Repair of bone defects using dynamic fabricated tissue-engineered bone based on a bio-derived porous bone scaffold

Fabrication and transplantation of tissue-engineered bones in a rotating wall vessel bioreactor (RWVB) was studied in the present study aiming to repair segmental bone defects. Osteoblasts were transfected with green fluorescent protein prior to seeding on bio-derived porous bone scaffolds at a density of 1?×?10⁶?cells/mL and cultured in an RWVB for one week. For comparison, constructs were also cultured in a static condition. Morphology and structure of fabricated bones were examined using an inverted microscope, scanning electron microscope and histology analysis via hematoxylin–eosin and toluidine blue staining. Moreover, an animal model for repairing segmental bone defects of a Zelanian rabbit was used to assess the efficacy and biosafety of fabricated bones. In conclusion, tissue-engineered bones grew favorably in RWVB. In animal study, a preliminary repair of bone defects was noticed only in the experimental group after 4 weeks of implantation. Using RWVB, the fabricated tissue-engineered bone constructs were approved with better bio-capability in repairing the segmental bone defect.     

Synthetic scaffold coating with adeno-associated virus encoding BMP2 to promote endogenous bone repair

Biomaterial scaffolds functionalized to stimulate endogenous repair mechanisms via the incorporation of osteogenic cues offer a potential alternative to bone grafting for the treatment of large bone defects. We first quantified the ability of a self-complementary adeno-associated viral vector encoding bone morphogenetic protein 2 (scAAV2.5-BMP2) to enhance human stem cell osteogenic differentiation in vitro. In two-dimensional culture, scAAV2.5-BMP2-transduced human mesenchymal stem cells (hMSCs) displayed significant increases in BMP2 production and alkaline phosphatase activity compared with controls. hMSCs and human amniotic-fluid-derived stem cells (hAFS cells) seeded on scAAV2.5-BMP2-coated three-dimensional porous polymer Poly(ε-caprolactone) (PCL) scaffolds also displayed significant increases in BMP2 production compared with controls during 12 weeks of culture, although only hMSC-seeded scaffolds displayed significantly increased mineral formation. PCL scaffolds coated with scAAV2.5-BMP2 were implanted into critically sized immunocompromised rat femoral defects, both with or without pre-seeding of hMSCs, representing ex vivo and in vivo gene therapy treatments, respectively. After 12 weeks, defects treated with acellular scAAV2.5-BMP2-coated scaffolds displayed increased bony bridging and had significantly higher bone ingrowth and mechanical properties compared with controls, whereas defects treated with scAAV2.5-BMP2 scaffolds pre-seeded with hMSCs failed to display significant differences relative to controls. When pooled, defect treatment with scAAV2.5-BMP2-coated scaffolds, both with or without inclusion of pre-seeded hMSCs, led to significant increases in defect mineral formation at all time points and increased mechanical properties compared with controls. This study thus presents a novel acellular bone-graft-free endogenous repair therapy for orthotopic tissue-engineered bone regeneration.     

Feasibility of repairing skin defects by VEGF165 gene-modified iPS-HFSCs seeded on a 3D printed scaffold containing astragalus polysaccharide

The preparation of biodegradable scaffolds loaded with cells and cytokine is a feature of tissue-engineered skin. IPSCs-based tissue-engineered skin treatment for wound repair is worth exploring. Healthy human skin fibroblasts were collected and reprogrammed into iPSCs. After gene modification and induction, CK19⁺/Integrinβ1⁺/CD200⁺ VEGF₁₆₅ gene-modified iPS-HFSCs^GFP were obtained and identified by a combination of immunofluorescence and RT-qPCR. Astragalus polysaccharide-containing 3D printed degradable scaffolds were prepared and co-cultured with VEGF₁₆₅ gene-modified iPS-HFSCs^GFP, and the biocompatibility and spatial structure of the tissue-engineered skin was analysed by cell counting kit-8 (CCK8) assay and scanning electron microscopy. Finally, the tissue-engineered skin was transplanted onto the dorsal trauma of nude mice, and the effect of tissue-engineered skin on the regenerative repair of total skin defects was evaluated by a combination of histology, immunohistochemistry, immunofluorescence, RT-qPCR, and in vivo three-dimensional reconstruction under two-photon microscopy. CK19⁺/Integrinβ1⁺/CD200⁺ VEGF₁₆₅ gene-modified iPS-HFSCs^GFP, close to the morphology and phenotype of human-derived hair follicle stem cells, were obtained. The surface of the prepared 3D printed degradable scaffold containing 200 μg/mL astragalus polysaccharide was enriched with honeycomb-like meshwork, which was more conducive to the proliferation of the resulting cells. After tissue-engineered skin transplantation, combined assays showed that it promoted early vascularization, collagen and hair follicle regeneration and accelerated wound repair. VEGF₁₆₅ gene-modified iPS-HFSCs^GFP compounded with 3D printed degradable scaffolds containing 200 μg/mL astragalus polysaccharide can directly and indirectly participate in vascular, collagen, and hair follicle regeneration in the skin, achieving more complete structural and functional skin regenerative repair.     

Tissue-engineered mesh for pelvic floor reconstruction fabricated from silk fibroin scaffold with adipose-derived mesenchymal stem cells

A tissue-engineered mesh fabricated with adipose-derived mesenchymal stem cells (AD-MSCs) cultured on a silk fibroin scaffold is evaluated for use in female pelvic reconstruction. Thirty-five female Sprague Dawley rats were divided into four groups. Group A (n?=?10) were implanted with polypropylene meshes, Group B (n?=?10) with silk fibroin scaffolds and Group C (n?=?10) with tissue-engineered meshes. Group D (n?=?5) acted as the tissue control. The tissue-engineered mesh was produced as follows. AD-MSCs were obtained from adipose tissue of rats designated to Group C. The cells were seeded onto a silk fibroin scaffold, cultured and then observed by scanning electron microscopy (SEM). Histological studies of these meshes were performed at 4 and 12 weeks after implantation and mechanical testing was carried out on all groups before implantation and at 12 weeks after implantation. AD-MSCs displayed fibroblast-like shapes and were able to differentiate into adipocytes or fibroblasts. SEM observation showed that AD-MSCs proliferated and secreted a matrix onto the silk fibroin scaffolds. After implantation of the scaffolds into rats, histological analysis revealed better organized newly formed tissue in Group C than in controls. Group C also had a similar failure force (2.67?±?0.15 vs 2.33?±?0.38 N) and a higher Young’s modulus (2.99?±?0.19 vs 1.68?±?0.20 MPa) than a normal vaginal wall, indicating the potential of this tissue-engineered approach. AD-MSCs were validated as seed cells for tissue engineering. The silk fibroin scaffold thus shows promise for application with AD-MSCs in the fabrication of tissue-engineered mesh with good biocompatibility and appropriate mechanical properties for pelvic floor reconstruction.     

膜性高分子材料在兔眼部的生物相容性

目的评价聚羟基脂肪酸(polyhydroxyalkanoates,PHA)、聚乳酸(polylacetic acid,PLA)和聚己内酯(polycaprolactone,PCL)三种膜性高分子材料在兔眼部的生物相容性。方法将24只新西兰兔随机分为4组,每组6只。PHA、PLA、PCL为实验组,材料植入兔右眼结膜下。假手术组结膜下钝性分离,但不植入任何高分子材料。使用裂隙灯显微镜观察并记录植入后不同时间手术眼的反应并评分。裂隙灯下观察材料的吸收时间。术后4周和16周取眼球,行HE染色、Masson染色和天狼猩红染色分别定性观察组织结构和炎症细胞、胶原纤维和胶原纤维的亚型与排列方向。结果术眼刺激性评分等级各组均不高于"轻度刺激性"。结膜下吸收时间PHA、PLA和PCL组分别是16周,12周和大于16周。组织学观察术后4周PHA、PLA和PCL组均形成材料包裹囊腔,囊壁以纤维组织为主,伴有毛细血管形成和炎性细胞浸润,以中性粒细胞为主。胶原纤维染色与假手术组无明显差异,以Ⅰ型和Ⅲ型为主,大致呈平行排列。术后16周PHA和PLA组材料已不可查及,包裹囊腔结构不规则,而PCL材料整体可查及,包裹囊腔规则。各组未见毛细血管,偶见淋巴细胞浸润。胶原纤维与假手术组无明显差异,以Ⅰ型和Ⅲ型为主,仍大致呈平行排列。结论 PHA、PLA和PCL三种膜性高分子材料在兔眼具有较好的生物相容性,结膜下吸收时间分别是16周,12周和大于16周。     

Combination of bone tissue engineering and BMP-2 gene transfection promotes bone healing in osteoporotic rats

OBJECTIVE: The aim of this study was to develop a feasible approach to promote bone healing in osteoporotic rats using autogenous bone tissue-engineering and gene transfection of human bone morphogenetic protein 2 (hBMP-2). METHODS: Bone marrow stromal cells (BMSCs) from the left tibia of osteoporotic rats were transfected with the hBMP-2 gene in vitro which was confirmed by immunohistochemistry, in situ hybridization and Western blotting. Autogenous transfected or untransfected BMSCs were seeded on macroporous coral hydroxyapatite (CHA) scaffolds. Each cell-scaffold construct was implanted into a defect site which was created in the ramus of the mandible of osteoporotic rats. Four or eight weeks after implantation in situ hybridization was performed in BMSCs transfected with hBMP-2, X-ray examinations, histological and histomorphological analyses were used to evaluate the effect of tissue-engineered bone on osseous defect repair. RESULTS: Newly formed bone was observed at the margin of the defect 4 weeks after implantation with BMSCs transfected with BMP-2. Mature bone was observed 8 weeks after treatment. In the control group there was considerably less new bone and some adipose tissue was observed at the defect margins 8 weeks after implantation. CONCLUSIONS: Autogenous cells transfected with hBMP-2 promote bone formation in osteoporotic rats. BMSC-mediated BMP-2 gene therapy used in conjunction with bone tissue engineering may be used to successfully treat bone defects in osteoporotic rats. This method provides a powerful tool for bone regeneration and other tissue engineering.     

表面改性双相陶瓷复合自体骨髓干细胞修复兔骨缺损的实验研究

目的:应用自体骨髓基质干细胞(Bone Marrow Stromal Cells,BMSCs)复合经低晶态羟基磷灰石(Low Crystalline Hydroxyap- atite,LcHA)涂层的双相陶瓷(Biphasic Calcium Phosphate,BCP)构建的组织工程化骨(LcBCP)修复兔桡骨节段性缺损。方法:体外分离培养、诱导扩增兔BMSCs,取第三代细胞复合LcBCP(实验组)后修复15只兔左侧桡骨15mm缺损;右侧桡骨缺损处植入复合BMSCs的BCP(对照组),于植入后4、8和12周处死动物,通过大体形态、组织学、影像学和扫描电镜检测骨缺损修复效果。结果:BMSCs-LcBCP复合物生长良好,随时间延长,X线显示实验组连接处骨痂形成,对照组连接处始终愈合稍差,12周大体观察实验组骨修复良好,髓腔再通;组织学显示板层骨形成,连接处骨性愈合,实验对照组连接处虽然也为骨性愈合,但尚有较多编织骨形成。结论:自体BMSCs复合LcBCP形成的组织工程化骨可修复兔桡骨节段性缺损,低晶态羟基磷灰石涂层能够增强双相陶瓷的早期成骨。     

Promotion of human mesenchymal stem cell differentiation on bioresorbable polycaprolactone/biphasic calcium phosphate composite scaffolds for bone tissue engineering

An artificial construct mimicking the intrinsic properties of the natural extracellular matrix in bones has been considered an ideal platform for bone tissue engineering, as it can present an appropriate microenvironment and regulate cell behaviours. In this report, we introduce biodegradable composite scaffolds consisting of polycaprolactone (PCL) and biphasic calcium phosphate (BCP). The scaffolds were fabricated by a salt-leaching process, and the ability of the scaffolds to facilitate osteogenic differentiation was investigated using human mesenchymal stem cells (hMSCs). The scaffolds had an inter-connected porous structure with quadrilateral pores of approximately 200 ～ 500 μm in width. The mechanical properties of the scaffolds changed as the BCP content was increased in the starting mixture. In the hMSC experiment, although we found that hMSCs adhered to the surface, as well as the inside, of the scaffolds, the incorporated BCP did not increase the proliferation of the hMSCs over 7 days in culture. Interestingly, the alkaline phosphatase (ALP) activity was 4 times higher on the PCL/BCP composite scaffold (0.12 ± 0.03 nmol/min/μg protein) thanon the PCL scaffold (0.03 ± 0.01 nmol/min/μg protein), suggesting that BCP can aid in generating a local environment that promotes bone regeneration. Therefore, a strategy combining polymers and ceramics can be considered a useful platform for bone tissue engineering.     

Influence of Architecture of β-Tricalcium Phosphate Scaffolds on Biological Performance in Repairing Segmental Bone Defects

Background

Although three-dimensional (3D) β-tricalcium phosphate (β-TCP) scaffolds serve as promising bone graft substitutes for the segmental bone defect treatment, no consensus has been achieved regarding their optimal 3D architecture.

Methods

In this study, we has systematically compared four types of β-TCP bone graft substitutes with different 3D architectures, including two types of porous scaffolds, one type of tubular scaffolds and one type of solid scaffolds, for their efficacy in treating segmental bone defect in a rabbit model.

Results

Our study has demonstrated that when compared to the traditional porous and solid scaffolds, tubular scaffolds promoted significantly higher amount of new bone formation in the defect regions as shown by X-ray, micro CT examinations and histological analysis, restored much greater mechanical properties of the damaged bone evidenced by the biomechanical testing, and eventually achieved the complete union of segmental defect. Moreover, the implantation of tubular scaffolds enhanced the neo-vascularization at the defect region with higher bone metabolic activities than others, as indicated by the bone scintigraphy assay.

Conclusions

This study has further the current knowledge regarding the profound influence of overall 3D architecture of β-TCP scaffolds on their in vivo defect healing performance and illuminated the promising potential use of tubular scaffolds as effective bone graft substitute in treating large segmental bone defects.     

利用聚己内酯/羟基磷灰石复合支架修复犬胸骨缺损

目的：探讨利用生物可降解支架修复动物胸骨缺损,为临床手术治疗提供新的可行性方法。方法：对于12只比格犬进行手术切除部分胸骨,并利用聚己内酯/羟基磷灰石（PCL/HA）复合支架,并制备出与临床相似的胸骨缺损模型。实验动物分成2组,分别是：空白对照组和PCL/HA支架组。分别于术后第4、12周进行胸部CT扫描,并对胸廓进行三维重建,观察胸骨缺损部位的修复情况,并在第12周取胸骨缺损部位组织进行硬组织切片,苦味酸-品红染色,观察缺损部位的骨组织修复情况,并利用软件进行骨组织比率分析,评估修复情况。结果：通过检查发现空白对照组的胸骨缺损部位未见明显骨连接,胸廓的骨性结构有明显畸形,PCL/HA支架组能很好地维持胸廓的完整性,组织学检查发现PCL/HA支架组的缺损部位有明显新生骨形成,通过软件分析可发现支架组的骨组织比率较空白组的高（P〈0.05）。结论：这些结果表明采用PCL/HA复合材料支架能很好地修复胸骨缺损。     

Bioresorbable Scaffolds Based on Fibroin for Bone Tissue Regeneration

Using the tissue-engineered constructs based on scaffolds that imitate the extracellular matrix of living tissues unveils new opportunities in the treatment of various pathologies and injuries associated with tissue and organ damage. Silk fibroin of silkworm Bombyx mori is a biocompatible and bioresorbable polymer with high mechanical strength and elasticity that allows creating scaffolds on its basis for regeneration of various tissues, including bone. In the present work, fibroin scaffolds were obtained. They were designed in the form of porous sponges, films, and hybrid scaffolds of a bilayer structure in which the porous sponge threedimensional structure is limited on one side by a film. The structure of the scaffolds and their biocompatibility were studied: immortalized and primary fibroblasts, as well as the osteoblast-like cells, have been shown to successfully adhere and proliferate on the surface of the studied scaffolds. Numerous osteogenesis foci have been observed in the implant region 4 weeks after the fibroin porous scaffold implantation in the in vivo experiments in a rat femoral bone defect model indicating the osteoconduction of the scaffolds.     

Rapid prototyping of anatomically shaped, tissue-engineered implants for restoring congruent articulating surfaces in small joints

Background:  Preliminary studies investigated advanced scaffold design and tissue engineering approaches towards restoring congruent articulating surfaces in small joints.
Materials and methods:  Anatomical femoral and tibial cartilage constructs, fabricated by three-dimensional fibre deposition (3DF) or compression moulding/particulate leaching (CM), were evaluated in vitro and in vivo in an autologous rabbit model. Effects of scaffold pore architecture on rabbit chondrocyte differentiation and mechanical properties were evaluated following in vitro culture and subcutaneous implantation in nude mice. After femoral and tibial osteotomy and autologous implantation of tissue-engineered constructs in rabbit knee joints, implant fixation and joint articulation were evaluated.
Results:  Rapid prototyping of 3DF architectures with 100% interconnecting pores promoted homogeneous distribution of viable cells, glycosaminoglycan (GAG) and collagen type II; significantly greater GAG content and differentiation capacity (GAG/DNA) in vitro compared to CM architectures; and higher mechanical equilibrium modulus and dynamic stiffness (at 0.1 Hz). Six weeks after implantation, femoral and tibial constructs had integrated with rabbit bone and knee flexion/extension and partial load bearing were regained. Histology demonstrated articulating surfaces between femoral and tibial constructs for CM and 3DF architectures; however, repair tissue appeared fibrocartilage-like and did not resemble implanted cartilage.
Conclusions:  Anatomically shaped, tissue-engineered constructs with designed mechanical properties and internal pore architectures may offer alternatives for reconstruction or restoration of congruent articulating surfaces in small joints.     

Supercritical carbon dioxide generated vascular endothelial growth factor encapsulated poly(DL-lactic acid) scaffolds induce angiogenesis in vitro

The ability to deliver, over time, biologically active vascular endothelial growth factor-165 (VEGF) through tailored designed scaffolds offers tremendous therapeutic opportunities to tissue-engineered therapies. Porous biodegradable poly(DL-lactic) acid (PLA) scaffolds encapsulating VEGF have been generated using supercritical CO2 (scCO2) and the kinetic release and angiogenic activity of these scaffolds examined in vitro and in an ex vivo chick chorioallantoic membrane (CAM) angiogenesis model. After processing through scCO2, VEGF maintained its angiogenic activity as assessed by increased tubule formation of human umbilical vein endothelial cells (HUVEC) cultured on Matrigel (VEGF = 1937 +/- 205 microm; scCO2-VEGF = 2085 +/- 234 microm; control = 1237 +/- 179 microm). VEGF release kinetics from scCO2-VEGF incorporated PLA monolith scaffolds showed a cumulative release of VEGF (2837 +/- 761 rhog/ml) over a 21 day period in culture. In addition, VEGF encapsulated PLA scaffolds increased the blood vessel network in the CAM compared to controls; control, 24.8 +/- 9.6; VEGF/PLA, 44.1 +/- 12.1 (vessels/field). These studies demonstrate that the controlled release of growth factors encapsulated into three-dimensional PLA scaffolds can actively stimulate the rapid development of therapeutic neovascularisation to regenerate or engineer tissues.     

Survival and integration of tissue-engineered corneal stroma in a model of corneal ulcer

Tissue-engineered replacement of diseased or damaged tissue has become a reality for some types of tissue, such as skin and cartilage. Tissue-engineered corneal stroma represents a promising concept to overcome the limitations of cornea replacement with allograft. In this study, porcine cornea was decellularized by a series of extraction methods, and the in vivo biocompatibility of the scaffold was measured subcutaneously in rabbits (n = 8). These were not acutely rejected and no abscesses were observed by hematoxylin and eosin staining at the 8th week, indicating that the scaffolds had good biocompatibility. To investigate the potential value of clinical applications, rabbit stromal keratocytes were implanted onto decellularized scaffolds to fabricate tissue-engineered corneal stroma. Allograft, tissue-engineered corneal stroma, or scaffolds were implanted into a model of corneal ulcer. The survival and reconstruction of corneal transplantation were morphologically evaluated by light and electron microscopy until the 32nd week after implantation. Experiments involving transplantation indicated that the epithelial and stromal defect healed quickly, with improvement in corneal clarity. The integration of the graft was accompanied by neurite ingrowth from the host tissue. By 16 weeks after transplantation, the cornea had gradually regained an intact state similar to that of normal cornea. Our results demonstrate that the tissue-engineered corneal stroma with allogenetic cells is a promising therapeutic method for corneal injury. This study was supported by the Nature Science Foundation of China (project no. 30572046) and the Development of High and New Science and Technology (863 Project) of China (2002AA205041, 2005AA205241).     

Comparison of the synthetic biodegradable polymers, polylactide (PLA), and polylactic-co-glycolic acid (PLGA) as scaffolds for artificial cartilage

Chondrocytes are easily de-differentiated when cultured in monolayer, and tissue-engineered cartilage can be generated by seeding chondrocytes onto three-dimensional porous synthetic biodegradable polymers. In this study, we investigated the biochemical and molecular aspects of chondrocytes in a monolayer-culture system and selected the optimal subculture passages based on their de-differentiation. We also compared two commonly used synthetic biodegradable polymers, polylactide (PLA), and polylactic-co-glycolic acid (PLGA), for their suitability as scaffolds for artificial cartilage. De-differentiated chondrocytes were observed after two passages. These results suggested that the first cell passage was optimal for seeding as only a few chondrocytes secreted extracellular matrix components to form homogeneously compact cartilage. Substantially increased glycosaminoglycan and total collagen levels revealed that PLGA scaffolds were a better option for inducing cartilage tissue formation compared to the PLA scaffolds. Histological and immunohistochemical results showed that chondrocytes seeded into PLGA retained their morphological phenotype to a greater extent than those seeded into PLA.     

仿生聚己内酯支架用于乳房组织工程的可行性研究

目的探讨聚己内酯（PCL）乳房形态支架用于组织工程乳房的构建的可能性。 方法通过熔融沉积3D打印制备形态仿生的PCL支架,测量其机械性能,并使用新西兰大白兔动物模型,皮下植入该PCL支架12周和18周后,利用核磁共振成像（MRI）观察支架内部新生组织分布情况,在组织学（HE、Masson及EVG染色）上评估支架内部的脂肪、纤维及血管的分布情况,并进一步使用qRT-PCR检测了12周时PCL支架内部组织的成脂相关基因（PPAR-γ、C/EBP-β、AP-2）、炎症相关基因TNF-α及巨噬细胞标记物F4-80的表达情况,同时使用凝胶渗透色谱法分析了PCL植入体内后平均分子量的变化。2组间均数比较采用独立样本t检验,多组间比较采用单因素方差分析,组间两两比较采用LSD-t检验,配对设计的均数比较采用配对t检验。 结果制备的PCL支架孔隙率为（85.30±1.12）%,压缩模量为（8.18±1.39）MPa,植入新西兰大白兔动物模型皮下12周后,MRI影像学显示脂肪组织已由支架周围向内部侵入,HE、Masson及EVG染色同样在该支架边缘观察到部分新生脂肪组织及血管,而支架内部则以疏松排列的纤维组织为主;与原生脂肪比较,12周PCL支架内组织的基因表达分析成脂相关基因C/EBPβ表达水平（2.32±0.28比1.00±0.02）升高,而巨噬细胞标记物F4/80表达（0.80±0.12比1.00±0.03）降低（P均< 0.01）;18周后,HE染色证实支架内部已充满脂肪组织。基因表达证实,与原生脂肪比较,支架内部组织C/EBP-β （3.30±0.63比1.00±0.02）,PPAR-γ （1.81±0.71比0.99±0.02）及AP-2表达水平（1.38±0.16比1.01±0.01）升高（P均< 0.01）;而TNF-α（0.50±0.15比1.00±0.01）及F4/80表达水平（0.52±0.09比1.00±0.03）均降低（P均< 0.001）。而植入体内PCL支架的分子量（M_n）在18周内变化不大[（65.04±2.24）kDa比（64.20±4.09） kDa]。 结论PCL支架具有较好的生物相容性,可用于组织工程乳房的构建,该新西兰大白兔动物模型的建立有利于乳房组织工程的进一步临床转化。     

Mesenchymal stem cell responses to bone-mimetic electrospun matrices composed of polycaprolactone, collagen I and nanoparticulate hydroxyapatite

The performance of biomaterials designed for bone repair depends, in part, on the ability of the material to support the adhesion and survival of mesenchymal stem cells (MSCs). In this study, a nanofibrous bone-mimicking scaffold was electrospun from a mixture of polycaprolactone (PCL), collagen I, and hydroxyapatite (HA) nanoparticles with a dry weight ratio of 50/30/20 respectively (PCL/col/HA). The cytocompatibility of this tri-component scaffold was compared with three other scaffold formulations: 100% PCL (PCL), 100% collagen I (col), and a bi-component scaffold containing 80% PCL/20% HA (PCL/HA). Scanning electron microscopy, fluorescent live cell imaging, and MTS assays showed that MSCs adhered to the PCL, PCL/HA and PCL/col/HA scaffolds, however more rapid cell spreading and significantly greater cell proliferation was observed for MSCs on the tri-component bone-mimetic scaffolds. In contrast, the col scaffolds did not support cell spreading or survival, possibly due to the low tensile modulus of this material. PCL/col/HA scaffolds adsorbed a substantially greater quantity of the adhesive proteins, fibronectin and vitronectin, than PCL or PCL/HA following in vitro exposure to serum, or placement into rat tibiae, which may have contributed to the favorable cell responses to the tri-component substrates. In addition, cells seeded onto PCL/col/HA scaffolds showed markedly increased levels of phosphorylated FAK, a marker of integrin activation and a signaling molecule known to be important for directing cell survival and osteoblastic differentiation. Collectively these results suggest that electrospun bone-mimetic matrices serve as promising degradable substrates for bone regenerative applications.     

Numerical simulation of fluid field and in vitro three-dimensional fabrication of tissue-engineered bones in a rotating bioreactor and in vivo implantation for repairing segmental bone defects

In this paper, two-dimensional flow field simulation was conducted to determine shear stresses and velocity profiles for bone tissue engineering in a rotating wall vessel bioreactor (RWVB). In addition, in vitro three-dimensional fabrication of tissue-engineered bones was carried out in optimized bioreactor conditions, and in vivo implantation using fabricated bones was performed for segmental bone defects of Zelanian rabbits. The distribution of dynamic pressure, total pressure, shear stress, and velocity within the culture chamber was calculated for different scaffold locations. According to the simulation results, the dynamic pressure, velocity, and shear stress around the surface of cell-scaffold construction periodically changed at different locations of the RWVB, which could result in periodical stress stimulation for fabricated tissue constructs. However, overall shear stresses were relatively low, and the fluid velocities were uniform in the bioreactor. Our in vitro experiments showed that the number of cells cultured in the RWVB was five times higher than those cultured in a T-flask. The tissue-engineered bones grew very well in the RWVB. This study demonstrates that stress stimulation in an RWVB can be beneficial for cell/bio-derived bone constructs fabricated in an RWVB, with an application for repairing segmental bone defects.     

Investigation of biodegradability and cellular activity of PCL/PLA and PCL/PLLA electrospun webs for tissue engineering applications

Biodegradability and cellular activity are key performance indicators that should be prioritized for tissue engineering applications. Biopolymer selection, determination of necessary structural properties, and their synergistic interactions play an active role in obtaining the expected biodegradability and biological activity from scaffolds. In this study, it is aimed to produce electrospun webs with improved biocompatibility by blending polycaprolactone (PCL) with polylactic acid (PLA) and poly-l -lactide (PLLA), and examine the effect of biopolymer selection and blend ratio on the biodegradability and cellular activity of surfaces. In this context, fibrous webs are produced from PCL/PLA and PCL/PLLA blends with a weight ratio of 80/20 and 50/50 and pure polymers of PCL, PLA, and PLLA by electrospinning method and subjected to morphological and biological analyses. The biodegradation tests are carried out hydrolytically while the cell viability and cell proliferation analyses are performed with adult human primary dermal fibroblasts and human umbilical endothelial cells (HUVECs). The results show that the fiber diameters of the fabricated webs ranged from 0.747 to 1.685 μm. At the end of the 5th month, it is observed that the biodegradation rates of the webs blended 50% with PLA and PLLA, in comparison to PCL ones, increase from 3.7% to 13.33% and 7.69%, respectively. On the other hand, cell culture results highlight that the addition of 20% PLA and PLLA improves the cellular activity of both cell types, but increased PLA or PLLA ratio in PCL webs has a negative effect as it makes the structure stiff and brittle.