In vitro and in vivo co‐culture of chondrocytes and bone marrow stem cells in photocrosslinked PCL–PEG–PCL hydrogels enhances cartilage formation

Chondrocytes (CH) and bone marrow stem cells (BMSCs) are sources that can be used in cartilage tissue engineering. Co‐culture of CHs and BMSCs is a promising strategy for promoting chondrogenic differentiation. In this study, articular CHs and BMSCs were encapsulated in PCL–PEG–PCL photocrosslinked hydrogels for 4 weeks. Various ratios of CH:BMSC co‐cultures were investigated to identify the optimal ratio for cartilage formation. The results thus obtained revealed that co‐culturing CHs and BMSCs in hydrogels provides an appropriate in vitro microenvironment for chondrogenic differentiation and cartilage matrix production. Co‐culture with a 1:4 CH:BMSC ratio significantly increased the synthesis of GAGs and collagen. In vivo cartilage regeneration was evaluated using a co‐culture system in rabbit models. The co‐culture system exhibited a hyaline chondrocyte phenotype with excellent regeneration, resembling the morphology of native cartilage. This finding suggests that the co‐culture of these two cell types promotes cartilage regeneration and that the system, including the hydrogel scaffold, has potential in cartilage tissue engineering. Copyright © 2013 John Wiley & Sons, Ltd.     

Enhanced recruitment and hematopoietic reconstitution of bone marrow‐derived mesenchymal stem cells in bone marrow failure by the SDF‐1/CXCR4

Aplastic anemia (AA) is a bone marrow failure disease. It is difficult to treat AA, and in addition, relapses are common because of its complex disease pathogenesis. Allogeneic bone marrow‐derived mesenchymal stem cells (BMSCs) infusion is an effective and safe treatment option for the AA patients. However, it found that BMSCs infusion in AA patients is less than 30% effective. Therefore, the key to improve the efficacy of BMSCs treatment in these patients is to enhance their homing efficiency to the target sites. Studies have shown that stromal cell‐derived factor‐1 (SDF‐1)/CXC chemokine receptor 4 (CXCR4) axis plays an important role in promoting BMSCs homing. In this study, human BMSCs were transduced with lentivirus stably expressing CXCR4‐BMSCs. Transduced BMSCs resemble normal BMSCs in many ways. Migration ability of CXCR4‐BMSCs toward SDF‐1 was increased because of the overexpression of CXCR4. In the mice with bone marrow failure, the migration and colonization ability of CXCR4‐BMSCs to the bone marrow was significantly improved as seen by IVIS imaging and FACS. The SDF‐1 level in the bone marrow failure mice was significantly higher than in the normal mice. Thus, from our study, it is clear that after CXCR4‐BMSCs were infused into mice with bone marrow failure, SDF‐1 interacted with CXCR4 receptor, leading cells to migrate and colonize to bone marrow. Because of the high SDF‐1 expression in mouse bone marrow and CXCR4 receptor expression in cells, BMSCs homing was increased.     

A doxycycline inducible,adenoviral bone morphogenetic protein‐2 gene delivery system to bone

We report the novel use of a tuneable, non‐integrating viral gene delivery system to bone that can be combined with clinically approved biomaterials in an 'off‐the‐shelf' manner. Specifically, a doxycycline inducible Tet‐on adenoviral vector (AdTetBMP‐2) in combination with mesenchymal stromal cells (MSCs), fibrin and a biphasic calcium phosphate ceramic (MBCP®) was used to repair large bone defects in nude rats. Bone morphogenetic protein‐2 (BMP‐2) transgene expression could be effectively tuned by modification of the doxycycline concentration. The effect of adenoviral BMP‐2 gene delivery upon bone healing was investigated in vivo in 4 mm critically sized, internally fixated, femoral defects. MSCs were transduced either by direct application of AdTetBMP‐2 or by pre‐coating MBCP granules with the virus. Radiological assessment scores post‐mortem were significantly improved upon delivery of AdTetBMP‐2. In AdTetBMP‐2 groups, histological analysis revealed significantly more newly formed bone at the defect site compared with controls. Newly formed bone was vascularized and fully integrated with nascent tissue and implanted biomaterial. Improvement in healing outcome was achieved using both methods of vector delivery (direct application vs. pre‐coating MCBP). Adenoviral delivery of BMP‐2 enhanced bone regeneration achieved by the transplantation of MSCs, fibrin and MBCP in vivo. Importantly, our in vitro and in vivo data suggest that this can be achieved with relatively low (ng/ml) levels of the growth factor. Our model and novel gene delivery system may provide a powerful standardized tool for the optimization of growth factor delivery and release for the healing of large bone defects. Copyright © 2016 John Wiley & Sons, Ltd.     

Oxy133, a novel osteogenic agent,promotes bone regeneration in an intramembranous bone‐healing model

Current reconstructive techniques for complex craniofacial osseous defects are challenging and are associated with significant morbidity. Oxysterols are naturally occurring cholesterol oxidation products with osteogenic potential. In this study, we investigated the effects of a novel semi‐synthetic oxysterol, Oxy133, on in vitro osteogenesis and an in vivo intramembranous bone‐healing model. Rabbit bone marrow stromal cells (BMSCs) were treated with either Oxy133 or BMP‐2. Alkaline phosphatase (ALP) activity, expression of osteogenic gene markers and in vitro mineralization were all examined. Next, collagen sponges carrying either Oxy133 or BMP‐2 were used to reconstruct critical‐sized cranial defects in mature rabbits and bone regeneration was assessed. To determine the mechanism of action of Oxy133 both in vitro and in vivo, rabbit BMSCs cultures and collagen sponge/Oxy133 implants were treated with the Hedgehog signalling pathway inhibitor, cyclopamine, and similar outcomes were measured. ALP activity in rabbit BMSCs treated with 1 μm Oxy133 was induced and was significantly higher than in control cells. These results were mitigated in cultures treated with cyclopamine. Expression of osteogenic gene markers and mineralization in BMSCs treated with 1 μm Oxy133 was significantly higher than in control groups. Complete bone regeneration was noted in vivo when cranial defects were treated with Oxy133; healing was incomplete, however, when cyclopamine was added. Collectively, these results demonstrate that Oxy133 has the ability to induce osteogenic differentiation in vitro in rabbit BMSCs and to promote robust bone regeneration in vivo in an animal model of intramembranous bone healing. Copyright © 2015 John Wiley & Sons, Ltd.     

Bone regeneration in minipigs via calcium phosphate cement scaffold delivering autologous bone marrow mesenchymal stem cells and platelet‐rich plasma

Macroporous calcium phosphate cement (CPC) with stem cell seeding is promising for bone regeneration. The objective of this study was to investigate the effects of co‐delivering autologous bone marrow mesenchymal stem cells (BMSCs) and autologous platelet‐rich plasma (PRP) in CPC scaffold for bone regeneration in minipigs for the first time. Twelve female adult Tibet minipigs (12–18 months old) were used. A cylindrical defect with 10 mm height and 8 mm diameter was prepared at the femoral condyle. Two bone defects were created in each minipig, one at each side of the femoral condyle. Three constructs were tested: (1) CPC scaffold (CPC control); (2) CPC seeded with BMSCs (CPC‐BMSC); (3) CPC seeded with BMSCs and PRP (CPC‐BMSC‐PRP). Two time points were tested: 6 and 12 weeks (n = 4). Good integration of implant with surrounding tissues was observed in all groups. At 12 weeks, the CPC‐BMSC‐PRP group had significantly less residual CPC remaining in the defect than the CPC‐BMSC group and the CPC control (p < 0.05). The residual CPC volume for the CPC‐BMSC‐PRP group was half that of the CPC control. New bone formation for CPC‐BMSC‐PRP was more than two‐fold that of the CPC control (p < 0.05). CPC‐BMSC‐PRP had new blood vessel density that was nearly two‐fold that of the CPC control (p < 0.05). In conclusion, CPC scaffold with autologous BMSC‐PRP doubled the new bone regeneration and blood vessel density in minipigs compared with the CPC control. In the present study, the new macroporous CPC system with co‐delivered BMSC‐PRP has been shown to promote scaffold resorption and bone regeneration in large defects. Copyright © 2017 John Wiley & Sons, Ltd.     

BMP‐2‐transduced human bone marrow stem cells enhance neo‐bone formation in a rat critical‐sized femur defect

Synthetic graft materials are considered as possible substitutes for cancellous bone, but lack osteogenic and osteoinductive properties. In this study, we investigated how composite scaffolds of βTCP containing osteogenic human bone marrow mesenchymal stem cells (hBMSCs) and osteoinductive bone morphogenetic protein‐2 (BMP‐2) influenced the process of fracture healing. hBMSCs were loaded into βTCP scaffolds 24 h before implantation in a rat critical‐sized bone defect. hBMSCs were either stimulated with rhBMP‐2 or transduced with BMP‐2 by gene transfer. The effect of both protein stimulation and gene transfer was compared for osteogenic outcome. X‐rays were conducted at weeks 0, 1, 3, 6, 9 and 12 post‐operatively. In addition, bone‐labelling fluorochromes were applied at 0, 3, 6 and 9 weeks. Histological analysis was performed for the amount of callus tissue and cartilage formation. At 6 weeks, the critical‐sized defect in 33% of the rats treated with the Ad‐BMP‐2‐transduced hBMSCs/βTCP scaffolds was radiographically bridged. In contrast, in only 10% of the rats treated with rhBMP2/hBMSCs, 12 weeks post‐treatment, the bone defect was closed in all treated rats of the Ad‐BMP‐2 group except for one. Histology showed significantly higher amounts of callus formation in both Ad‐BMP‐2‐ and rhBMP‐2‐treated rats. The amount of neocartilage was less pronounced in both BMP‐2‐related groups. In summary, scaffolds with BMP‐2‐transduced hBMSCs performed better than those with the rhBMP2/hBMSCs protein. These results suggest that combinations of osteoconductive biomaterials with genetically modified MSCs capable of secreting osteoinductive proteins may represent a promising alternative for bone regeneration. Copyright © 2015 John Wiley & Sons, Ltd.     

Molecular‐ and microarray‐based analysis of diversity among resting and osteogenically induced porcine mesenchymal stromal cells of several tissue origin

Mesenchymal stromal cells (MSCs) play a pivotal role in modern therapeutic approaches in bone‐healing disorders. Although bone marrow‐derived MSCs are most frequently used, the knowledge that many other adult tissues represent promising sources for potent MSCs has gained acceptance. In the present study, the osteogenic differentiation potential of porcine skin fibroblasts (FBs), as well as bone marrow‐ (BMSCs), adipose tissue‐ (ASCs) and dental pulp‐derived stromal cells (DSCs) were evaluated. However, additional application of BMP‐2 significantly elevated the delayed osteogenic differentiation capacity of ASC and FB cultures, and in DSC cultures the supplementation of platelet‐rich plasma increased osteogenic differentiation potential to a comparable level of the good differentiable BMSCs. Furthermore, microarray gene expression performed in an exemplary manner for ASCs and BMSCs revealed that ASCs and BMSCs use different gene expression patterns for osteogenic differentiation under standard media conditions, as diverse MSCs are imprinted dependent from their tissue niche. However, after increasing the differentiation potential of ASCs to a comparable level as shown in BMSCs, a small subset of identical key molecules was used to differentiate in the osteogenic lineage. Until now, the importance of identified genes seems to be underestimated for osteogenic differentiation. Apparently, the regulation of transmembrane protein 229A, interleukin‐33 and the fibroblast growth factor receptor‐2 in the early phase of osteogenic differentiation is needed for optimum results. Based on these results, bone regeneration strategies of MSCs have to be adjusted, and in vivo studies on the osteogenic capacities of the different types of MCSs are warranted. Copyright © 2016 The Authors Tissue Engineering and Regenerative Medicine published by John Wiley & Sons, Ltd.     

Micro‐aggregates do not influence bone marrow stromal cell chondrogenesis

Although bone marrow stromal cells (BMSCs) appear promising for cartilage repair, current clinical results are suboptimal and the success of BMSC‐based therapies relies on a number of methodological improvements, among which is better understanding and control of their differentiation pathways. We investigated here the role of the cellular environment (paracrine vs juxtacrine signalling) in the chondrogenic differentiation of BMSCs. Bovine BMSCs were encapsulated in alginate beads, as dispersed cells or as small micro‐aggregates, to create different paracrine and juxtacrine signalling conditions. BMSCs were then cultured for 21 days with TGFβ₃ added for 0, 7 or 21 days. Chondrogenic differentiation was assessed at the gene (type II and X collagens, aggrecan, TGFβ, sp7) and matrix (biochemical assays and histology) levels. The results showed that micro‐aggregates had no beneficial effects over dispersed cells: matrix production was similar, whereas chondrogenic marker gene expression was lower for the micro‐aggregates, under all TGFβ conditions tested. This weakened chondrogenic differentiation might be explained by a different cytoskeleton organization at day 0 in the micro‐aggregates. Copyright © 2014 John Wiley & Sons, Ltd.     

Matrix formation is enhanced in co‐cultures of human meniscus cells with bone marrow stromal cells

The ultimate aim of this study was to assess the feasibility of using human bone marrow stromal cells (BMSCs) to supplement meniscus cells for meniscus tissue engineering and regeneration. Human menisci were harvested from three patients undergoing total knee replacements. Meniscus cells were released from the menisci after collagenase treatment. BMSCs were harvested from the iliac crest of three patients and were expanded in culture until passage 2. Primary meniscus cells and BMSCs were co‐cultured in vitro in three‐dimensional (3D) pellet culture at three different cell–cell ratios for 3 weeks under normal (21% O₂) or low (3% O₂) oxygen tension in the presence of serum‐free chondrogenic medium. Pure BMSCs and pure meniscus cell pellets served as control groups. The tissue generated was assessed biochemically, histochemically and by quantitative RT–PCR. Co‐cultures of primary meniscus cells and BMSCs resulted in tissue with increased (1.3–1.7‐fold) deposition of proteoglycan (GAG) extracellular matrix (ECM) relative to tissues derived from BMSCs or meniscus cells alone under 21% O₂. GAG matrix formation was also enhanced (1.3–1.6‐fold) under 3% O₂ culture conditions. Alcian blue staining of generated tissue confirmed increased deposition of GAG‐rich matrix. mRNA expression of type I collagen (COL1A2), type II collagen (COL2A1) and aggrecan were upregulated in co‐cultured pellets. However, SOX9 and HIF‐1α mRNA expression were not significantly modulated by co‐culture. Co‐culture of primary meniscus cells with BMSCs resulted in increased ECM formation. Co‐delivery of meniscus cells and BMSCs can, in principle, be used in tissue engineering and regenerative medicine strategies to repair meniscus defects. Copyright © 2012 John Wiley & Sons, Ltd.     

Repair of an osteochondral defect by sustained delivery of BMP‐2 or TGFβ1 from a bilayered alginate–PLGA scaffold

Regeneration of cartilage defects can be accelerated by localized delivery of appropriate growth factors (GFs) from scaffolds. In the present study we analysed the in vitro and in vivo release rates and delivery efficacies of transforming growth factor‐β1 (TGFβ1) and bone morphogenetic protein‐2 (BMP‐2) from a bilayered system, applied for osteochondral defect repair in a rabbit model. A bone‐orientated, porous PLGA cylinder was overlaid with GF containing PLGA microspheres, dispersed in an alginate matrix. Four microsphere formulations were incorporated: (a) blank ones; (b) microspheres containing 50 ng TGFβ1; (c) microspheres containing 2.5 µg BMP‐2; and (d) microspheres containing 5 µg BMP‐2. Release kinetics and tissue distributions were determined using iodinated (¹²⁵I) GFs. Bioactivity of in vitro released BMP‐2 and TGFβ1 was confirmed in cell‐based assays. In vivo release profiles indicated good GF release control. 20% of BMP‐2 and 15% of TGFβ1 were released during the first day. Virtually the total dose was delivered at the end of week 6. Significant histological differences were observed between untreated and GF‐treated specimens, there being especially relevant short‐term outcomes with 50 ng TGFβ1 and 5 µg BMP‐2. Although the evaluation scores for the newly formed cartilage did not differ significantly, 5 µg BMP‐2 gave rise to higher quality cartilage with improved surface regularity, tissue integration and increased collagen‐type II and aggrecan immunoreactivity 2 weeks post‐implantation. Hence, the bilayered system controlled GF release rates and led to preserved cartilage integrity from 12 weeks up to at least 24 weeks. Copyright © 2012 John Wiley & Sons, Ltd.     

Expression of platelet‐bound stromal cell‐derived factor‐1 in patients with non‐valvular atrial fibrillation and ischemic heart disease

Summary. Aims: Blood cell infiltration and inflammation are involved in atrial remodelling during atrial fibrillation (AF) although the exact mechanisms of inflammatory cell recruitment remain poorly understood. Platelet‐bound stromal cell‐derived factor‐1 (SDF‐1) is increased in cases of ischemic myocardium and regulates recruitment of CXCR4⁺ cells on the vascular wall. Whether platelet‐bound SDF‐1 expression is differentially influenced by non‐valvular paroxysmal or permanent atrial fibrillation (AF) in patients with stable angina pectoris (SAP) or acute coronary syndrome (ACS) has not been reported so far. Methods and results: A total of 1291 consecutive patients with coronary artery disease (CAD) undergoing coronary angiography were recruited. Among the patients with SAP, platelet‐bound‐SDF‐1 is increased in patients with paroxysmal AF compared with SR or to persistent/permanent AF (P < 0.05 for both). Platelet‐bound SDF‐1 correlated with plasma SDF‐1 (r = 0.488, P = 0.013) in patients with AF and ACS, which was more pronounced among patients with persistent AF (r = 0.842, P = 0.009). Plasma SDF‐1 was increased in persistent/permanent AF compared with SR. Patients with ACS presented with enhanced platelet‐bound‐SDF‐1 compared with SAP. Interestingly, among patients with ACS, patients with paroxysmal or persistent/permanent AF presented with an impaired platelet‐bound SDF‐1 expression compared with patients with SR. Conclusions: Differential expression of platelet‐bound and plasma SDF‐1 was observed in patients with AF compared with SR which may be involved in progenitor cell mobilization and inflammatory cell recruitment in patients with AF and ischemic heart disease. Further in vivo studies are required to elucidate the role of SDF‐1 in atrial remodeling and the atrial fibrillation course.     

Comparing the osteogenic potential of bone marrow and tendon‐derived stromal cells to repair a critical‐sized defect in the rat femur

Despite significant advancements in bone tissue‐engineering applications, the clinical impact of bone marrow stromal cells (BMSCs) for the treatment of large osseous defects remains limited. Therefore, other cell sources are under investigation for their osteogenic potential to repair bone. In this study, tendon‐derived stromal cells (TDSCs) were evaluated in comparison to BMSCs to support the functional repair of a 5 mm critical‐sized, segmental defect in the rat femur. Analysis of the trilineage differentiation capacity of TDSCs and BMSCs cultured on collagen sponges revealed impaired osteogenic differentiation and mineral deposition of TDSCs in vitro, whereas chondrogenic and adipogenic differentiation was evident for both cell types. Radiographic assessment demonstrated that neither cell type significantly improved the healing rate of a challenging 5 mm segmental femoral defect. Transplanted TDSCs and BMSCs both led to the formation of only small amounts of bone in the defect area, and histological evaluation revealed non‐mineralized, collagen‐rich scar tissue to be present within the defect area. Newly formed lamellar bone was restricted to the defect margins, resulting in closure of the medullary cavity. Interestingly, in comparison to BMSCs, significantly more TDSC‐derived cells were present at the osteotomy gap up to 8 weeks after transplantation and were also found to be located within newly formed lamellar bone, suggesting their capacity to directly contribute to de novo bone formation. To our knowledge, this is the first study investigating the in vivo capacity of TDSCs to regenerate a critical‐sized defect in the rat femur. Copyright © 2015 John Wiley & Sons, Ltd.     

Vascular endothelial growth factor‐transfected adipose‐derived stromal cells enhance bone regeneration and neovascularization from bone marrow stromal cells

Vascular endothelial growth factor (VEGF)‐transfected adipose‐derived stromal cells (ADSCs^VEGF) were devised to promote bone regeneration and neovascularization of bone marrow stromal cells (BMSCs). ADSCs^VEGF were added to BMSCs and cocultured in variable proportions. ADSCs^VEGF alone or ADSCs^VEGF with BMSCs (BMSCs:ADSCs^VEGF ratio of 1:0.025–0.5) induced significantly greater tube formation in human umbilical vein endothelial cells than untransfected ADSCs. The cocultures of BMSCs and ADSCs^VEGF at ratios of 1: 0.025–0.1 showed significantly greater osteogenic differentiation and mineralization than BMSCs alone in vitro. Osteogenic markers COL1A1, OCN and BSP were most effectively induced at the BMSC: ADSC^VEGF ratio of 1:0.05. Of angiogenesis‐related genes, upregulation of cathepsin Z and downregulation of early growth response 1 were observed while two osteogenesis‐related genes, osteoactivin and tetranectin, were upregulated in BMSCs/ADSCs^VEGF compared to BMSCs/ADSCs. When critical size calvarial defects in rats were implanted with mixture of BMSCs and ADSCs^VEGF along with hydroxyapatite/β‐tricalcium phosphate granules, BMSCs and ADSCs^VEGF at the ratio of 1:0.05 showed better bone regeneration that BMSCs alone. The cotransplantation of ADSCs^VEGF with BMSCs significantly increased neovascularization on the regenerated bone of the repaired defect than BMSCs alone. In conclusion, ADSCs^VEGF added in small proportion to BMSCs effectively promote bone regeneration and neovascularization. Copyright © 2017 John Wiley & Sons, Ltd.     

In vitro generation of a multilayered osteochondral construct with an osteochondral interface using rabbit bone marrow stromal cells and a silk peptide‐based scaffold

Tissue engineering of a biological osteochondral multilayered construct with a cartilage‐interface subchondral bone layer is a key challenge. This study presented a rabbit bone marrow stromal cell (BMSC)/silk fibroin scaffold‐based co‐culture approach to generate tissue‐engineered osteochondral grafts with an interface. BMSC‐seeded scaffolds were first cultured separately in osteogenic and chondrogenic stimulation media. The two differentiated pieces were then combined using an RADA self‐assembling peptide and subsequently co‐cultured. Gene expression, histological and biochemical analyses were used to evaluate the multilayered structure of the osteochondral graft. A complete osteochondral construct with a cartilage‐subchondral bone interface was regenerated and BMSCs were used as the only cell source for the osteochondral construct and interface regeneration. Furthermore, in the intermediate region of co‐cultured samples, hypertrophic chondrogenic gene markers type X collagen and MMP‐13 were found on both chondrogenic and osteogenic section edges after co‐culture. However, significant differences gene expression profile were found in distinct zones of the construct during co‐culture and the section in the intermediate region had significantly higher hypertrophic chondrocyte gene expression. Biochemical analyses and histology results further supported this observation. This study showed that specific stimulation from osteogenic and chondrogenic BMSCs affected each other in this co‐culture system and induced the formation of an osteochondral interface. Moreover, this system provided a possible approach for generating multilayered osteochondral constructs. Copyright © 2013 John Wiley & Sons, Ltd.     

Load‐induced osteogenic differentiation of mesenchymal stromal cells is caused by mechano‐regulated autocrine signaling

Mechanical boundary conditions critically influence the bone healing process. In this context, previous in vitro studies have demonstrated that cyclic mechanical compression alters migration and triggers osteogenesis of mesenchymal stromal cells (MSC), both processes being relevant to healing. However, it remains unclear whether this mechanosensitivity is a direct consequence of cyclic compression, an indirect effect of altered supply or a specific modulation of autocrine bone morphogenetic protein (BMP) signaling. Here, we investigate the influence of cyclic mechanical compression (ε = 5% and 10%, f = 1 Hz) on human bone marrow MSC (hBMSC) migration and osteogenic differentiation in a 3D biomaterial scaffold, an in vitro system mimicking the mechanical environment of the early bone healing phase. The open‐porous architecture of the scaffold ensured sufficient supply even without cyclic compression, minimizing load‐associated supply alterations. Furthermore, a large culture medium volume in relation to the cell number diminished autocrine signaling. Migration of hBMSCs was significantly downregulated under cyclic compression. Surprisingly, a decrease in migration was not associated with increased osteogenic differentiation of hBMSCs, as the expression of RUNX2 and osteocalcin decreased. In contrast, BMP2 expression was significantly upregulated. Enabling autocrine stimulation by increasing the cell‐to‐medium ratio in the bioreactor finally resulted in a significant upregulation of RUNX2 in response to cyclic compression, which could be reversed by rhNoggin treatment. The results indicate that osteogenesis is promoted by cyclic compression when cells condition their environment with BMP. Our findings highlight the importance of mutual interactions between mechanical forces and BMP signaling in controlling osteogenic differentiation.     

In vitro generation of whole osteochondral constructs using rabbit bone marrow stromal cells,employing a two‐chambered co‐culture well design

The regeneration of whole osteochondral constructs with a physiological structure has been a significant issue, both clinically and academically. In this study, we present a method using rabbit bone marrow stromal cells (BMSCs) cultured on a silk–RADA peptide scaffold in a specially designed two‐chambered co‐culture well for the generation of multilayered osteochondral constructs in vitro. This specially designed two‐chambered well can simultaneously provide osteogenic and chondrogenic stimulation to cells located in different regions of the scaffold. We demonstrated that this co‐culture approach could successfully provide specific chemical stimulation to BMSCs located on different layers within a single scaffold, resulting in the formation of multilayered osteochondral constructs containing cartilage‐like and subchondral bone‐like tissue, as well as the intermediate osteochondral interface. The cells in the intermediate region were found to be hypertrophic chondrocytes, embedded in a calcified extracellular matrix containing glycosaminoglycans and collagen types I, II and X. In conclusion, this study provides a single‐step approach that highlights the feasibility of rabbit BMSCs as a single‐cell source for multilayered osteochondral construct generation in vitro. Copyright © 2013 John Wiley & Sons, Ltd.     

Rat bone marrow stromal cells‐seeded porous gelatin/tricalcium phosphate/oligomeric proanthocyanidins composite scaffold for bone repair

Repair of bone defects remains a major challenge in orthopaedic surgery. Bone tissue engineering is an attractive approach for treating bone loss in various shapes and amounts. The aim of this study was to prepare and evaluate the feasibility of a porous scaffold, which was composed of oligomeric proanthocyanidin crosslinked gelatin mixed with β‐tricalcium phosphate (GTP) and was seeded with bone marrow stromal cells (BMSCs) as a bone substitute. GTP scaffolds were made porous using a salt‐leaching method. The physicochemical properties of the scaffold were evaluated to determine the optimal salt:composite weight ratio. The results indicated that the GTP scaffold had a favourable macroporous structure and higher porosity when the salt:composite weight ratio was 4:1. Cytotoxic tests demonstrated that extracts from the GTP scaffolds promoted the proliferation of BMSCs. Rat BMSCs were seeded on a GTP scaffold and cultured in a spinner flask. After 2 weeks of culture, scanning electron microscopy observation showed that the cells adhered well to the surfaces of the pores in the scaffold. Moreover, this study explored the biological response of rat calvarial bone to the scaffold to evaluate its potential in bone tissue engineering. Bone defects were filled with BMSC‐seeded GTP scaffold and acellular GTP scaffold. After 8 weeks, the scaffold induced new bone formation at a bone defect, as was confirmed by X‐ray microradiography and histology. The BMSC‐seeded scaffold induced more new bone formation than did an acellular scaffold. These observations suggest that the BMSCs‐seeded GTP scaffold can promote the regeneration of defective bone tissue. Copyright © 2012 John Wiley & Sons, Ltd.     

Improved calvarial bone repair by hASCs engineered with Cre/loxP‐based baculovirus conferring prolonged BMP‐2 and MiR‐148b co‐expression

Repairing large calvarial bone defects remains a challenging task. Previously, it was discovered that that miR‐148b, when acting in concert with bone morphogenetic protein 2 (BMP‐2), enhanced the osteogenesis of human adipose‐derived stem cells (hASCs) and improved calvarial bone healing in nude mice. However, the molecular target of miR‐148b remained elusive. Here it is revealed that miR‐148b directly targets NOG, whose gene product (noggin) is an antagonist to BMPs and negatively regulates BMP‐induced osteogenic differentiation and bone formation. A new Cre/loxP‐based baculovirus system was employed to drive prolonged BMP‐2 and miR‐148b overexpression in hASCs, wherein the BMP‐2 overexpression induced noggin expression but the concurrent miR‐148b expression downregulated noggin, thus relieving the negative regulatory loop and ameliorating hASC osteogenesis without hindering hASC proliferation or triggering appreciable cytotoxicity. Implantation of the engineered hASCs coexpressing BMP‐2 and miR‐148b into nude mice enabled substantial repair of critical‐size calvarial bone defects (4 mm diameter) at 12 weeks post‐transplantation, filling 83% of the defect area, 75% of bone volume and restoring the bone density to 89% of the original bone density. Such superior healing effects indicate the potential of the Cre/loxP‐based baculovirus‐mediated BMP‐2/miR‐148b expression for calvarial bone repair. Copyright © 2016 John Wiley & Sons, Ltd.