高仿真组织工程神经支架制备工艺的参数优化

目的：对直接影响神经支架微观结构的关键因素进行分析,以确定制备不同孔径仿真支架的制备工艺。方法：用前期开发的神经支架制备工艺,应用不同浓度的醋酸浓度和冷淋速度制备仿真神经支架,以扫描电镜观察神经支架结构特征,以确定醋酸浓度和冷淋速度对神经支架内部结构的影响。结果：醋酸浓度和冷淋速度对神经支架内部结构具有重要影响。醋酸浓度为0mg/ml时,无法制备定向结构的神经支架,当醋酸浓度为1mg/ml、2mg/ml、3mg/ml和4mg/ml时,可制备轴定向仿真支架,并且神经支架的孔径随醋酸浓度增大而增大;当冷淋速度为1×10-5m/s、2×10-5m/s和5×10-5m/s时,所制备的仿真支架内部均呈明显的轴向微管结构,其中冷淋速度为2×10-5m/s时,其轴向微管结构排列最为有序、规律。当速度为1×10-6m/s,2×10-6m/s,5×10-6m/s以及1×10-4m/s时,所制备的材料内部微管结构走向无明显规律。结论：醋酸浓度和冷淋速度是影响神经支架内部结构的两个关键因素,通过改变醋酸浓度和冷淋速度可制备不同孔径的仿真神经支架。     

制备大孔径静电纺丝组织工程支架的研究进展

研究表明静电纺丝可以制备出模拟细胞外基质的三维结构,其中限制静电纺丝纤维支架应用的问题之一就是纤维排列紧密导致支架的孔径较小,从而阻碍了细胞的浸入,组织中血管化的形成以及支架与宿主细胞的融合。为了增大支架的孔径,提高孔隙率,许多研究者提出了相应的策略。本文综述了多种制备大孔径静电纺丝纤维支架的方法,主要包括不同接收装置控制电场分布、盐粒子/聚合物析出法、水浴接收、低温静电纺丝以及激光/紫外烧蚀法等,以上的方法都能够有效的增大静电纺丝三维支架的孔径,进而提高了细胞的浸润性、营养物质的传输以及废物的排出,为静电纺丝纤维支架在组织工程中的应用奠定了基础。     

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。     

几种神经支架原材料的生物力学性质评价

组织工程支架都需要有一定的力学性能以满足实际使用时的要求。本文考察了9种候选神经支架原材料的力学性能,为神经支架的设计制作的选材提供力学依据。本研究以PLGA、胶原、海藻酸钠、脱细胞猪皮、脱细胞血管、脱细胞猪皮-PLGA的复合体、脱细胞血管-PLGA的复合体以及经改性的壳聚糖和明胶作为考察材料,用拉伸实验机对其进行拉伸试验。本试验获得了这9种材料的最大应变、最大应力厦杨氏模量。其结果可以为神经支架的选材、设计和制作提供力学参考依据。     

溶剂浇铸/颗粒沥滤技术制备组织工程支架材料

生物可降解多孔三维细胞支架是组织工程化组织构建的基础。溶剂浇铸粒子沥滤技术是最简便、也是研究最广泛的一种多孔三维细胞支架制备技术,随着各种改进方法的出现,溶剂浇铸粒子沥滤已成为组织工程用多孔三维细胞支架的理想制备技术 。     

Ⅱ型胶原-硫酸软骨素支架的制备及组织工程软骨的构建

研究经乙基-(3-二甲基氨基丙基)碳化二亚胺盐酸盐(EDC)处理的Ⅱ型胶原-硫酸软骨素支架材料的性能特点,并在体外构建组织工程软骨。从鸡软骨中提取Ⅱ型胶原,以不同浓度的EDC为交联剂通过冷冻干燥的方法制备Ⅱ型胶原与硫酸软骨素复合支架并测定其理化性质。将体外培养的新生兔关节软骨细胞接种在Ⅱ型胶原与硫酸软骨素复合支架上,观察软骨细胞在支架上的生长形态并检测支架上软骨细胞分泌的糖胺聚糖含量及Ⅱ型胶原含量。结果表明:采用EDC与硫酸软骨素交联增加了支架的稳定性,最适的交联剂质量浓度为7 mg/mL。软骨细胞在复合支架上增殖分化良好,并保持软骨细胞特异分化的表型,分泌Ⅱ型胶原与蛋白多糖(GAG)。培养14 d后已有软骨样组织形成。     

兔组织工程同种异体气管支架三种制备方法的比较

目的:探讨深低温冷冻-酶洗法制备的气管支架在去除抗原性、维持生物力学及保护细胞外基质方面的效果。方法:健康新西兰兔24只随机分为气管未处理作为对照A组,深低温冷冻法处理B组,玻璃化法处理C组,深低温冷冻-酶洗法D组,各组样本数均为6。处理后将各组标本行HE染色后光镜观察,戊二醛固定后电镜扫描,并测量气管最大拉伸力、破裂力和变异率等生物力学性能。结果:组织学观察显示对照A组有大量完整的粘膜上皮细胞;B组和C组可见部分气管粘膜上皮细胞;D组标本未见气管粘膜上皮细胞,且细胞核碎裂。电镜显示A、B、C、D组气管支架可见丰富的细胞基质,未暴露胶原纤维。组间两两比较,气管支架的最大拉伸力、最大破裂力和变异率均无统计学差异。结论:综合组织学、扫面电镜和生物力学分析,应用深低温冷冻-酶洗法制备气管支架D组可以有效地去除抗原,维持生物力学性能,并具有较完整的细胞外基质。     

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。     

基于组织工程研究的可降解支架材料选择策略

目前,器官或组织移植是治疗器官衰竭或大范围组织缺损唯一长期有效的方法,但存在供体短缺、免疫排斥等问题。组织工程技术作为一种潜在的替代治疗方法,支架材料的选择是其中具有决定意义的组成部分。组织工程支架材料按其来源可分为天然及其改性修饰材料、人工合成与复合支架材料3种。组织工程目的就是修复临床上的病损组织或器官,并达到较理想的结构和功能的恢复。因此组织工程支架也必须从基本性质上具有一定的仿生化结构及功能,即"活"支架,这样才能彻底代替病损组织或器官。通过多种支架材料的优化组合(即材料的复合),对材料进行表面改性、制备工艺优化及添加细胞因子缓释微球等技术,模拟病损器官组织的特性及周围环境,有望打开组织工程的新局面。理想的组织工程支架应当以临床需要为根本目的,依靠材料学、分子生物学、工程学等多学科间的交叉研究,取各家之长,优化配比组合,达到仿生的目的。本课题组前期工作已经将骨髓间充质干细胞体外诱导分化为胆管上皮样细胞,并设计出左旋聚乳酸/聚己内酯共聚物(PLCL)胆道支架,内部混有包含生长因子的纳米缓释微球,供细胞因子的远期释放,支架内表面涂有基质胶/胶原混合层,且胶内加入bFGF、EGF,提供诱导因子的早期释放。将诱导细胞与PLCL胆道支架复合,制备组织工程胆管。文中综述了现存各类支架材料的研究状况,简单介绍了制备工艺、表面修饰等影响支架性能的因素,力求探索组织工程支架材料的选择策略。     

微环境对细胞的影响以及仿生学在组织工程支架中的应用

微环境影响着细胞的增殖、迁移、分化以及细胞功能,细胞微环境影响细胞命运的因素包括细胞之间相互作用、细胞与细胞外基质相互作用、可溶性信号分子以及缺氧和营养对细胞的影响。组织工程支架的制备就是要利用仿生学原理最大程度模拟细胞微环境,从而应用于细胞行为研究以及临床治疗。全面了解细胞微环境对细胞的影响因素是制备组织工程支架的重要条件,而组织工程支架的研究也进一步推动了细胞微环境对细胞影响的认识。组织工程支架研究在组织工程研究中仍具有广阔前景,新的制备工艺也在组织工程支架研究中发挥着巨大推动作用。     

Modification of the Silver Proteinate Impregnation Technique for Protozoa and Cultured Nerve Cells

Silver impregnation with silver-protein compounds is widely used for staining tissue sections and cell cultures. Some authors report that the results obtained with these methods have not always been reproducible because the reagent's composition varies according to the manufacturer. To avoid this problem in the method described in this paper, a silver proteinate, produced in our own laboratory is used. Although our method is based on Bodian's, the modifications we have made allows its use for both free-living cells (protozoa) and cells grown in culture (nerve cells). The significant modifications are 1) different fixation, 2) postfixation with Cajal's for-mol-bromide, 3) changes in the duration of the impregnation steps technique and 4) elimination of metallic copper. The method reported here enables us to use silver proteinate whenever we require it and to control the composition of the silver proteinate. This technique can be used for cells cultured in either plastic or glass.     

Tissue Engineering: Construction of a Multicellular 3D Scaffold for the Delivery of Layered Cell Sheets

Many tissues, such as the adult human hearts, are unable to adequately regenerate after damage.^2,3 Strategies in tissue engineering propose innovations to assist the body in recovery and repair. For example, TE approaches may be able to attenuate heart remodeling after myocardial infarction (MI) and possibly increase total heart function to a near normal pre-MI level.⁴ As with any functional tissue, successful regeneration of cardiac tissue involves the proper delivery of multiple cell types with environmental cues favoring integration and survival of the implanted cell/tissue graft. Engineered tissues should address multiple parameters including: soluble signals, cell-to-cell interactions, and matrix materials evaluated as delivery vehicles, their effects on cell survival, material strength, and facilitation of cell-to-tissue organization. Studies employing the direct injection of graft cells only ignore these essential elements.^2,5,6 A tissue design combining these ingredients has yet to be developed. Here, we present an example of integrated designs using layering of patterned cell sheets with two distinct types of biological-derived materials containing the target organ cell type and endothelial cells for enhancing new vessels formation in the “tissue”. Although these studies focus on the generation of heart-like tissue, this tissue design can be applied to many organs other than heart with minimal design and material changes, and is meant to be an off-the-shelf product for regenerative therapies. The protocol contains five detailed steps. A temperature sensitive Poly(N-isopropylacrylamide) (pNIPAAM) is used to coat tissue culture dishes. Then, tissue specific cells are cultured on the surface of the coated plates/micropattern surfaces to form cell sheets with strong lateral adhesions. Thirdly, a base matrix is created for the tissue by combining porous matrix with neovascular permissive hydrogels and endothelial cells. Finally, the cell sheets are lifted from the pNIPAAM coated dishes and transferred to the base element, making the complete construct.     

Nerve growth factor stimulates the interaction of ZIP/p62 with atypical protein kinase C and targets endosomal localization: evidence for regulation of nerve growth factor-induced differentiation

Atypical protein kinase Cs zeta and lambda/iota play a functional role in the regulation of NGF-induced differentiation and survival of pheochromocytoma, PC12 cells [Coleman and Wooten, 1994; Wooten et al., 1999]. Here we demonstrate an NGF-dependent interaction of aPKC with its binding protein, ZIP/p62. Although, ZIP/p62 was not a PKC-iota substrate, the formation of a ZIP/p62-aPKC complex in PC12 cells by NGF occurred post activation of PKC-iota and was regulated by the tyrosine phosphorylation state of aPKC. Furthermore, NGF-dependent localization of ZIP/p62 was observed within vesicular structures, identified as late endosomes by colocalization with a Rab7 antibody. Both ZIP/p62 as well as PKC-iota colocalized with Rab7 upon NGF stimulation. Inhibition of the tyrosine phosphorylation state of PKC-iota did not prevent movement of ZIP/p62 to the endosomal compartment. These observations indicate that the subcellular localization of ZIP/p62 does not depend entirely upon activation of aPKC itself. Of functional importance, transfection of an antisense p62 construct into PC12 cells significantly diminished NGF-induced neurite outgrowth. Collectively, these findings demonstrate that ZIP/p62 acts as a shuttling protein involved in routing activated aPKC to an endosomal compartment and is required for mediating NGF's biological properties.