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.     

Cultured cell‐derived extracellular matrices to enhance the osteogenic differentiation and angiogenic properties of human mesenchymal stem/stromal cells

Cell‐derived extracellular matrix (ECM) consists of a complex assembly of fibrillary proteins, matrix macromolecules, and associated growth factors that mimic the composition and organization of native ECM micro‐environment. Therefore, cultured cell‐derived ECM has been used as a scaffold for tissue engineering settings to create a biomimetic micro‐environment, providing physical, chemical, and mechanical cues to cells, and support cell adhesion, proliferation, migration, and differentiation. Here, we present a new strategy to produce different combinations of decellularized cultured cell‐derived ECM (dECM) obtained from different cultured cell types, namely, mesenchymal stem/stromal cells (MSCs) and human umbilical vein endothelial cells (HUVECs), as well as the coculture of MSC:HUVEC and investigate the effects of its various compositions on cell metabolic activity, osteogenic differentiation, and angiogenic properties of human bone marrow (BM)‐derived MSCs, vital features for adult bone tissue regeneration and repair. Our findings demonstrate that dECM presented higher cell metabolic activity compared with tissue culture polystyrene. More importantly, we show that MSC:HUVEC ECM enhanced the osteogenic and angiogenic potential of BM MSCs, as assessed by in vitro assays. Interestingly, MSC:HUVEC (1:3) ECM demonstrated the best angiogenic response of MSCs in the conditions tested. To the best of our knowledge, this is the first study that demonstrates that dECM derived from a coculture of MSC:HUVEC impacts the osteogenic and angiogenic capabilities of BM MSCs, suggesting the potential use of MSC:HUVEC ECM as a therapeutic product to improve clinical outcomes in bone regeneration.     

Micropattern size‐dependent endothelial differentiation from a human induced pluripotent stem cell line

The multifaceted extracellular milieu presents biochemical and biophysical stimuli that influence stem cell differentiation. Two‐dimensional (2D) micropatterned substrates allow the presentation of these cues in spatially defined geometries that have been demonstrated to guide stem cell fate decisions. Leveraging stem cells to reconstruct microvasculature, made up of an inner lining of endothelial cells (ECs) supported by pericytes, is critical to tissue‐engineering advances; thus, methods to improve endothelial differentiation efficiency are vital to these efforts. In this study, we examine the hypothesis that the diameter of micropatterned islands influences endothelial differentiation from human induced pluripotent stem cells (hiPSCs). Comparing island diameters of 80, 140, 225 and 500 µm, we found that co‐cultures of control ECs and pericytes did not yield variable ratios of cell types; however, when hiPSCs were differentiated toward a bicellular population of ECs and pericytes on these varying micropattern feature sizes, we found that smaller islands promoted EC differentiation efficiency, yielding a derived population composed of 70% ECs, which exhibited a greater sprouting propensity. Differentiation on the largest feature size exhibited a smaller EC yield, similar to that on non‐patterned substrates. Taken together, these data demonstrate that micropatterned islands of varying diameters can be used to modulate EC differentiation efficiency. Copyright © 2015 John Wiley & Sons, Ltd.     

Adipose‐derived stem cells induce vascular tube formation of outgrowth endothelial cells in a fibrin matrix

Vascularization of engineered tissues is one of the current challenges in tissue engineering. Several strategies aim to generate a prevascularized scaffold which can be implanted at sites of injury or trauma. Endothelial cells derived from peripheral blood (outgrowth endothelial cells, OECs) display promising features for vascular tissue engineering, including their autologous nature, capacity for proliferation and ability to form mature vessels. In this study we investigated the ability of OECs to form vascular structures in co‐culture with adipose‐derived stem cells (ASCs) in a fibrin matrix. Using microcarrier beads coated with OECs, we showed ingrowth of endothelial cells in the fibrin scaffold. Furthermore, co‐cultures with ASCs induced vessel formation, as evidenced by immunostaining for CD31. The degradation of fibrin is at least in part mediated by expression of matrix metalloproteinase‐14. Moreover, we showed OEC/ASC‐induced vessel‐like structure formation even in the absence of microcarrier beads, where increasing amounts of ASCs resulted in a denser tubular network. Our data add new insights into co‐culture‐induced vessel formation of outgrowth endothelial cells within a fibrin matrix in an autologous system. Copyright © 2012 John Wiley & Sons, Ltd.     

兔骨髓间充质干细胞的分离培养及成骨诱导

背景：骨髓间充质干细胞具有多向分化潜能,且可大量体外扩增培养,是重要的组织工程种子细胞。但尚无统一的体外培养及定向诱导方法。目的：探讨体外定向诱导兔骨髓间充质干细胞分化为成骨细胞的可行性。方法：应用密度梯度离心法从兔四肢骨中分离纯化间充质干细胞,应用密度为1．073g／mL的Percoll分离液,3000r／minx30min离心,区别于相关报道的Ficoll分离液,2000—2500r／min×（20—30）min离心以及全骨髓培养法体外扩增至第3代,分别在普通培养基（对照组）和成骨诱导培养基（实验组）中培养。结果与结论：成功获得大量高纯度骨髓间充质干细胞。经成骨诱导后,实验组骨钙素含量明显高于对照组（P〈0．05）。实验组碱性磷酸酶和钙结节染色阳性,对照组均阴性。结果表明使用密度梯度离心法可成功建立兔骨髓间充质干细胞的分离培养体系,骨髓间充质干细胞可定向诱导为成骨细胞。     

Co‐culture of adipose‐derived stem cells and endothelial cells in fibrin induces angiogenesis and vasculogenesis in a chorioallantoic membrane model

Neovascularization of adipose tissue equivalents is a crucial step in successful adipose tissue engineering, since insufficient vascularization results in graft resorption in an in vivo situation. A possible cellular approach to overcome this limitation is the co‐implantation of adipose‐derived stem cells (ASCs) with endothelial cells to stimulate the formation of a vascular network. We investigated the potential of ASCs derived from human abdominal fat tissue co‐cultured with endothelial progenitor cells (EPCs) from human peripheral blood to stimulate neovascularization of fibrin constructs on the chorioallantoic membrane (CAM) of fertilized chicken eggs, in direct comparison to human umbilical vein endothelial cells (HUVECs). After 9 days of incubation, cell–fibrin constructs were explanted and histologically evaluated with respect to ingrowth of avian blood vessels into the construct and formation of human blood vessels by co‐implanted endothelial cells. When administered on the CAM, ASCs successfully guided host vasculature into the construct (angiogenesis) and guided formation of capillary‐like structures by co‐implanted human endothelial cells (vasculogenesis), with HUVECs being superior to EPCs, leading to a perfused avian and human capillary network within the fibrin construct. However, the results also showed that perfused human blood vessels were only observed near the CAM compared to unperfused capillary‐like structures near the top of the construct, indicating that perfusion of the cell–fibrin construct takes longer than 9 days. In conclusion, as blood vessel formation is an essential step during adipogenic differentiation, the data support our hypothesis that cellular communication between transplanted ASCs and endothelial cells is beneficial for vasculogenesis. Copyright © 2013 John Wiley & Sons, Ltd.     

人脐带羊膜来源和骨髓来源间充质干细胞的免疫调控特征比较

本研究旨在比较人脐带羊膜来源的间充质干细胞(mesenchymal stem cells,MSC)与骨髓来源MSC的免疫调控能力,为临床开展异基因造血干细胞移植提供实验依据。采用胶原酶消化法分离人脐带羊膜贴壁细胞,并从细胞形态、生长特性、细胞表型、多向分化能力进行鉴定。利用淋巴细胞转化实验和混合淋巴细胞反应比较人脐带羊膜来源MSC与人骨髓来源MSC的免疫调控能力的差异。结果表明,人脐带羊膜来源和骨髓来源的MSC具有相似的生物学特征,即细胞呈成纤维样形态生长,并具有强大的体外扩增能力;流式细胞仪检测细胞表型结果显示,脐带羊膜来源MSC高表达CD73、CD90、CD105,而骨髓来源MSC表面标志CD34、CD45以及参与免疫反应的细胞表面分子HLA-DR和CD86等为阴性。其诱导多向分化能力结果表明,两组细胞均可向成脂肪、成骨和成软骨分化。混合淋巴细胞反应和淋巴细胞转化实验证明,两组MSC均可抑制异体T细胞的增殖,且随MSC数量的增加,抑制效应逐渐增强;RT-PCR检测显示两组MSC表达相同的免疫相关因子。结论:人脐带羊膜来源的MSC可以替代成人骨髓MSC,可作为满足实验和临床需要的MSC重要来源。     

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.     

Osteoarthritic human chondrocytes proliferate in 3D co‐culture with mesenchymal stem cells in suspension bioreactors

Osteoarthritis (OA) is a painful disease, characterized by progressive surface erosion of articular cartilage. The use of human articular chondrocytes (hACs) sourced from OA patients has been proposed as a potential therapy for cartilage repair, but this approach is limited by the lack of scalable methods to produce clinically relevant quantities of cartilage‐generating cells. Previous studies in static culture have shown that hACs co‐cultured with human mesenchymal stem cells (hMSCs) as 3D pellets can upregulate proliferation and generate neocartilage with enhanced functional matrix formation relative to that produced from either cell type alone. However, because static culture flasks are not readily amenable to scale up, scalable suspension bioreactors were investigated to determine if they could support the co‐culture of hMSCs and OA hACs under serum‐free conditions to facilitate clinical translation of this approach. When hACs and hMSCs (1:3 ratio) were inoculated at 20,000 cells/ml into 125‐ml suspension bioreactors and fed weekly, they spontaneously formed 3D aggregates and proliferated, resulting in a 4.75‐fold increase over 16 days. Whereas the apparent growth rate was lower than that achieved during co‐culture as a 2D monolayer in static culture flasks, bioreactor co‐culture as 3D aggregates resulted in a significantly lower collagen I to II mRNA expression ratio and more than double the glycosaminoglycan/DNA content (5.8 vs. 2.5 μg/μg). The proliferation of hMSCs and hACs as 3D aggregates in serum‐free suspension culture demonstrates that scalable bioreactors represent an accessible platform capable of supporting the generation of clinical quantities of cells for use in cell‐based cartilage repair.     

Interactive endothelial phenotype maintenance and osteogenic differentiation of adipose tissue stromal vascular fraction SSEA‐4+‐derived cells

Bone formation relies on complex processes that require well‐orchestrated interactions between several cell types, such as bone‐forming cells (osteoblasts, OBs) and endothelial cells (ECs). Their co‐culture has been proved relevant to mimicking specific features of the bone niche. Here we propose the co‐culture of microvascular‐like ECs and pre‐OBs, both derived from the SSEA‐4⁺ cell subpopulation from the stromal vascular fraction of human adipose tissue (SSEA‐4⁺ hASCs), to define the conditions in which cells synergistically communicate to support the full differentiation of pre‐OBs and maintenance of the EC phenotype. Co‐cultures of different ratios of the two cell types were established and maintained for up to 21 days in standard endothelial maintenance (ENDO) and osteogenic differentiation (OST) media, as well as in a mixture of these (MIX). The osteogenic maturation of pre‐OBs (ALP activity, OPN and OCN expression, calcium deposition), the evolution of EC numbers (CD31⁺ cells) and maintenance of the endothelial phenotype (CD31 and vWF expression, LDL uptake) were assessed throughout the culture time as a function of cell ratio and culture media. The results obtained demonstrate that EC number has a significant effect on the osteogenic differentiation of pre‐OBs, depending on the medium used. While in ENDO medium the osteogenic differentiation was not observed, in the OST and MIX media it was attained at similar levels, except for the co‐culture with a higher number of ECs in MIX medium. These findings demonstrate that the use of SSEA‐4⁺ hASCs as a single‐cell source is promising to attain 3D bone‐like models with the potential to promote vascularized bone tissue regeneration. Copyright © 2015 John Wiley & Sons, Ltd.     

人脐带和骨髓源间充质干细胞对脐血单个核细胞增殖能力的影响

目的：探讨人脐带间充质干细胞（UCMSCs）与骨髓间充质干细胞（BMMSCs）在体外对造血干细胞的支持作用。方法分别从人脐带和骨髓中分离、培养间充质干细胞,通过免疫细胞化学染色等方法对其进行表型鉴定;采用流式细胞仪测定脐血单个核细胞的周期分布,采用甲基纤维素法测定脐血单个核细胞混合集落形成单位（CFU-Mix）,比较 UCMSCs和BMMSCs对脐血单个核细胞细胞周期、CFU-Mix形成能力的影响。结果成功培养获得 UCMSCs和BMMSCs,鉴定结果符合预期;与非共培养组细胞相比,UCMSCs和 BMMSCs共培养均能促进脐血单个核细胞进入增殖周期,并增加其形成CFU-Mix的能力（P＜0．05）,但UCMSCs和BMMSCs共培养组之间比较差异无统计学意义（P＞0．05）。结论成功从人脐带和骨髓组织中培养获得间充质干细胞,两种来源的间充质干细胞均能提高脐血单个核细胞的体外增殖能力及 CFU-Mix形成能力,均具有造血支持作用。     

Fucoidan‐induced osteogenic differentiation promotes angiogenesis by inducing vascular endothelial growth factor secretion and accelerates bone repair

Osteogenesis and angiogenesis, including cell–cell communication between blood vessel cells and bone cells, are essential for bone repair. Fucoidan is a chemical compound that has a variety of biological activities. It stimulates osteoblast differentiation in human mesenchymal stem cells (MSCs), which in turn induces angiogenesis. However, the mechanism by which this communication between osteoblasts and endothelial cells is mediated remains unclear. Thus, the aim of this study was to clarify the relationship between fucoidan‐induced osteoblastic differentiation in MSCs and angiogenesis in endothelial cells. First, the effect was confirmed of fucoidan on osteoblast differentiation in MSCs and obtained conditioned media from these cells (Fucoidan‐MSC‐CM). Next, the angiogenic activity of Fucoidan‐MSC‐CM was investigated and it was found that it stimulated angiogenesis, demonstrated by proliferation, tube formation, migration and sprout capillary formation in human umbilical vein endothelial cells. Messenger ribonucleic acid expression and protein secretion of vascular endothelial growth factor (VEGF) were dramatically increased during fucoidan‐induced osteoblast differentiation and that its angiogenic activities were reduced by a VEGF/VEGF receptor‐specific binding inhibitor. Furthermore, Fucoidan‐MSC‐CM increased the phosphorylation of mitogen‐activated protein kinase and PI3K/AKT/eNOS signalling pathway, and that its angiogenic effects were markedly suppressed by SB203580 and AKT 1/2 inhibitor. Finally, an in vivo study was conducted and it was found that fucoidan accelerated new blood vessel formation and partially promoted bone formation in a rabbit model of a calvarial bone defect. This is the first study to investigate the angiogenic effect of fucoidan‐induced osteoblastic differentiation through VEGF secretion, suggesting the therapeutic potential of fucoidan for enhancing bone repair.     

Neutrophil‐mediated enhancement of angiogenesis and osteogenesis in a novel triple cell co‐culture model with endothelial cells and osteoblasts

Repair and regeneration of critical‐sized bone defects remain a major challenge in orthopaedic and craniomaxillofacial surgery. Until now, attempts to bioengineer bone tissue have been hindered by the inability to establish proper angiogenesis and osteogenesis in the tissue construct. In the present study, we established a novel triple cell co‐culture model consisting of osteoblasts, endothelial cells, and neutrophils and conducted a systematic investigation of the effects of neutrophils on angiogenesis and osteogenesis. Neutrophils significantly increased angiogenesis in the tissue construct, evidenced by the formation of microvessel‐like structures with an extensive lattice‐like, stable tubular network in the co‐culture model. Moreover, neutrophils significantly induced the expression of pro‐angiogenic markers, such as VEGF‐A, CD34, EGF, and FGF‐2 in a dose‐ and time‐dependent manner. Subsequently, PCR arrays corroborated that neutrophils upregulate the important angiogenic markers and MMPs. Moreover, neutrophils also enhanced osteogenic markers, such as ALP, OCN, OPN, and COL‐1 compared with the controls. As shown by the osteogenic gene arrays, neutrophils significantly regulated major osteogenic markers such as BMP2, BMP3, BMP4, BMP5, TGF‐β2, RUNX2, and ECM proteins. Significantly higher mineralization was observed in triple cell co‐culture compared with controls. Foregoing data indicate that the triple cell co‐culture model can be used to stimulate the growth of microvasculature within a bone bioengineering construct to improve cell viability. Neutrophil‐mediated enhancement of angiogenesis and osteogenesis could be a viable, clinically relevant tissue engineering strategy to obtain optimal bone growth in defect sites, in the field of oral and maxillofacial surgery.     

Integrated culture platform based on a human platelet lysate supplement for the isolation and scalable manufacturing of umbilical cord matrix‐derived mesenchymal stem/stromal cells

Umbilical cord matrix (UCM)‐derived mesenchymal stem/stromal cells (MSCs) are promising therapeutic candidates for regenerative medicine settings. UCM MSCs have advantages over adult cells as these can be obtained through a non‐invasive harvesting procedure and display a higher proliferative capacity. However, the high cell doses required in the clinical setting make large‐scale manufacturing of UCM MSCs mandatory. A commercially available human platelet lysate‐based culture supplement (UltraGRO^TM, AventaCell BioMedical) (5%(v/v)) was tested to effectively isolate UCM MSCs and to expand these cells under (1) static conditions, using planar culture systems and (2) stirred culture using plastic microcarriers in a spinner flask. The MSC‐like cells were isolated from UCM explant cultures after 11 ± 2 days. After five passages in static culture, UCM MSCs retained their immunophenotype and multilineage differentiation potential. The UCM MSCs cultured under static conditions using UltraGRO^TM‐supplemented medium expanded more rapidly compared with UCM MSCs expanded using a previously established protocol. Importantly, UCM MSCs were successfully expanded under dynamic conditions on plastic microcarriers using UltraGRO^TM‐supplemented medium in spinner flasks. Upon an initial 54% cell adhesion to the beads, UCM MSCs expanded by >13‐fold after 5–6 days, maintaining their immunophenotype and multilineage differentiation ability. The present paper reports the establishment of an easily scalable integrated culture platform based on a human platelet lysate supplement for the effective isolation and expansion of UCM MSCs in a xenogeneic‐free microcarrier‐based system. This platform represents an important advance in obtaining safer and clinically meaningful MSC numbers for clinical translation. Copyright © 2016 John Wiley & Sons, Ltd.     

Improved expansion of human bone marrow‐derived mesenchymal stem cells in microcarrier‐based suspension culture

Human bone marrow‐derived mesenchymal stem cells (hBM‐MSCs) have potential clinical utility in the treatment of a multitude of ailments and diseases, due to their relative ease of isolation from patients and their capacity to form many cell types. However, hBM‐MSCs are sparse, and can only be isolated in very small quantities, thereby hindering the development of clinical therapies. The use of microcarrier‐based stirred suspension bioreactors to expand stem cell populations offers an approach to overcome this problem. Starting with standard culture protocols commonly reported in the literature, we have successfully developed new protocols that allow for improved expansion of hBM‐MSCs in stirred suspension bioreactors using CultiSpher‐S microcarriers. Cell attachment was facilitated by using intermittent bioreactor agitation, removing fetal bovine serum, modifying the stirring speed and manipulating the medium pH. By manipulating these parameters, we enhanced the cell attachment efficiency in the first 8 h post‐inoculation from 18% (standard protocol) to 72% (improved protocol). Following microcarrier attachment, agitation rate was found to impact cell growth kinetics, whereas feeding had no significant effect. By serially subculturing hBM‐MSCs using the new suspension bioreactor protocols, we managed to obtain cell fold increases of 10³ within 30 days, which was superior to the 200‐fold increase obtained using the standard protocol. The cells were found to retain their defining characteristics after several passages in suspension. This new bioprocess represents a more efficient approach for generating large numbers of hBM‐MSCs in culture, which in turn should facilitate the development of new stem cell‐based therapies. Copyright © 2012 John Wiley & Sons, Ltd.     

Collagen scaffold combined with human umbilical cord‐derived mesenchymal stem cells promote functional recovery after scar resection in rats with chronic spinal cord injury

Effective therapeutic strategies for treating chronic spinal cord injury (SCI) are currently unavailable. Scar tissue in the lesion area is a main inhibitory factor for axonal regeneration and repair of chronic SCI. In this study, scar tissue was surgically resected from adult rats with 12 week chronic SCI and then collagen scaffold (NeuroRegen Scaffold; NRS) and human umbilical cord‐derived mesenchymal stem cells (hUC‐MSCs) were implanted into the resected cavity to repair chronic SCI. The results demonstrated that the locomotor function of rats was not affected by surgical scar resection, indicating its safety in treating chronic SCI. Implanting NRS and hUC‐MSCs promoted locomotion in rats and improved cortical motor‐ and somatosensory‐evoked potentials. Furthermore, implanting NRS and hUC‐MSCs promoted neurofilament‐ and β‐tubulin‐III‐positive neural regeneration and remyelination, elicited β‐tubulin‐III‐positive neuron production in the lesion area and blocked astrocyte growth outside the lesion area. In conclusion, implanting NRS in combination with hUC‐MSCs provided a beneficial microenvironment for neural regeneration, showing significant therapeutic effects for chronic SCI.     

Co‐transplantation of Wharton's jelly mesenchymal stem cell‐derived osteoblasts with differentiated endothelial cells does not stimulate blood vessel and osteoid formation in nude mice models

A major challenge in bone tissue engineering is the lack of post‐implantation vascular growth into biomaterials. In the skeletal system, blood vessel growth appears to be coupled to osteogenesis—suggesting the existence of molecular crosstalk between endothelial cells (ECs) and osteoblastic cells. The present study (performed in two murine ectopic models) was designed to determine whether co‐transplantation of human Wharton's jelly mesenchymal stem cell‐derived osteoblasts (WJMSC‐OBs) and human differentiated ECs enhances bone regeneration and stimulates angiogenesis, relative to the seeding of WJMSC‐OBs alone. Human WJMSC‐OBs and human ECs were loaded into a silicate‐substituted calcium phosphate (SiCaP) scaffold and then ectopically implanted at subcutaneous or intramuscular sites in nude mice. At both subcutaneous and intramuscular implantation sites, we observed ectopic bone formation and osteoids composed of host cells when WJMSC‐OBs were seeded into the scaffold. However, the addition of ECs was associated with a lower level of osteogenesis, and we did not observe stimulation of blood vessel ingrowth. in vitro studies demonstrated that WJMSC‐OBs lost their ability to secrete vascular endothelial growth factor and stromal cell‐derived factor 1—including when ECs were present. In these two murine ectopic models, our cell‐matrix environment combination did not seem to be optimal for inducing vascularized bone reconstruction.     

Bone marrow mesenchymal stem cells,platelet‐rich plasma and nanohydroxyapatite–type I collagen beads were integral parts of biomimetic bone substitutes for bone regeneration

Platelet rich plasma (PRP), which includes many growth factors, can activate osteoid production, collagen synthesis and cell proliferation. Nanohydroxyapatite‐type I collagen beads (CIB), which mimetic natural bone components, are not only flexible fillers for bone defect but also encourage osteogenesis. Bone marrow mesenchymal stem cells (BMSCs) are often used as an abundant cell source for tissue engineering. We used a rabbit model to combine PRP, CIB and BMSCs (CIB+PRP+BMSC) into a bone‐like substitute to study its impact on bone regeneration, when compared to defect alone, PRP, CIB+PRP, and PRP+BMSC. CIB+PRP upregulated more alkaline phosphatase (ALP) activity in BMSCs than PRP alone at 4 weeks postoperation. CIB+PRP+BMSC and PRP+BMSC did not differ significantly in DNA content, total collagen content, and ALP activity at 8 weeks. In histological assay, both CIB+PRP+BMSC and PRP+BMSC showed more bone regeneration at 4 and 8 weeks. Higher trabecular bone volume in tissue volume (BV/TV) (31.15±2.67% and 36.93±1.01%), fractal dimension (FD) (2.30±0.18 and 2.65±0.02) and lower trabecular separation (Tb.Sp) (2.30±0.18 and 1.35±0.16) of CIB+PRP+BMSC than of other groups at 4 and 8 weeks, and approach to of bone tissue (BV/TV=24.35±2.13%; FD=2.65±0.06; Tb.Sp=4.19±0.95). CIB+PRP+BMSC significantly enhanced new bone formation at 4 week. Therefore, nanohydroxyapatite‐type I collagen beads combined with PRP and BMSCs produced a bone substitute with efficiently improved bone regeneration that shows promise to repair bone defects. Copyright © 2012 John Wiley & Sons, Ltd.     

Electrical stimulation of adipose‐derived mesenchymal stem cells and endothelial cells co‐cultured in a conductive scaffold for potential orthopaedic applications

Electrical stimulation (ES) has emerged as a useful tool to regulate cell behaviour, but the effect of ES on mesenchymal stem cell (MSC)/vasculogenic cell co‐culture has not been investigated. Herein, human adipose‐derived MSCs (AD‐MSCs) and umbilical vein endothelial cells (HUVECs) were co‐cultured in an electrically conductive polypyrrole/chitosan scaffold. Compared with AD‐MSC monoculture, calcium deposition in the co‐culture without and with ES (200 μA for 4 h/day) was 139% and 346% higher, respectively, after 7 days. As the application of ES to AD‐MSC monoculture only increased calcium deposition by 56% compared with that without ES after 7 days, these results indicate that ES and co‐culture with HUVECs have synergistic effects on AD‐MSCs' osteogenic differentiation. ES application also significantly enhanced CD31 expression of HUVECs. In HUVEC monoculture, application of ES increased CD31 expression by 224%, whereas the corresponding increase in AD‐MSC/HUVEC co‐culture with ES application was 62%. The gene expression results indicate that ES enhanced the cellular functions in AD‐MSC and HUVEC monoculture via autocrine bone morphogenetic protein‐2 (BMP‐2) and vascular endothelial growth factor (VEGF), respectively. In co‐culture, crosstalk between AD‐MSCs and HUVECs due to paracrine BMP‐2 and VEGF enhanced the cellular functions compared with the respective monoculture. With application of ES to the AD‐MSC/HUVEC co‐culture, autocrine signalling was enhanced, resulting in further promotion of cellular functions. These findings illustrate that co‐culturing AD‐MSC/HUVEC in a conductive scaffold with ES offers potential benefits for bone defect therapy.