Effect of partial oxygen pressure on survival, proliferation, and differentiation of mouse bone marrow mesenchymal stem cells

Effects of partial oxygen pressure in a gas mixture surrounding the culture medium on survival, proliferation and differentiation of mesenchymal stem cells (MSC) isolated from mouse bone marrow was studied. It was found that 3% oxygen increased the survival of cells seeded at low density; the rate and duration of the MSC proliferation were also elevated. Effect of oxygen concentration on replicative activity of MSC was manifested as early as the first few days after the onset of cell growth. Studies of colony formation revealed that preincubation of cells with 21% oxygen had a negative effect on cell growth under 3% oxygen, while preincubation with 3% oxygen stimulated MSC proliferation in the presence of 21% oxygen. Notwithstanding, this effect of oxygen cannot be interpreted as unequivocally deleterious. Low partial oxygen pressure inhibited osteogenic differentiation of MSC, but adipogenic differentiation was insensitive to oxygen concentration. It is concluded that proliferation and differentiation of MSC depend critically on oxygen content in the culture medium.     

Low physiologic oxygen tensions reduce proliferation and differentiation of human multipotent mesenchymal stromal cells

Background

Human multipotent mesenchymal stromal cells (MSC) can be isolated from various tissues including bone marrow. Here, MSC participate as bone lining cells in the formation of the hematopoietic stem cell niche. In this compartment, the oxygen tension is low and oxygen partial pressure is estimated to range from 1% to 7%. We analyzed the effect of low oxygen tensions on human MSC cultured with platelet-lysate supplemented media and assessed proliferation, morphology, chromosomal stability, immunophenotype and plasticity.

Results

After transferring MSC from atmospheric oxygen levels of 21% to 1%, HIF-1α expression was induced, indicating efficient oxygen reduction. Simultaneously, MSC exhibited a significantly different morphology with shorter extensions and broader cell bodies. MSC did not proliferate as rapidly as under 21% oxygen and accumulated in G₁ phase. The immunophenotype, however, was unaffected. Hypoxic stress as well as free oxygen radicals may affect chromosomal stability. However, no chromosomal abnormalities in human MSC under either culture condition were detected using high-resolution matrix-based comparative genomic hybridization. Reduced oxygen tension severely impaired adipogenic and osteogenic differentiation of human MSC. Elevation of oxygen from 1% to 3% restored osteogenic differentiation.

Conclusion

Physiologic oxygen tension during in vitro culture of human MSC slows down cell cycle progression and differentiation. Under physiological conditions this may keep a proportion of MSC in a resting state. Further studies are needed to analyze these aspects of MSC in tissue regeneration.     

Substrate Stiffness and Oxygen as Regulators of Stem Cell Differentiation during Skeletal Tissue Regeneration: A Mechanobiological Model

Extrinsic mechanical signals have been implicated as key regulators of mesenchymal stem cell (MSC) differentiation. It has been possible to test different hypotheses for mechano-regulated MSC differentiation by attempting to simulate regenerative events such as bone fracture repair, where repeatable spatial and temporal patterns of tissue differentiation occur. More recently, in vitro studies have identified other environmental cues such as substrate stiffness and oxygen tension as key regulators of MSC differentiation; however it remains unclear if and how such cues determine stem cell fate in vivo. As part of this study, a computational model was developed to test the hypothesis that substrate stiffness and oxygen tension regulate stem cell differentiation during fracture healing. Rather than assuming mechanical signals act directly on stem cells to determine their differentiation pathway, it is postulated that they act indirectly to regulate angiogenesis and hence partially determine the local oxygen environment within a regenerating tissue. Chondrogenesis of MSCs was hypothesized to occur in low oxygen regions, while in well vascularised regions of the regenerating tissue a soft local substrate was hypothesised to facilitate adipogenesis while a stiff substrate facilitated osteogenesis. Predictions from the model were compared to both experimental data and to predictions of a well established computational mechanobiological model where tissue differentiation is assumed to be regulated directly by the local mechanical environment. The model predicted all the major events of fracture repair, including cartilaginous bridging, endosteal and periosteal bony bridging and bone remodelling. It therefore provides support for the hypothesis that substrate stiffness and oxygen play a key role in regulating MSC fate during regenerative events such as fracture healing.     

Jagged1 protein enhances the differentiation of mesenchymal stem cells into cardiomyocytes

BACKGROUND: Mesenchymal stem cells (MSCs) can differentiate into cardiomyocytes if an appropriate cellular environment is provided. Notch signals exchanged between neighboring cells through the Notch receptor can eventually dictate cell differentiation. In our study, we show that MSC differentiation into cardiomyocytes is dependent on the Notch signal. METHODS: We created a myocardial infarction model in rat by coronary ligation, administered direct intramyocardial injection of DAPI-labeled MSC immediately, and observed the differentiation of MSCs after 14 days by immunofluorescence staining against troponin T. We cultured MSCs and cardiomyocytes in four ways, respectively, in vitro. (1) MSCs cocultured with cardiomyocytes obtained from neonatal rat ventricles in a ratio of 1:10. (2) The two types of cells were cultured in two chambers separated by a semipermeable membrane as indirect coculture group. (3) Notch receptor-soluble jagged1 protein was added to indirect coculture group. (4) Both jagged1 protein and gamma-secretase inhibitor-DAPT were added to indirect coculture group. Two weeks later, we observed the differentiation percentage, respectively, by immunofluorescence staining. RESULTS: We found the differentiation of MSCs which were close to cardiomyocytes in vivo. The differentiation percentage of the four cell culture group was 30.13+/-2.16%, 12.52+/-1.18%, 26.33+/-2.20%, and 13.08+/-1.15%. CONCLUSIONS: MSCs can differentiate into cardiomyocytes in vitro and in vivo if a cardiomyocyte microenvironment is provided. 2. Cell-to-cell interaction is very important for the differentiation of MSCs into cardiomyocytes. 3. Jagged1 protein can activate Notch signal and enhance the differentiation of MSC into cardiomyocyte, while the effect can be inhibited by DAPT.     

Difluoromethylornithine stimulates early cardiac commitment of mesenchymal stem cells in a model of mixed culture with cardiomyocytes

The efficiency of in vitro mesenchymal stem cell (MSC) differentiation into the myocardial lineage is generally poor. In order to improve cardiac commitment, bone marrow GFP+MSCs obtained from transgenic rats were cultured with adult wild type rat cardiomyocytes for 5 days in the presence of difluoromethylornithine (DFMO), an inhibitor of polyamine synthesis and cell proliferation. The percentage of GFP+MSCs showing cardiac myofibril proteins (cMLC2, cTnI) was about threefold higher after DFMO addition (3%) relative to the untreated control (1%). Another set of experiments was performed with cardiomyocytes incubated for 1 day in the absence of glucose and serum and under hypoxic conditions (pO2 < 1%), in order to simulate severe ischemia. The percentage of cardiac committed GFP+MSCs was about 5% when cultured with the hypoxic/starved cardiomyocytes and further increased to 7% after DFMO addition. The contemporary presence of putrescine in DFMO-treated cells markedly blunted differentiation, while the cytostatic mitomycin C was not able to induce cardiac commitment. The involvement of histone acetylation in DFMO-induced differentiation was evidenced by the strong attenuation of cardiac commitment exerted by anacardic acid, an inhibitor of histone acetylase. Moreover, the percentage of acetylated histone H3 significantly increased in bone marrow MSCs obtained from wild type rats and treated with DFMO. These results suggest that polyamine depletion can represent a useful strategy to improve MSC differentiation into the cardiac lineage, especially in the presence of cardiomyocytes damaged by an ischemic environment.     

Calcium phosphate surfaces promote osteogenic differentiation of mesenchymal stem cells

Although studies in vivo revealed promising results in bone regeneration after implantation of scaffolds together with osteogenic progenitor cells, basic questions remain how material surfaces control the biology of mesenchymal stem cells (MSC). We used human MSC derived from bone marrow and studied the osteogenic differentiation on calcium phosphate surfaces. In osteogenic differentiation medium MSC differentiated to osteoblasts on hydroxyapatite and BONITmatrix, a degradable xerogel composite, within 14 days. Cells revealed a higher alkaline phosphatase (ALP) activity and increased RNA expression of collagen I and osteocalcin using real-time RTPCR compared with cells on tissue culture plastic. To test whether material surface characteristics alone are able to stimulate osteogenic differentiation, MSC were cultured on the materials in expansion medium without soluble additives for osteogenic differentiation. Indeed, cells on calcium phosphate without osteogenic differentiation additives developed to osteoblasts as shown by increased ALP activity and expression of osteogenic genes, which was not the case on tissue culture plastic. Because we reasoned that the stimulating effect on osteogenesis by calcium phosphate surfaces depends on an altered cell-extracellular matrix interaction we studied the dynamic behaviour of focal adhesions using cells transfected with GFP labelled vinculin. On BONITmatrix, an increased mobility of focal adhesions was observed compared with cells on tissue culture plastic. In conclusion, calcium phosphate surfaces are able to drive MSC to osteoblasts in the absence of osteogenic differentiation supplements in the medium. An altered dynamic behaviour of focal adhesions on calcium phosphate surfaces might be involved in the molecular mechanisms which promote osteogenic differentiation.     

低氧对间充质干细胞成骨相关基因表达的影响

目的：观察低氧对间充质干细胞（MSC）成骨相关基因表达的影响。方法：取第2代MSC,分别在常氧和3％氧浓度下培养,采用real-timeRT-PCR检测骨桥蛋白（OPN）、核心结合因子α1（Cbfal）、骨形态发生蛋白（BMP）和血管内皮生长因子（VEGF）mRNA的表达。结果：2种氧浓度下MSC的形态无明显差异,但3％氧浓度下MSC集落形成能力增强。常氧下MSC中Cbfal和BMPmRNA的表达高于3％氧浓度,差异有显著性（P〈0．05）;而OPN和VEGFmRNA的表达虽高于3％氧浓度,但差异无显著性（P〉0．05）。结论：3％氧浓度对MSC的形态没有明显影响,但增强其增殖能力,抑制其成骨分化能力。     

Human mesenchymal stem cell spheroids in fibrin hydrogels exhibit improved cell survival and potential for bone healing

Mesenchymal stem cells (MSCs) have great therapeutic potential for the repair of nonhealing bone defects, because of their proliferative capacity, multilineage potential, trophic factor secretion and lack of immunogenicity. However, a major challenge to the translation of cell-based therapies into clinical practice is ensuring their survival and function upon implantation into the defect site. We hypothesize that forming MSCs into more physiologic three-dimensional spheroids, rather than employing dissociated cells from two-dimensional monolayer culture, will enhance their survival when exposed to a harsh microenvironment but maintain their osteogenic potential. MSC spheroids were formed by using the hanging drop method with increasing cell numbers. Compared with larger spheroids, the smallest spheroids, which contained 15,000 cells, exhibited increased metabolic activity, reduced apoptosis and the most uniform distribution of proliferating cells. Spheroids were then entrapped in fibrin gels and cultured in serum-free medium and 1 % oxygen. Compared with identical numbers of dissociated MSCs in fibrin gels, spheroids exhibited significantly reduced apoptosis and secreted up to 100-fold more vascular endothelial growth factor. Moreover, fibrin gels containing spheroids and those containing an equivalent number of dissociated cells exhibited similar expression levels of early and late markers of osteogenic differentiation. Thus, MSC spheroids exhibit greater resistance to apoptosis and enhanced proangiogenic potential while maintaining similar osteogenic potential to dissociated MSCs entrapped in a clinically relevant biomaterial, supporting the use of MSC spheroids in cell-based approaches to bone repair.     

3D mesenchymal stem/stromal cell osteogenesis and autocrine signalling

Mesenchymal stem/stromal cells (MSC) are rapidly becoming a leading candidate for use in tissue regeneration, with first generation of therapies being approved for use in orthopaedic repair applications. Capturing the full potential of MSC will likely require the development of novel in vitro culture techniques and devices. Herein we describe the development of a straightforward surface modification of an existing commercial product to enable the efficient study of three dimensional (3D) human bone marrow-derived MSC osteogenic differentiation. Hundreds of 3D microaggregates, of either 42 or 168 cells each, were cultured in osteogenic induction medium and their differentiation was compared with that occurring in traditional two dimensional (2D) monolayer cultures. Osteogenic gene expression and matrix composition was significantly enhanced in the 3D microaggregate cultures. Additionally, BMP-2 gene expression was significantly up-regulated in 3D cultures at day 3 and 7 by approximately 25- and 30-fold, respectively. The difference in BMP-2 gene expression between 2D and 3D cultures was negligible in the more mature day 14 osteogenic cultures. These data support the notion that BMP-2 autocrine signalling is up-regulated in 3D MSC cultures, enhancing osteogenic differentiation. This study provides both mechanistic insight into MSC differentiation, as well as a platform for the efficient generation of microtissue units for further investigation or use in tissue engineering applications.     

Phenotypical and functional properties of human bone marrow mesenchymal progenitor cells

Bone marrow stroma provides the microenvironment for hematopoiesis and is also the source of mesenchymal progenitors (mesenchymal or marrow stromal cells [MSC]) that may serve as long-lasting precursors for bone, cartilage, lung, and muscle. While several studies have indicated the differentiation potential of MSC, few studies have been performed on the cells themselves. In an attempt to further expand our knowledge on these cells, we have performed studies on their cell cycle, immuno- and adhesive-phenotype, ex vivo expansion, and differentiation properties. MSC cultures have been initiated from human bone marrow low-density mononuclear cells and maintained in the absence of differentiation stimuli and hematopoietic cells. The homogenous layer of adherent cells thus formed exhibits a typical fibroblastlike morphology, a population doubling time of 33 h, a large expansive potential, and cell cycle characteristics including a subset (20%) of quiescent cells. The antigenic phenotype of MSC is not unique, borrowing features of mesenchymal, endothelial, and epithelial cells. Together, MSC express several adhesion-related antigens, like the integrin subunits α4, α5, β1, integrins αvβ3 and αvβ5, ICAM-1, and CD44H. MSC produce and functionally adhere to extracellular matrix molecules. When incubated under proper stimuli, MSC differentiate into osteoblasts or adipocytes. Taken together, these results demonstrate that adherent marrow-derived cells cultured in the absence of hematopoietic cells and differentiation stimulus give rise to a population of cells with phenotypical and functional features of mesenchymal progenitors. The existence of a subset of quiescent cells in MSC cultures seems to be extremely significant, since their number and properties should be enough to sustain a steady supply of cells that upon proliferation and commitment may serve as precursors for a number of nonhematopoietic tissues. J. Cell. Physiol. 181:67–73, 1999. © 1999 Wiley-Liss, Inc.     

人脐带间充质干细胞的分离培养与鉴定简

目的：建立并优化人脐带间充质干细胞分离纯化方法,并对其表面标志与多向分化潜能进行鉴定。方法：收集健康足月产胎儿脐带组织,采用组织块贴壁法进行原代培养,流式细胞仪对其表面标志进行检测,通过向成骨成脂分化对其多向分化潜能进行鉴定,RT-PCR对其干细胞特性基因Oct4、Nanog、Sox2、Nestin进行检测。结果：采用组织块贴壁法可在2周左右获得大量间充质干细胞,培养的细胞经流式细胞仪检测,高表达CD29、CD44、CD105、CD106,低表达CD34、CD45;经成骨成脂诱导2周后可分化为成骨细胞和成脂细胞,RT-PCR检测发现原代细胞表达Oct4、Nanog、Sox2、Nestin基因。结论：人脐带间充质干细胞可在体外扩增培养,具有多向分化潜能,可作为组织工程种子细胞来源。     

Improved proliferation and differentiation capacity of human mesenchymal stromal cells cultured with basement-membrane extracellular matrix proteins

Background aimsIn vitro cultured mesenchymal stromal cells (MSC) are characterized by a short proliferative lifespan, an increasing loss of proliferation capacity and progressive reduction of differentiation potential. Laminin-1, laminin-5, collagen IV and fibronectin are important constituents of the basement membrane extracellular matrix (ECM) that are involved in a variety of cellular activities, including cell attachment and motility.Methods and resultsThe in vitro proliferation capacity of MSC was significantly improved when the cells were incubated in the presence of basement membrane ECM proteins. For example, a mixture of proteins improved proliferation capacity 250-fold in comparison with standard conditions after five passages. Furthermore, in colony-forming unit–fibroblast (CFU-F) assays colony numbers and size were significantly extended. Blocking specific integrin cell-surface receptors, positive effects on the proliferation capacity of MSC were inhibited. Additionally, when MSC were co-cultivated with ECM proteins, cells maintained their multipotential differentiation capacity throughout many culture passages in comparison with cells cultivated on plastic. However, expansion of MSC on laminin-5 suppressed any subsequent chondrogenic differentiation.ConclusionsOur results suggest that expansion of bone marrow-derived MSC in the presence of ECM proteins is a powerful approach for generating large numbers of MSC, showing a prolonged capacity to differentiate into mesodermal cell lineages, with the exception of the lack of chondrogenesis by using laminin-5 coating.     

Plasticity and banking potential of cultured adipose tissue derived mesenchymal stem cells

The present day research on stem cells is yet not filled to the gunwales. The correlation of stem cell technology with tissue repair still has a long way to go. Since Embryonic stem cells are a kind of thorn inside when it comes to therapeutics, there emerged few potent contemporary sources of stem cells. Though bone marrow proves to be the pioneer among these, they lose themselves to adipose tissue in various aspects. The major shortcoming of bone marrow lies in lieu of its loss in potency with age. Adipose tissue puts up a tough competition among leading edge stem cell sources like cord blood and cord matrix. Adipose tissue wins over its counterparts in that it possesses astounding proliferation potency in vitro and holds a prominent stand in showcasing in vivo tissue repair efficacy. In spite of its precedence, the whole enchilada of adipose derived stem cells is still in its salad days. In our work we aim at excogitating the Mesenchymal stem cell population present in cultured adipose derived stem cells, in a wide perspective. Furthermore, the coalition of cell adhesion molecules with the proliferation potency of MSC and analysis of growth curve of ADSC was also paid accolade. The presence of robust MSC with immense differentiation and transdifferentiation potency was endorsed by lucrative differentiation of P3 cells into mesodermal and neuronal lineages. Additionally, mesenchymal stem cells exhibiting coherent expression of surface markers at P3 in all samples can be cryopreserved for therapeutic applications.     

Calcification or dedifferentiation: Requirement to lock mesenchymal stem cells in a desired differentiation stage

A current challenge in mesenchymal stem cell (MSC)‐based cartilage repair is to solve donor and tissue‐dependent variability of MSC cultures and to prevent chondrogenic cells from terminal differentiation like in the growth plate. The aim of this study was to select the best source for MSC which could promise stable cartilage formation in the absence of hypertrophy and ectopic in vivo mineralization. We hypothesized that MSC from synovium are superior to bone marrow‐ and adipose tissue‐derived MSC since they are derived from a joint tissue. MSC were characterized by flow cytometry. MSC pellets were cultured under chondrogenic conditions and differentiation was evaluated by histology, gene expression analysis, and determination of alkaline phosphatase activity (ALP). After chondrogenic induction, pellets were transplanted subcutaneously into SCID mice. MSC from bone marrow, adipose tissue, and synovium revealed similar COL2A1/COL10A1 mRNA levels after chondrogenic induction and were positive for collagen‐type‐X. Bone marrow‐derived and adipose tissue‐derived MSC showed significantly higher ALP activity than MSC from synovium. Low ALP‐activity before transplantation of pellets correlated with marginal calcification of explants. Surprisingly, non‐mineralizing transplants specifically lost their collagen‐type II, but not collagen‐type I deposition in vivo, or were fully degraded. In conclusion, the lower donor‐dependent ALP activation and reduced mineralization of synovium‐derived heterotopic transplants did not lead to stable ectopic cartilage as known from articular chondrocytes, but correlated with fibrous dedifferentation or complete degeneration of MSC pellets. This emphasizes that beside appropriate induction of differentiation, locking of MSC in the desired differentiation state is a major challenge for MSC‐based repair strategies. J. Cell. Physiol. 219: 219–226, 2009. © 2008 Wiley‐Liss, Inc.     

Effects of In Vitro Low Oxygen Tension Preconditioning of Adipose Stromal Cells on Their In Vivo Chondrogenic Potential: Application in Cartilage Tissue Repair

Purpose

Multipotent stromal cell (MSC)-based regenerative strategy has shown promise for the repair of cartilage, an avascular tissue in which cells experience hypoxia. Hypoxia is known to promote the early chondrogenic differentiation of MSC. The aim of our study was therefore to determine whether low oxygen tension could be used to enhance the regenerative potential of MSC for cartilage repair.

Methods

MSC from rabbit or human adipose stromal cells (ASC) were preconditioned in vitro in control or chondrogenic (ITS and TGF-β) medium and in 21 or 5% O₂. Chondrogenic commitment was monitored by measuring COL2A1 and ACAN expression (real-time PCR). Preconditioned rabbit and human ASC were then incorporated into an Si-HPMC hydrogel and injected (i) into rabbit articular cartilage defects for 18 weeks or (ii) subcutaneously into nude mice for five weeks. The newly formed tissue was qualitatively and quantitatively evaluated by cartilage-specific immunohistological staining and scoring. The phenotype of ASC cultured in a monolayer or within Si-HPMC in control or chondrogenic medium and in 21 or 5% O₂ was finally evaluated using real-time PCR.

Results/Conclusions

5% O₂ increased the in vitro expression of chondrogenic markers in ASC cultured in induction medium. Cells implanted within Si-HPMC hydrogel and preconditioned in chondrogenic medium formed a cartilaginous tissue, regardless of the level of oxygen. In addition, the 3D in vitro culture of ASC within Si-HPMC hydrogel was found to reinforce the pro-chondrogenic effects of the induction medium and 5% O₂. These data together indicate that although 5% O₂ enhances the in vitro chondrogenic differentiation of ASC, it does not enhance their in vivo chondrogenesis. These results also highlight the in vivo chondrogenic potential of ASC and their potential value in cartilage repair.     

In vitro and in vivo effects of rat kidney vascular endothelial cells on osteogenesis of rat bone marrow mesenchymal stem cells growing on polylactide-glycoli acid (PLGA) scaffolds

It is well established that vascularization is critical for osteogenesis. However, adequate vascularization also remains one of the major challenges in tissue engineering of bone. This problem is further accentuated in regeneration of large volume of tissue. Although a complex process, vascularization involves reciprocal regulation and functional interaction between endothelial and osteoblast-like cells during osteogenesis. This prompted us to investigate the possibility of producing bone tissue both in vitro and ectopically in vivo using vascular endothelial cells because we hypothesized that the direct contact or interaction between vascular endothelial cells and bone marrow mesenchymal stem cells are of benefit to osteogenesis in vitro and in vivo. For that purpose we co-cultured rat bone marrow mesenchymal stem cells (MSC) and kidney vascular endothelial cells (VEC) with polylactide-glycolic acid scaffolds. In vitro experiments using alkaline phosphatase and osteocalcin assays demonstrated the proliferation and differentiation of MSC into osteoblast-like cells, especially the direct contact between VEC and MSC. In addition, histochemical analysis with CD31 and von-Willebrand factor staining showed that VEC retained their endothelial characteristics. In vivo implantation of MSC and VEC co-cultures into rat's muscle resulted in pre-vascular network-like structure established by the VEC in the PLGA. These structures developed into vascularized tissue, and increased the amount and size of the new bone compared to the control group (p < 0.05). These results suggest that the vascular endothelial cells could efficiently stimulate the in vitro proliferation and differentiation of osteoblast-like cells and promote osteogenesis in vivo by the direct contact or interaction with the MSC. This technique for optimal regeneration of bone should be further investigated.     

A thermosensitive hydrogel capable of releasing bFGF for enhanced differentiation of mesenchymal stem cell into cardiomyocyte-like cells under ischemic conditions

A thermosensitive hydrogel capable of differentiating mesenchymal stem cells (MSCs) into cardiomyocyte-like cells was synthesized. The hydrogel was based on N-isopropylacrylamide (NIPAAm), N-acryloxysuccinimide, acrylic acid, and hydroxyethyl methacrylate-poly(trimethylene carbonate). The hydrogel was highly flexible at body temperature with breaking strain >1000% and Young's modulus 45 kPa. When MSCs were encapsulated in the hydrogel and cultured under normal culture conditions (10% FBS and 21% O(2)), the cells differentiated into cardiomyocyte-like cells. However, the differentiation was retarded, and even diminished, under low nutrient and low oxygen conditions, which are typical of the infarcted heart. We hypothesized that enhancing MSC survival under low nutrient and low oxygen conditions would restore the differentiation. To enhance cell survival, a pro-survival growth factor (bFGF) was loaded in the hydrogel. bFGF was able to sustainedly release from the hydrogel for 21 days. Under the low nutrient and low oxygen conditions (1% O(2) and 1% FBS), bFGF enhanced MSC survival and differentiation in the hydrogel. After 14 days of culture, survival of 70.5% of MSCs remained in the bFGF-loaded hydrogel, while only 4.9% of MSCs remained in the hydrogel without bFGF. The differentiation toward cardiomyocyte-like cells was completely inhibited at 1% FBS and 1% oxygen. Loading bFGF in the hydrogel restored the differentiation, as confirmed by the expression of cardiac markers at both the gene (MEF2C and CACNA1c) and protein (cTnI and connexin 43) levels. bFGF loading also up-regulated the paracrine effect of MSCs. VEGF expression was significantly increased in the bFGF-loaded hydrogel. These results demonstrate that the developed bFGF-loaded hydrogel may potentially be used to deliver MSCs into hearts for regeneration of heart tissue.     

Good manufacturing practice-compliant animal-free expansion of human bone marrow derived mesenchymal stroma cells in a closed hollow-fiber-based bioreactor

Mesenchymal stroma cells (MSC) are increasingly recognized for various applications of cell-based therapies such as regenerative medicine or immunomodulatory treatment strategies. Standardized large-scale expansions of MSC under good manufacturing practice (GMP)-compliant conditions avoiding animal derived components are mandatory for further evaluation of these novel therapeutic approaches in clinical trials.We applied a novel automated hollow fiber cell expansion system (CES) for in vitro expansion of human bone marrow derived MSC employing a GMP-compliant culture medium with human platelet lysate (HPL). Between 8 and 32 ml primary bone marrow aspirate were loaded into the hollow fiber CES and cultured for 15–27 days. 2–58 million MSC were harvested after primary culture. Further GMP-compliant cultivation of second passage MSC for 13 days led to further 10–20-fold enrichment. Viability, surface antigen expression, differentiation capacity and immunosuppressive function of MSC cultured in the hollow fiber CES were in line with standard criteria for MSC definition. We conclude that MSC can be enriched from primary bone marrow aspirate in a GMP-conform manner within a closed hollow fiber bioreactor and maintain their T lymphocyte inhibitory capacity. Standardized and reliable conditions for large scale MSC expansion pave the way for safe applications in humans in different therapeutic approaches.