静电纺丝的主要参数对ＰＬＧＡ纤维支架形貌和纤维直径的影响

目的以聚乳酸-羟基乙酸共聚物(PLGA)为材料,采用静电纺丝方法制备纤维支架,考察制备参数对纤维支架结构及纤维直径的影响规律。方法以四氢呋喃(THF)和N,N-二甲基甲酰胺(DMF)的混合液为溶剂,调节PLGA溶液浓度、流量及电场强度分别制备了具有不同表面形貌的纤维支架。通过扫描电镜(SEM)观察了纺丝溶液的浓度、流量及电场强度对纤维形貌和直径的影响。同时在制备的PLGA纤维支架上接种了人的真皮成纤维细胞,并对细胞在PLGA支架上的黏附和增殖情况进行了研究,从而来评价支架材料的细胞相容性。结论结果表明,随着纺丝溶液浓度的增加,纤维直径逐渐增大,纤维直径的分布也随之增大。随着流量的增加,纤维直径略有增大。随着电场强度的增大,纤维直径没有明显的变化。但是电压和浓度的增大有助于减少珠丝的产生。体外细胞培养实验证明,制备的PLGA纤维支架能支持细胞正常的黏附和增殖活动。     

担载血管生长因子的乳液法纤维用于血管再生的研究

目的:制备担载血管生长因子(VEGF)的乳液法静电纺丝纤维膜,对其开展一系列表征,从而研究其血管再生的潜能。方法:通过W/O乳液法制备担载VEGF的静电纺丝纤维膜,并对其形态、力学性质进行表征。用VEGF ELISA分析方法对其体外释放动力学进行研究。运用CCK-8法检测乳液法静电纺丝纤维膜中VEGF的活性变化。结果:乳液法静电纺丝纤维膜呈现连通的三维网状结构,平均直径为1μm,模拟了细胞外基质(ECM),最大拉伸应力为3.03±0.66 M Pa,具有良好的抗拉伸能力,能够支持细胞的生长。乳液法纤维膜中VEGF在体外累积释放了14天,总释放量超过20000 pg,达到血管再生的有效浓度。CCK-8结果显示,乳液法纤维膜中的VEGF仍然保持较高的蛋白活性。结论:担载VEGF的乳液法静电纺丝纤维膜能够缓释出活性的蛋白,具有血管再生的潜能。     

静电纺丝纳米纤维体外释放与蛋白活性的研究

目的:通过选择不同的模型蛋白,探讨准确的研究静电纺丝纳米纤维支架的体外释放和快速的测定蛋白活性的方法.方法:通过O/W乳液法静电纺丝制备纳米纤维,并用扫描电镜对纳米纤维表面进行了表征.以GM-CSF为模型蛋白,采用ELISA双抗体夹心法考察纤维的体外释放行为;以BSA为模型蛋白,用SEC-H-PLC比较纤维制备前后蛋白的聚集情况;以β-半乳糖苷酶为模型蛋白,用ONPG法比较纤维制备前后酶的催化活性.结果:纤维表面平滑,直径均一,呈现互相连通的三维网状结构.纤维在5天内释放90％以上;纤维中回收的BSA单体比例为66.53％;β-半乳糖苷酶在纤维中的催化活性保持原活性的3.37％.结论:通过选择不同的模型蛋白,能够准确的测定静电纺丝纤维的体外释放,快速的考察纤维中的蛋白活性,对于更好的研究蛋白药物纳米纤维支架具有重要的参考价值.     

肌腱组织工程支架与种子细胞研究进展

目的:综述肌腱组织工程支架材料、细胞来源、制备技术及体外构建的研究进展.方法:查阅近期肌腱组织工程研究的相关文献,对组织工程肌腱支架的材料来源、制备技术,复合细胞种类,体外构建力学刺激等进行分析、归纳.结果:肌腱组织工程支架材料有天然材料、人工合成材料及复合材料等;制备技术包括静电纺丝和编织法等;其中支架材料的表面修饰是组织工程化肌腱构建的重要环节.与肌腱材料进行复合的种子细胞有肌腱细胞、骨髓间充质干细胞及成纤维细胞等.结论:复合材料是近年肌腱组织工程支架材料研究的重点,静电纺丝技术是一种具有潜力的支架制备技术,支架材料的表面修饰可促进细胞在支架上的黏附及肌腱的形成,种子细胞的研究仍是肌腱组织工程发展的瓶颈,周期性张力的存在为组织工程化肌腱的形成创造了条件.     

静电纺丝制备担载神经生长因子的聚乳酸纤维的工艺研究

目的:研究担载神经生长因子(NGF)的聚乳酸纤维乳液法静电纺丝的制备工艺,从电压、溶液浓度等工艺条件进行探索,通过扫描电镜对纤维的形态结构进行观察,旨在找到最佳纺丝制备条件,并观察该条件下纤维的体外释放行为和细胞活性。方法:将NGF水溶液分散于聚乳酸(PLLA)溶液中,通过W/O乳液法制备静电纺丝纤维。分别从电压8 k V、10 k V、12 k V,浓度梯度90mg/m L、100 mg/m L、110 mg/m L进行静电纺丝纤维的制备,对纤维的形态等进行表征。使用ELISA对NGF体外释放动力学进行检测,用Alamer Blue试剂考察纤维释放液对于PC12悬浮细胞增殖的影响。结果:浓度和电压对电纺纤维制备影响很大。当浓度过大时,易堵塞纺丝喷头且纤维弯曲,过小时纤维粗细差异较大。电压过大或过小时纤维弯曲情况严重,甚至出现缠绕现象。当浓度为100 mg/m L,电压为10 k V时制备的乳液法静电纺丝聚乳酸纤维直径粗细均匀,具有较好形态。在该条件下的制备的纤维NGF体外有效释放13天,释放液可以促进PC12细胞的增殖。结论:担载NGF的聚乳酸纤维乳液法最佳静电纺丝制备条件为:PLLA溶液浓度100 mg/m L、电压10 k V,该条件下制备的担载NGF的聚乳酸纤维体外释放可累计释放13天,其释放液可有效促进PC12细胞的增殖,为进一步研究担载NGF的聚乳酸纤维导管奠定了一定的工艺基础。     

NGF电纺纤维的体外缓释研究

目的:研究担载神经生长因子(NGF)的静电纺丝纤维的表征,考察NGF电纺纤维对于周围神经修复的效果。方法:将NGF水溶液分散于PLLA溶液,通过W/O乳液法制备静电纺丝纤维,对纤维的形态、力学性能等进行表征,Elisa方法测定NGF的体外释放动力学,Alamer Blue法检测试剂来考察纤维释放液对于PC12细胞增殖的影响。结果:NGF电纺纤维具备良好的形态和力学性质,直径为500-900 nm,纤维具备三维多孔结构。纤维的最大拉伸应力为2.50±0.41 MPa。电纺纤维中NGF在体外可有效释放9天,累积释放量接近3000 pg。细胞活性实验结果显示,第1、3、5、7天释放液的荧光强度与对照组相比有显著差异。结论:担载NGF的乳液法静电纺丝纤维有促进缺损周围神经修复的潜质。     

组织工程支架制备中超临界CO2技术的应用*

作为组织工程研究中三大要素之一,组织工程支架可为细胞的附着、迁移和增殖提供理想的环境。传统的组织工程支架制备方法,如粒子沥滤法、相分离法及静电纺丝法等在理论和技术上已较为成熟,但由于大多需要有机溶剂的参与,在制备过程中仍存在有机溶剂难以去除,以及支架孔洞难以控制、连通性较差等问题。超临界二氧化碳(supercritical carbon dioxide,SC-CO₂)密度近似液体,黏度和扩散系数近似气体,具有流动性强、溶解能力大、传热效率高等特殊的理化性质,与传统工艺相结合,可在绿色温和的反应体系中有效规避上述问题,在组织工程支架制备及药物负载方面具有广阔前景。     

丝素蛋白/壳聚糖复合材料在组织工程中应用的研究进展

丝素蛋白(silk fibroin,SF)和壳聚糖(chitosan,CS)具有良好的生物相容性和可降解性,然而单一组分的SF和CS支架材料的诸多缺点限制了其在组织工程研究中的应用。SF/CS复合材料克服单一组分SF和CS支架的缺点,具有力学性能优良、可塑性好、孔隙率及孔径可调和组分优势互补等特点。多种方法制备的SF/CS复合材料(微米/纳米颗粒、膜、纳米纤维、水凝胶和三维多孔支架)已用于骨、软骨、皮肤、神经、脂肪、心脏和角膜等组织工程或组织损伤修复的研究中。目前,国内外对于SF/CS复合材料在组织工程中应用的研究尚处于起步阶段。主要对SF/CS复合材料的特点、制备方法以及在多种组织工程中应用的研究现状进行了简要介绍。     

一种具有空腔结构的高分子超细纤维的制备及应用研究

目的:制备一种具有空腔结构的高分子超细纤维并研究其相关性质,探索其应用。方法:结合静电纺丝技术和微流控技术,制备出具有空腔结构的聚乳酸(PLA)超细纤维,并使用荧光显微镜、扫描电子显微镜、透射电子显微镜等手段进行结构表征;采用甘油铜分光光度法、Alamar-Blue法间接检测了纤维膜的甘油含量和细胞毒性,并考察了其吸水率相较于普通实心纤维膜的变化;将PEI-质粒复合物载入纤维的空腔结构中,通过细胞转染实验验证了此纤维膜在运载质粒方面的应用。结果:纤维平均直径在1μm左右,内部均匀分布着椭圆形空腔。该纤维膜中甘油占比38.99%,吸水率为普通实心PLA纤维膜的近2倍。纤维膜与内皮细胞5天的共培养中,没有明显的细胞毒性。细胞转染检测结果证明了纤维空腔部分能有效运载质粒复合物并保证其生物活性。结论:静电纺丝技术和微流控技术有效结合,成功制备出具有空腔结构的新型高分子超细纤维,展现出了区别于普通纤维的独特性质和应用。     

担载b-FGF的PLGA微球复合明胶支架的体外释放研究

目的:研究担载碱性成纤维细胞生长因子(b-FGF)微球复合明胶支架的外形特征、孔径、孔隙率及体外释放动力学,以期构建具有缓释功能、高孔隙率的担载细胞因子的新型复合明胶支架。方法:本文利用冷冻相分离法和S/O/W法先将b-FGF水溶液包裹于PLGA微球中,然后埋置于明胶溶液中制备为多孔复合明胶支架。分别对微球的形态和复合明胶支架的基本形态、孔径、孔隙率进行表征,通过Elisa法测定b-FGF在复合明胶支架中的体外释放行为。结果:制备成形态良好的三维复合明胶支架,其孔隙率为82.90%±1.45%,孔径范围为150~300μm,复合明胶支架中b-FGF在体外缓慢释放20余天。结论:担载蛋白微球复合明胶支架不仅满足组织工程支架的要求,还能有效缓释细胞因子,为细胞和组织生长提供良好的微环境,为进一步应用于组织工程领域提供了可能。     

Electrospun poly(epsilon-caprolactone) microfiber and multilayer nanofiber/microfiber scaffolds: characterization of scaffolds and measurement of cellular infiltration

The physical and spatial architectural geometries of electrospun scaffolds are important to their application in tissue engineering strategies. In this work, poly(epsilon-caprolactone) microfiber scaffolds with average fiber diameters ranging from 2 to 10 microm were individually electrospun to determine the parameters required for reproducibly fabricating scaffolds. As fiber diameter increased, the average pore size of the scaffolds, as measured by mercury porosimetry, increased (values ranging from 20 to 45 microm), while a constant porosity was observed. To capitalize on both the larger pore sizes of the microfiber layers and the nanoscale dimensions of the nanofiber layers, layered scaffolds were fabricated by sequential electrospinning. These scaffolds consisted of alternating layers of poly(epsilon-caprolactone) microfibers and poly(epsilon-caprolactone) nanofibers. By electrospinning the nanofiber layers for different lengths of time, the thickness of the nanofiber layers could be modulated. Bilayered constructs consisting of microfiber scaffolds with varying thicknesses of nanofibers on top were generated and evaluated for their potential to affect rat marrow stromal cell attachment, spreading, and infiltration. Cell attachment after 24 h did not increase with increasing number of nanofibers, but the presence of nanofibers enhanced cell spreading as evidenced by stronger F-actin staining. Additionally, increasing the thickness of the nanofiber layer reduced the infiltration of cells into the scaffolds under both static and flow perfusion culture for the specific conditions tested. The scaffold design presented in this study allows for cellular infiltration into the scaffolds while at the same time providing nanofibers as a physical mimicry of extracellular matrix.     

Electrospun fibrous mats with high porosity as potential scaffolds for skin tissue engineering

Diffusional limitations of mass transport have adverse effects on engineering tissues that normally have high vascularity and cellularity. The current electrospinning method is not always successful to create micropores to encourage cell infiltration within the scaffold, especially when relatively large-sized pores are required. In this study, a slow rotating frame cylinder was developed as the collector to extend the pore size and increase the porosity of electrospun fibrous scaffolds. Fibrous mats with porosity as high as 92.4% and average pore size of 132.7 microm were obtained. Human dermal fibroblasts (HDFs) were seeded onto these mats, which were fixed on a cell-culture ring to prevent the shrinkage and contraction during the incubation. The viability test indicated that significantly more HDFs were generated on highly porous fibrous mats. Toluidine blue staining showed that the highly porous scaffold provided mechanical support for cells to maintain uniform distribution. The cross-section observations indicated that cells migrated and infiltrated more than 100 microm inside highly porous fibrous mats after 5 d incubation. The immunohistochemistry analysis demonstrated that cells began secreting collagen, which is the main constituent of extracellular matrix. It is supposed that highly porous electrospun fibrous scaffolds could be constructed by this elaboration and may be used for skin tissue engineering.     

Combining electrospun scaffolds with electrosprayed hydrogels leads to three-dimensional cellularization of hybrid constructs

A common problem in the design of tissue engineered scaffolds using electrospun scaffolds is the poor cellular infiltration into the structure. To tackle this issue, three approaches to scaffold design using electrospinning were investigated: selective leaching of a water-soluble fiber phase (poly ethylene oxide (PEO) or gelatin), the use of micron-sized fibers as the scaffold, and a combination of micron-sized fibers with codeposition of a hyaluronic acid-derivative hydrogel, Heprasil. These designs were achieved by modifying a conventional electrospinning system with two charged capillaries and a rotating mandrel collector. Three types of scaffolds were fabricated: medical grade poly(epsilon-caprolactone)/collagen (mPCL/Col) cospun with PEO or gelatin, mPCL/Col meshes with micron-sized fibers, and mPCL/Col microfibers cosprayed with Heprasil. All three scaffold types supported attachment and proliferation of human fetal osteoblasts. However, selective leaching only marginally improved cellular infiltration when compared to meshes obtained by conventional electrospinning. Better cell penetration was seen in mPCL/Col microfibers, and this effect was more pronounced when Heprasil regions were present in the structure. Thus, such techniques could be further exploited for the design of cell permeable fibrous meshes for tissue engineering applications.     

应用于组织工程支架制备的电纺技术

组织工程技术为修复病损的组织和器官提供了一种新的途径,在组织工程中,细胞支架起着支撑细胞生长、引导组织再生、控制组织结构和释放活性因子等作用。针对电纺技术的新发展和细胞支架的新理念,综述了国内外利用电纺技术制备细胞支架的工艺条件、制备方法、组织细胞培养等方面的研究进展,并结合作者所在研究团队的研究工作提出了对未来电纺技术在组织工程中应用的研究重点和发展方向的认识。     

Fabrication of a multi-layer three-dimensional scaffold with controlled porous micro-architecture for application in small intestine tissue engineering

Various methods can be employed to fabricate scaffolds with characteristics that promote cell-to-material interaction. This report examines the use of a novel technique combining compression molding with particulate leaching to create a unique multi-layered scaffold with differential porosities and pore sizes that provides a high level of control to influence cell behavior. These cell behavioral responses were primarily characterized by bridging and penetration of two cell types (epithelial and smooth muscle cells) on the scaffold in vitro. Larger pore sizes corresponded to an increase in pore penetration, and a decrease in pore bridging. In addition, smaller cells (epithelial) penetrated further into the scaffold than larger cells (smooth muscle cells). In vivo evaluation of a multi-layered scaffold was well tolerated for 75 d in a rodent model. This data shows the ability of the components of multi-layered scaffolds to influence cell behavior, and demonstrates the potential for these scaffolds to promote desired tissue outcomes in vivo.     

Hybrid chitosan–ß‐glycerol phosphate–gelatin nano‐/micro fibrous scaffolds with suitable mechanical and biological properties for tissue engineering

Scaffold‐based tissue engineering is considered as a promising approach in the regenerative medicine. Graft instability of collagen, by causing poor mechanical properties and rapid degradation, and their hard handling remains major challenges to be addressed. In this research, a composite structured nano‐/microfibrous scaffold, made from a mixture of chitosan–ß‐glycerol phosphate–gelatin (chitosan–GP–gelatin) using a standard electrospinning set‐up was developed. Gelatin–acid acetic and chitosan ß‐glycerol phosphate–HCL solutions were prepared at ratios of 30/70, 50/50, 70/30 (w/w) and their mechanical and biological properties were engineered. Furthermore, the pore structure of the fabricated nanofibrous scaffolds was investigated and predicted using a theoretical model. Higher gelatin concentrations in the polymer blend resulted in significant increase in mean pore size and its distribution. Interaction between the scaffold and the contained cells was also monitored and compared in the test and control groups. Scaffolds with higher chitosan concentrations showed higher rate of cell attachment with better proliferation property, compared with gelatin‐only scaffolds. The fabricated scaffolds, unlike many other natural polymers, also exhibit non‐toxic and biodegradable properties in the grafted tissues. In conclusion, the data clearly showed that the fabricated biomaterial is a biologically compatible scaffold with potential to serve as a proper platform for retaining the cultured cells for further application in cell‐based tissue engineering, especially in wound healing practices. These results suggested the potential of using mesoporous composite chitosan–GP–gelatin fibrous scaffolds for engineering three‐dimensional tissues with different inherent cell characteristics. © 2015 Wiley Periodicals, Inc. Biopolymers 105: 163–175, 2016.     

Engineering porous scaffolds using gas-based techniques

Scaffolds are used in tissue engineering as a matrix for the seeding and attachment of human cells. The creation of porosity in three-dimensional (3D) structures of scaffolds plays a critical role in cell proliferation, migration, and differentiation into the specific tissue while secreting extracellular matrix components. These pores are used to transfer nutrients and oxygen and remove wastes produced from the cells. The lack of oxygen and nutrient supply impedes the cell migration more than 500μm from the surface. The physical properties of scaffolds such as porosity and pore interconnectivity can improve mass transfer and have a great impact on the cell adhesion and penetration into the scaffolds to form a new tissue. Various techniques such as electrospinning, freeze-drying, and solvent casting/salt leaching have been used to create porosity in scaffolds. The major issues in these methods include lack of 3D structure, control on pore size, and pore interconnectivity. In this review, we provide a brief overview of gas-based techniques that have been developed for creating porosity in scaffolds.     

Development of biodegradable scaffolds based on magnetically guided assembly of magnetic sugar particles

Biodegradable scaffolds with controlled pore layout and porosity have great significance in tissue engineering for cell penetration, tissue ingrowth, vascularization, and nutrient delivery. Porogen leaching has been commonly used to control pore size, pore structure and porosity in the scaffold. In this paper we focus on the use/development of two magnetically guided porogen assembly methods using magnetic sugar particles (MSPs) for scaffold fabrication. First, a patterning device is utilized to align MSPs following designed templates. Then a magnetic sheet film is fabricated by mixing poly(vinyl alcohol, PVA) and NdFeB powder for steering the MSPs. After poly(l-lactide-co-?-caprolactone) (PLCL) casting and removal of the sugar template, a scaffold with spherical pores is obtained. The surface and the inner structure of the scaffolds are evaluated using light and electron micrographs showing their interconnection of pores, pore wall morphology and porosity. Single layer scaffolds with the size of 8mm in width and 10mm in length were constructed with controllable pore diameters in the ranges of 105-150 μm, 250-300 μm and 425-500 μm.     

Electrospinning Fibrous Polymer Scaffolds for Tissue Engineering and Cell Culture

As the field of tissue engineering evolves, there is a tremendous demand to produce more suitable materials and processing techniques in order to address the requirements (e.g., mechanics and vascularity) of more intricate organs and tissues. Electrospinning is a popular technique to create fibrous scaffolds that mimic the architecture and size scale of the native extracellular matrix. These fibrous scaffolds are also useful as cell culture substrates since the fibers can be used to direct cellular behavior, including stem cell differentiation (see extensive reviews by Mauck et al. and Sill et al. for more information). In this article, we describe the general process of electrospinning polymers and as an example, electrospin a reactive hyaluronic acid capable of crosslinking with light exposure (see Ifkovits et al. for a review on photocrosslinkable materials). We also introduce further processing capabilities such as photopatterning and multi-polymer scaffold formation. Photopatterning can be used to create scaffolds with channels and multi-scale porosity to increase cellular infiltration and tissue distribution. Multi-polymer scaffolds are useful to better tune the properties (mechanics and degradation) of a scaffold, including tailored porosity for cellular infiltration. Furthermore, these techniques can be extended to include a wide array of polymers and reactive macromers to create complex scaffolds that provide the cues necessary for the development of successful tissue engineered constructs.Download video file.^{(114M, mp4)}     

The Effect of Sterilization Methods on the Physical Properties of Silk Sericin Scaffolds

Protein-based biomaterials respond differently to sterilization methods. Since protein is a complex structure, heat, or irradiation may result in the loss of its physical or biological properties. Recent investigations have shown that sericin, a degumming silk protein, can be successfully formed into a 3-D scaffolds after mixing with other polymers which can be applied in skin tissue engineering. The objective of this study was to investigate the effectiveness of ethanol, ethylene oxide (EtO) and gamma irradiation on the sterilization of sericin scaffolds. The influence of these sterilization methods on the physical properties such as pore size, scaffold dimensions, swelling and mechanical properties, as well as the amount of sericin released from sericin/polyvinyl alcohol/glycerin scaffolds, were also investigated. Ethanol treatment was ineffective for sericin scaffold sterilization whereas gamma irradiation was the most effective technique for scaffold sterilization. Moreover, ethanol also caused significant changes in pore size resulting from shrinkage of the scaffold. Gamma-irradiated samples exhibited the highest swelling property, but they also lost the greatest amount of weight after immersion for 24 h compared with scaffolds obtained from other sterilization methods. The results of the maximum stress test and Young’s modulus showed that gamma-irradiated and ethanol-treated scaffolds are more flexible than the EtO-treated and untreated scaffolds. The amount of sericin released, which was related to its collagen promoting effect, was highest from the gamma-irradiated scaffold. The results of this study indicate that gamma irradiation should have the greatest potential for sterilizing sericin scaffolds for skin tissue engineering.