聚己内酯在组织工程中的应用进展

聚己内酯(PCL)以其具有的良好生物相容性及其力学特点,在组织工程领域已经成为主要的生物支架材料之一。利用生物支架材料,组织工程的目的是对组织、器官的丧失或功能障碍进行修复与重建。本文综述了对生物支架材料聚己内酯(PCL)的研究进展以及其在组织工程中的应用。     

锶纳米纤维能促进骨组织再生

为了探究锶纳米纤维在骨组织再生中的作用机制,本研究通过静电纺丝来制备聚合物纳米复合材料工程支架,促进骨组织再生。将碳酸锶纳米粒子(nSrCO3)以10%和15%重量比添加到聚己酸内酯(PCL)中,做成纤维直径在300～500 nm范围内的纳米复合材料纤维支架(PCL+10%SrCO3和PCL+15%SrCO3),掺入nSrCO3后降低了纤维支架的结晶度和弹性模量,复合PCL+15%SrCO3支架可在4 d内释放出高达58 ppm的Sr2+离子。细胞研究证实,体外使用的含有15%n Sr CO3的复合支架增强了人间充质干细胞的增殖。在PCL+15%SrCO3中,最小沉积量显著增加达约4倍,促进了骨形成。在PCL+15%SrCO3纤维中,成骨标志物如BMP-2和Runx2的mRNA和蛋白的高表达也可以证明锶纳米纤维能促进骨形成。本研究为研究锶纳米纤维在促进骨组织再生中的运用提供了一定的参考价值。     

可降解组织工程血管支架成功用于犬股动脉移植

目的采用可降解的聚己内酯接枝肝素材料,负荷b-FGF(碱性成纤维细胞生长因子),体外构建的小口径组织工程血管,完成犬的股动脉移植动物实验。方法利用可降解的聚己内酯接枝肝素材料,电纺丝技术制备组织工程血管支架,并对支架负荷b-FGF生长因子,并进行材料的内皮细胞粘附实验。将体外构建的小口径组织工程血管,完成犬的股动脉移植动物实验,观察通畅率和移植术后组织工程血管的改变。结果可降解聚己内酯接枝肝素材料支架,负荷细胞生长因子(b-FGF),利于内皮细胞粘附。构建的组织工程血管进行体外动物实验构建,3个月移植物通畅率好,移植后取材,有新生内膜迁移和胶原纤维浸入。结论利用可降解聚己内酯接枝肝素材料构建小口径支架,初步符合构建组织工程血管支架的要求。     

Ⅰ型胶原/聚己内酯/凹凸棒石复合支架材料体外诱导成骨的研究

目的:研究Ⅰ型胶原(ColⅠ)/聚己内酯(PCL)/凹凸棒石(ATP)复合支架材料的生物相容性及体外骨诱导性。方法:采用溶液浇铸-粒子滤沥法制备三种不同ATP含量(0% wt、10% wt、30% wt)的ColⅠ/PCL/ATP复合支架材料;将D1细胞与三种支架材料共培养,扫描电镜、鬼笔环肽和H&E染色、CCK-8法评价支架材料的生物相容性;D1细胞复合三种支架材料培养7天、14天、21天后RT-qPCR检测其成骨相关基因(Runx-2、Osterix、ALP、Col I、OPN、OC)的相对表达量,分别评价比较三种支架材料的成骨诱导效应。结果:SEM、鬼笔环肽和H&E染色显示D1细胞在三种支架材料表面均呈现良好的黏附;CCK-8结果显示,细胞在ATP含量30% wt的支架材料上增殖率显著高于其他两组,RT-qPCR检测结果显示,与0% wt、10% wt ATP相比,30% wt ATP组的Runx-2相对表达量在7天时显著升高, 14天、21天降低;ALP相对表达量在14天时显著升高,21天时显著降低;Osterix、Col I、OPN、OC的相对表达量随时间和ATP剂量的增加显著上调(P<0.05)。结论:ColⅠ/PCL/ATP复合支架材料具有良好的生物相容性及骨诱导性,有望成为一种理想的骨组织工程支架材料。     

羟基磷灰石/柞蚕丝素（HA/TSF骨仿生纳米纤维的生物学性能研究

目的：柞蚕丝素（tussah silk fibroin,TSF）和羟基磷灰石（hydroxyapatite,HA）均具有良好的生物活性和生物相容性,是组织工程研究的热点i,但结构单一及微米级的材料所表现出的性能简单,不能满足人们对生物材料支架性能的要求,本课题将两者按不同比例进行复合,探讨不同皮芯比例羟基磷灰石／柞蚕丝素（HA／TSF）的骨仿生纳米纤维的生物学性能。方法：首先利用同轴静电纺丝技术,以TSF水溶液为皮,HA水溶液为芯,制备不同皮芯比例的HA／TSF骨仿生纳米纤维,然后将人成骨肉瘤细胞（MG-63）种植在不同皮芯比例的HA／TSF纳米纤维上。在不同的时间点分别通过倒置显微镜、扫描电镜观察细胞形态学变化;通过四甲基偶氮噻唑蓝比色（Four methyl azo thiazole blue colorimetric, MTT）法、碱性磷酸酶（alkaline phosphatase,ALP）活性检测法观察细胞在材料表面的增殖和分化,从多角度来评价材料的生物学性能。结果：通过形态学观察,SEM观察以及MTT检测,发现除空白对照组外,各组样品均显示良好的生物相容性,均能促进细胞的黏附、增殖,尤以HA／TSF为2：1时最明显;通过MG-63细胞的ALP活性检测,发现当HA／TSF比例为2：1时,最能促进细胞ALP活性的表达,有利于诱导成骨细胞的分化。结论：皮芯结构的HA／TSF骨仿生纳米纤维具有良好的生物学性能,且二者在自然界来源丰富,价格便宜,为临床骨组织缺损修复的应用奠定了一定的实验基础     

BMSCs在PLGA-[ASP-PEG]基质材料表面粘附及增殖的研究

目的：探讨大鼠骨髓间充质干细胞BMSCs在聚丙交酯/乙交酯/天冬氨酸-聚乙二醇三嵌段多元共聚物 PLGA-[ASP-PEG]表面粘附、增殖的情况,为组织工程学体外诱导种子细胞生长提供新的生物材料。方法：在PLGA支架材料中引入聚乙二醇（PEG）和含有多个功能位点的天冬氨酸（ASP）,制成PLGA-[ASP-PEG]高分子支架材料。 将PLGA-[ASP-PEG]支架材料与BMSCs复合培养,以未改性的PLGA支架材料作对照,通过沉淀法、MTT法和考马斯亮蓝法分别检测BMSCs的粘附和增殖变化;扫描电镜观察黏附细胞的形态。结果 BMSCs在PLGA-[ASP-PEG]材料表面帖壁生长,细胞数目明显多于单纯PLGA组。细胞粘附率检测显示：改性后的PLGA-[ASP-PEG]表面BMSCs的粘附性能和增殖能力明显高于对照组,P＜0.05。MTT比色试验,BMSCs在三嵌段材料上培养20d后,吸光值A=1.336,约为对照组0.780的两倍。细胞内蛋白总量间接反映细胞黏附及增殖情况。培养12d时,在PLGA-[ASP-PEG]材料组细胞的蛋白含量为66.44μg/孔,单纯PLGA组为41.23μg/孔,间接说明了三嵌段材料生物相容性好,细胞黏附力强的特点。结论PLGA-[ASP-PEG]能促进组织工程种子细胞在骨基质材料表面的黏附、增殖并能较好地保持细胞的形态。     

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。     

复合红景天苷支架材料对大鼠骨髓间充质干细胞的影响

探讨复合红景天苷微球的胶原蛋白材料支架对大鼠骨髓间充质干细胞的影响及作用。将红景天苷制作成微球复合到胶原蛋白中,扫描电镜观察材料支架的表征,接种大鼠骨髓间充质干细胞后扫描电镜观察细胞与材料的黏附性,CCK-8法测细胞在材料上的增殖情况,HE染色检测细胞在材料上的增殖及形态,S100免疫荧光化学法检测干细胞向神经细胞的分化情况。结果显示,细胞接种到材料上,在材料上黏附并生长。同种材料,随着时间的延长,材料上的细胞显著增殖(P0.05)。神经细胞标志性蛋白S100表达为阳性。复合红景天苷微球的胶原蛋白具有良好的生物相容性,红景天苷微球不影响细胞在材料上的增殖,且可有效诱导大鼠间充质干细胞向神经细胞分化。     

骨髓基质细胞与交联明胶-聚羟基丁酸酯膜的生物相容性研究

目的研究生物材料交联明胶-聚羟基丁酸酯膜与骨髓基质细胞的生物相容性,探讨新型材料在骨组织工程中的应用前景。方法体外培养兔骨髓基质细胞,分别接种于G-PHB(交联明胶-聚羟基丁酸酯)、PHB(聚羟基丁酸酯)和G(交联明胶)材料膜片。采用MTT法检测细胞增殖活性,体视学方法检测细胞粘附能力,荧光双染法检测细胞完整性,扫描电镜观察细胞-材料界面。结果MTT检测发现G-PHB组增殖活性最强,而且表现为最佳的细胞粘附特性,与对照组比较差异有显著性意义。各组细胞完整性分析没有发现显著性差异。扫描电镜观察显示,G-PHB组细胞粘附及铺展良好,优于其他各组。结论交联后的生物降解膜材料G-PHB与BMSCs细胞的体外相容性明显优于单纯膜材料PHB和明胶,在骨组织工程学领域具有良好的研究价值和应用潜力。     

蚕丝纳米纤维在组织工程领域的研究进展

在组织工程中最为关键的是提供理想的生物材料支架,而结构和功能仿生是组织工程支架最重要的性能要求,但仿生组织工程支架的设计与构建必须由纳米纤维来实现.本文介绍蚕丝纳米纤维的性能特点,并通过国内外文献证实了家蚕丝素具有良好的生物相容性等优良特性,在组织工程领域广泛应用.然而,与家蚕丝相比,野蚕丝更利于细胞的黏附、生长,因此我们推测利用我国特有的野蚕丝素进行静电纺丝制取纳米纤维,有望在生物医学领域获得新的进展.     

Antioxidant effects of chrysin-loaded electrospun nanofibrous mats on proliferation and stemness preservation of human adipose-derived stem cells

An ideal biomaterial in regenerative medicine should be able to regulate the stem cell proliferation without the loss of its pluripotency. Chrysin (Chr) is a naturally occurring flavone with a wide spectrum of biological functions including anti-inflammatory and anti-oxidant properties. The present study describes the influence of Chr-loaded nanofibrous mats on the regulation of proliferation and stemness preservation of adipose-derived stem cells (ADSCs). For this purpose, Chr-loaded poly (ε-caprolactone)/poly (ethylene glycol) (PCL/PEG) nanofibrous mats were produced via electrospinning process and the successful fabrication of these bioactive mats was confirmed by field emission scanning electron microscopy (FE-SEM) and fourier transform infrared spectroscopy. ADSCs were seeded on the nanofibers and their morphology, viability, and stemness expression were analyzed using FE-SEM, MTT, and qPCR assays after 2 weeks of incubation, respectively. The results display that ADSCs exhibit better adhesion and significantly increased viability on the Chr-loaded PCL/PEG nanofibrous mats in relative to the PCL/PEG nanofibers and tissue culture polystyrene. The greater viability of ADSCs on Chr based nanofibers was further confirmed by higher expression levels of stemness markers Sox-2, Nanog, Oct-4, and Rex-1. These findings demonstrate that Chr-loaded PCL/PEG electrospun nanofibrous mats can be applied to improve cell adhesion and proliferation while concurrently preserving the stemness of ADSCs, thus representing a hopeful potential for application in stem cell therapy strategies.     

Electrospun Poly(L-lactide)/Poly(ε-caprolactone) Blend Nanofibrous Scaffold: Characterization and Biocompatibility with Human Adipose-Derived Stem Cells

The essence of tissue engineering is the fabrication of autologous cells or induced stem cells in naturally derived or synthetic scaffolds to form specific tissues. Polymer is thought as an appealing source of cell-seeded scaffold owing to the diversity of its physicochemical property and can be electrospun into nano-size to mimic natural structure. Poly (L-lactic acid) (PLLA) and poly (ε-caprolactone) (PCL) are both excellent aliphatic polyester with almost “opposite” characteristics. The controlling combination of PLLA and PCL provides varying properties and makes diverse applications. Compared with the copolymers of the same components, PLLA/PCL blend demonstrates its potential in regenerative medicine as a simple, efficient and scalable alternative. In this study, we electrospun PLLA/PCL blends of different weight ratios into nanofibrous scaffolds (NFS) and their properties were detected including morphology, porosity, degradation, ATR-FTIR analysis, stress-stain assay, and inflammatory reaction. To explore the biocompatibility of the NFS we synthesized, human adipose-derived stem cells (hASCs) were used to evaluate proliferation, attachment, viability and multi-lineage differentiation. In conclusion, the electrospun PLLA/PCL blend nanofibrous scaffold with the indicated weight ratios all supported hASCs well. However, the NFS of 1/1 weight ratio showed better properties and cellular responses in all assessments, implying it a biocompatible scaffold for tissue engineering.     

Fabrication of conductive fibrous scaffold for photoreceptor differentiation of mesenchymal stem cell

Conductive nanofibrous scaffolds with that can conduct electrical current have a great potential in neural tissue engineering. The purpose of this study was to survey effects of electrical stimulation and polycaprolactone/polypyrrole/multiwall carbon nanotube (PCL/PPY/MWCNTs) fibrous scaffold on photoreceptor differentiation of trabecular meshwork mesenchymal stem cells (TM-MSCs). PCL/PPY/MWCNTs scaffold was made by electrospinning method. TM-MSCs were seeded on PCL/PPY/MWCNTs scaffold and stimulated with a potential of 115 V/m. Scanning electron microscopy, transmission electron microscopy, and FT-IR were used to evaluate the fabricated scaffold. Immunofluorescence and quantitative real-time polymerase chain reaction were used to examine differentiated cells. Scanning electron microscopy, transmitting electron microscopy, and FT-IR confirmed the creation of the composite structure of fibers. RT-qPCR analysis showed that the expression of rhodopsin and peripherin genes in electrically stimulated cells were significantly higher (5.7- and 6.23-fold, respectively; p ≤ 0.05) than those with no electrical stimulation. Collectively, it seems that the combination of PCL/PPY/MWCNTs scaffold, as a suitable conductive scaffold, and electrical stimulation could be an effective approach in the differentiation of stem cells in retinal tissue engineering.     

Fabrication of chitosan/poly(caprolactone) nanofibrous scaffold for bone and skin tissue engineering

Chitosan/poly(caprolactone) (CS/PCL) nanofibrous scaffold was prepared by a single step electrospinning technique. The presence of CS in CS/PCL scaffold aided a significant improvement in the hydrophilicity of the scaffold as confirmed by a decrease in contact angle, which thereby enhanced bioactivity and protein adsorption on the scaffold. The cyto-compatibility of the CS/PCL scaffold was examined using human osteoscarcoma cells (MG63) and found to be non toxic. Moreover, CS/PCL scaffold was found to support the attachment and proliferation of various cell lines such as mouse embryo fibroblasts (NIH3T3), murine aneuploid fibro sarcoma (L929), and MG63 cells. Cell attachment and proliferation was further confirmed by nuclear staining using 4',6-diamidino-2-phenylindole (DAPI). All these results indicate that CS/PCL nanofibrous scaffold would be an excellent system for bone and skin tissue engineering.     

Epiblast stem cell subpopulations represent mouse embryos of distinct pregastrulation stages

Embryonic stem cells (ESCs) comprise at least two populations of cells with divergent states of pluripotency. Here, we show that epiblast stem cells (EpiSCs) also comprise two distinct cell populations that can be distinguished by the expression of a specific Oct4-GFP marker. These two subpopulations, Oct4-GFP positive and negative EpiSCs, are capable of converting into each other in?vitro. Oct4-GFP positive and negative EpiSCs are distinct from ESCs with respect to global gene expression pattern, epigenetic profile, and Oct4 enhancer utilization. Oct4-GFP negative cells share features with cells of the late mouse epiblast and cannot form chimeras. However, Oct4-GFP positive EpiSCs, which only represent a minor EpiSC fraction, resemble cells of the early epiblast and can readily contribute to chimeras. Our findings suggest that the rare ability of EpiSCs to contribute to chimeras is due to the presence of the minor EpiSC fraction representing the early epiblast.     

Adipose-derived stem cells-conditioned medium improved osteogenic differentiation of induced pluripotent stem cells when grown on polycaprolactone nanofibers

Considering that the common osteogenic growth factors cannot be transplanted with stem cells to the patients, many studies are underway to find a replacement for these factors. Recently, it has been determined that mesenchymal stem cell (MSC)-derived conditioned medium (CM) contains effective factors in the bone formation process. In the current study, the synergistic effect of adipose-derived MSC’s CM, and polycaprolactone (PCL) scaffold was investigated on the osteogenic differentiation potential of human induced pluripotent stem cells (iPSCs). After scaffold fabrication by electrospinning and characterization by scanning electron microscopy, iPSCs proliferation in the presence of CM, PCL, and both was evaluated using 3-[4,5-dimethylthiazol-2-yl]-2,5 diphenyl tetrazolium bromide. Then, iPSCs osteogenic differentiation was investigated while cultured on tissue culture plate and PCL under CM compared with the osteogenic medium using alizarin red staining, calcium content, alkaline phosphatase activity and gene and protein expression analysis. Proliferation rate of the iPSCs was increased while cultured under CM and its effect was synergistically enhanced by culture on PCL. Evaluation of the osteogenic markers was showed CM alone could induce osteogenic differentiation into the iPSCs and this potential was significantly increased while combined with PCL nanofibrous scaffold. According to the results, it was demonstrated that CM has an osteogenic induction property almost the same of the common osteogenic medium and it can also be used potentially with stem cells when transplant to the patients. CM can also help by prolonging cell survival at the site of the defect as well as accelerating healing process.     

Preparation and Characterization of Electrospun PLCL/Poloxamer Nanofibers and Dextran/Gelatin Hydrogels for Skin Tissue Engineering

In this study, two different biomaterials were fabricated and their potential use as a bilayer scaffold for skin tissue engineering applications was assessed. The upper layer biomaterial was a Poly(ε-caprolactone-co-lactide)/Poloxamer (PLCL/Poloxamer) nanofiber membrane fabricated using electrospinning technology. The PLCL/Poloxamer nanofibers (PLCL/Poloxamer, 9/1) exhibited strong mechanical properties (stress/strain values of 9.37±0.38 MPa/187.43±10.66%) and good biocompatibility to support adipose-derived stem cells proliferation. The lower layer biomaterial was a hydrogel composed of 10% dextran and 20% gelatin without the addition of a chemical crosslinking agent. The 5/5 dextran/gelatin hydrogel displayed high swelling property, good compressive strength, capacity to present more than 3 weeks and was able to support cells proliferation. A bilayer scaffold was fabricated using these two materials by underlaying the nanofibers and casting hydrogel to mimic the structure and biological function of native skin tissue. The upper layer membrane provided mechanical support in the scaffold and the lower layer hydrogel provided adequate space to allow cells to proliferate and generate extracellular matrix. The biocompatibility of bilayer scaffold was preliminarily investigated to assess the potential cytotoxicity. The results show that cell viability had not been affected when cocultured with bilayer scaffold. As a consequence, the bilayer scaffold composed of PLCL/Poloxamer nanofibers and dextran/gelatin hydrogels is biocompatible and possesses its potentially high application prospect in the field of skin tissue engineering.