embryonic fibroblasts (MEFs) as stromal support instead of HDFs or human mesenchymal stromal cells (MSCs). We have then compared iPSCs which were either clonally derived by manual selection of a single colony, or derived from bulk-cultures of all initial colonies. After few passages their morphology, expression of pluripotency markers, and gene expression profiles did not reveal any significant differences. Furthermore, clonally-derived and bulk-cultured iPSCs had indistinguishable in vitro differentiation potential towards the three germ layers. Therefore, manual selection of individual colonies does not appear to be necessary for the generation of iPSCs – this is of relevance for standardization and automation of cell culture procedures