Dynamic culture of a thermosensitive collagen hydrogel as an extracellular matrix improves the construction of tissue-engineered peripheral nerve

Tissue engineering technologies offer new treatment strategies for the repair of peripheral nerve injury, hut cell loss between seeding and adhesion to the scaffold remains inevitable. A thermosensitive collagen hydrogel was used as an extracellular matrix in this study and combined with bone marrow mesenchymal stem cells to construct tissue-engineered peripheral nerve composites in vitro. Dynamic culture was performed at an oscillating frequency of 0.5 Hz and 35° swing angle above and below the horizontal plane. The results demonstrated that bone marrow mesenchymal stem cells formed membrane-like structures around the poly-L-lactic acid scaffolds and exhibited regular alignment on the composite surface. Collagen was used to fill in the pores, and seeded cells adhered onto the poly-L-lactic acid fibers. The DNA content of the bone marrow mesenchymal stem cells was higher in the composites constructed with a thermosensitive collagen hydrogel compared with that in collagen I scaffold controls. The cellular DNA content was also higher in the thermosensitive collagen hydrogel composites constructed with the thermosensitive collagen hydrogel in dynamic culture than that in static culture. These results indicate that tissue-engineered composites formed with thermosensitive collagen hydrogel in dynamic culture can maintain larger numbers of seeded cells by avoiding cell loss during the initial adhe-sion stage. Moreover, seeded cells were distributed throughout the material.

Characteristics of neural growth and cryopreservation of the dorsal root ganglion using three-dimensional collagen hydrogel culture versus conventional culture

In vertebrates, most somatosensory pathways begin with the activation of dorsal root ganglion(DRG) neurons. The development of an appropriate DRG culture method is a prerequisite for establishing in vitro peripheral nerve disease models and for screening therapeutic drugs. In this study, we compared the changes in morphology, molecular biology, and transcriptomics of chicken embryo DRG cultured on tissue culture plates(T-DRG) versus three-dimensional collagen hydrogels(C-DRG). Our results showed that after 7 days of culture, the transcriptomics of T-DRG and C-DRG were quite different. The upregulated genes in C-DRG were mainly related to neurogenesis, axon guidance, and synaptic plasticity, whereas the downregulated genes in C-DRG were mainly related to cell proliferation and cell division. In addition, the genes related to cycles/pathways such as the synaptic vesicle cycle, cyclic adenosine monophosphate signaling pathway, and calcium signaling pathway were activated, while those related to cell-cycle pathways were downregulated. Furthermore, neurogenesis-and myelination-related genes were highly expressed in C-DRG, while epithelial–mesenchymal transition-, apoptosis-, and cell division-related genes were suppressed. Morphological results indicated that the numbers of branches, junctions, and end-point voxels per C-DRG were significantly greater than those per T-DRG. Furthermore, cells were scattered in T-DRG and more concentrated in C-DRG, with a higher ratio of 5-ethynyl-2′-deoxyuridine(EdU)-positive cells in T-DRG compared with C-DRG. C-DRG also had higher S100 calcium-binding protein B(S100 B) and lower α-smooth muscle actin(α-SMA) expression than T-DRG, and contained fewer terminal deoxynucleotidyl transferase dUTP nick end labeling(TUNEL)-positive cells after 48 hours of serum starvation. After cryopreservation, C-DRG maintained more intact morphological characteristics, and had higher viability and less TUNEL-positive cells than T-DRG. Furthermore, newly formed nerve bundles were able to grow along the existing Schwann cells in C-DRG. These results suggest that C-DRG may be a promising in vitro culture model, with better nerve growth and anti-apoptotic ability, quiescent Schwann cells, and higher viability. Results from this study provide a reference for the construction, storage, and transportation of tissue-engineered nerves. The study was approved by the Ethics Committee of Aier School of Ophthalmology, Central South University, China(approval No. 2020-IRB16), on March 15, 2020.

Chitosan conduits enriched with fibrin-collagen hydrogel with or without adipose-derived mesenchymal stem cells for the repair of 15-mm-long sciatic nerve defect

Hollow conduits of natural or synthetic origins have shown acceptable regeneration results in short nerve gap repair;however,results are still not comparable with the current gold standard technique“autografts”.Hollow conduits do not provide a successful regeneration outcome when it comes to critical nerve gap repair.Enriching the lumen of conduits with different extracellular materials and cells could provide a better biomimicry of the natural nerve regenerating environment and is expected to ameliorate the conduit performance.In this study,we evaluated nerve regeneration in vivo using hollow chitosan conduits or conduits enriched with fibrin-collagen hydrogels alone or with the further addition of adipose-derived mesenchymal stem cells in a 15 mm rat sciatic nerve transection model.Unexpected changes in the hydrogel consistency and structural stability in vivo led to a failure of nerve regeneration after 15 weeks.Nevertheless,the molecular assessment in the early regeneration phase(7,14,and 28 days)has shown an upregulation of useful regenerative genes in hydrogel enriched conduits compared with the hollow ones.Hydrogels composed of fibrin-collagen were able to upregulate the expression of soluble NRG1,a growth factor that plays an important role in Schwann cell transdifferentiation.The further enrichment with adipose-derived mesenchymal stem cells has led to the upregulation of other important genes such as ErbB2,VEGF-A,BDNF,c-Jun,and ATF3.

Role of integrin b1 and tenascin C mediate TGF-SMAD2/3 signaling in chondrogenic differentiation of BMSCs induced by type I collagen hydrogel

Cartilage defects may lead to severe degenerative joint diseases.Tissue engineering based on type I collagen hydrogel that has chondrogenic potential is ideal for cartilage repair.However,the underlying mechanisms of chondrogenic differentiation driven by type I collagen hydrogel have not been fully clarified.Herein,we explored potential collagen receptors and chondrogenic signaling pathways through bioinformatical analysis to investigate the mechanism of collagen-induced chondrogenesis.Results showed that the super enhancer-related genes induced by collagen hydrogel were significantly enriched in the TGF-b signaling pathway,and integrin-b1(ITGB1),a receptor of collagen,was highly expressed in bone marrow mesenchymal stem cells(BMSCs).Further analysis showed genes such as COL2A1 and Tenascin C(TNC)that interacted with ITGB1 were significantly enriched in extracellular matrix(ECM)structural constituents in the chondrogenic induction group.Knockdown of ITGB1 led to the downregulation of cartilage-specific genes(SOX9,ACAN,COL2A1),SMAD2 and TNC,as well as the downregulation of phosphorylation of SMAD2/3.Knockdown of TNC also resulted in the decrease of cartilage markers,ITGB1 and the SMAD2/3 phosphorylation but overexpression of TNC showed the opposite trend.Finally,in vitro and in vivo experiments confirmed the involvement of ITGB1 and TNC in collagen-mediated chondrogenic differentiation and cartilage regeneration.In summary,we demonstrated that ITGB1 was a crucial receptor for chondrogenic differentiation of BMSCs induced by collagen hydrogel.It can activate TGF-SMAD2/3 signaling,followed by impacting TNC expression,which in turn promotes the interaction of ITGB1 and TGF-SMAD2/3 signaling to enhance chondrogenesis.These may provide concernful support for cartilage tissue engineering and biomaterials development.

携载microRNA-140外泌体/海藻酸钠/胶原水凝胶修复关节软骨损伤

背景:研究已证实,上调microRNA-140表达可部分抑制膝关节软骨组织与细胞的骨关节炎样改变,延缓骨关节炎进程,提示microRNA-140参与了骨关节炎的发病机制。目的:采用海藻酸钠/胶原水凝胶负载过表达microRNA-140的外泌体,进一步分析microRNA-140参与骨关节炎的相关机制。方法:利用慢病毒感染大鼠骨髓间充质干细胞使其过表达microRNA-140,随后分离提取外泌体,得到过表达microRNA-140的外泌体。制备负载外泌体的海藻酸钠/胶原水凝胶。采用随机数字表法将32只SD大鼠随机分为4组,每组8只:正常对照组不进行任何处理,骨关节炎组、未转染外泌体组、转染外泌体组均通过膝关节腔内注射碘乙酸钠的方式建立骨关节炎模型,造模2周后,骨关节炎组膝关节腔内注射PBS,未转染外泌体组、转染外泌体组膝关节腔内分别注射负载未过表达microRNA-140与过表达microRNA-140外泌体的海藻酸钠/胶原水凝胶。造模后第6周,检测大鼠机械刺激缩足反应阈值、滑膜液炎症因子浓度、软骨相关基因表达、膝关节软骨组织的组织学变化与焦亡相关蛋白表达。结果与结论:①与正常对照组比较,骨关节炎组机械刺激缩足反应阈值、Ⅱ型胶原及SOX9 mRNA表达、Ⅱ型胶原免疫荧光强度均减少(P<0.05),滑膜液中促炎症因子水平增加(P<0.05),基质金属蛋白酶13、血小板反应蛋白解整合素金属肽酶5(ADAMTS5)mRNA表达增加(P<0.05),NLRP3、ASC、GSDMD p30、caspase-1 p20、白细胞介素1β、白细胞介素18蛋白表达均增加(P<0.05),GSDMD、cleaved caspase-1免疫荧光强度增强(P<0.05),软骨组织损伤严重。②与骨关节炎组比较,两外泌体组机械刺激缩足反应阈值、Ⅱ型胶原及SOX9 mRNA表达、Ⅱ型胶原免疫荧光强度均增加(P<0.05),滑膜液中促炎症因子水平减少(P<0.05),基质金属蛋白酶13 mRNA表达减少(P<0.05),NLRP3、ASC、GSDMD p30、caspase-1 p20、白细胞介素1β、白细胞介素18的蛋白表达均减少(P<0.05),GSDMD、cleaved caspase-1的免疫荧光强度减弱(P<0.05),软骨组织损伤减轻(P<0.05),并且转染外泌体组的作用更强。③结果表明,microRNA-140可通过抑制炎症、维持软骨稳态、抑制软骨焦亡来减轻骨关节炎大鼠的疼痛反应,降低软骨损伤,发挥骨关节炎治疗作用。

羟基磷灰石-聚乙烯醇/胶原-壳聚糖-明胶复合水凝胶修复兔骨软骨缺损

背景:关节骨软骨缺损是目前骨科医生面临的难题,传统修复方法难以取得满意疗效,以羟基磷灰石-聚乙烯醇为基础的复合水凝胶材料是目前研究的一个方向。目的:制备羟基磷灰石-聚乙烯醇/胶原-壳聚糖-明胶复合水凝胶,表征其物理学特征,验证其植入体内后的组织相容性及细胞黏附增殖能力,探讨其对兔骨软骨缺损的修复效果。方法:利用3D打印技术制备圆柱状多孔聚乳酸支架(孔径分别为1.2,1.4,1.6,1.8 mm),再将聚乙烯醇及羟基磷灰石混合乳液灌入聚乳酸支架中,经过冻融及二氯甲烷溶解后制成羟基磷灰石-聚乙烯醇水凝胶。然后将胶原-壳聚糖-明胶混合液灌入羟基磷灰石-聚乙烯醇水凝胶中,利用京尼平进行交联,最后经乙醇清洗及冷冻干燥制成羟基磷灰石-聚乙烯醇/胶原-壳聚糖-明胶复合水凝胶,表征4组水凝胶的物理学特征,筛选性能最优的水凝胶进行后续实验。将羟基磷灰石-聚乙烯醇水凝胶、胶原-壳聚糖-明胶复合水凝胶分别植入SD大鼠皮下,苏木精-伊红与Masson染色观察材料表面的细胞黏附生长状况。在15只兔双侧膝关节股骨滑车制作骨软骨缺损(直径5 mm、深6 mm)模型,左侧植入复合水凝胶(实验组),右侧未植入任何材料(对照组),Micro-CT及组织学检测来评估其对骨软骨缺损的修复效果。结果与结论:①综合孔隙率、含水率、力学测试及扫描电镜结果,得出孔径1.2 mm的羟基磷灰石-聚乙烯醇/胶原-壳聚糖-明胶复合水凝胶更符合天然软骨的一般特性,用于后续实验;②苏木精-伊红与Masson三色染色显示,随着材料植入大鼠皮下时间的延长,两种材料周边黏附的细胞均明显增多,其中胶原-壳聚糖-明胶植入后的细胞增殖状况更好,可见大量细胞长入其形成的网状结构,且网状结构也逐渐降解;③在兔骨软骨缺损实验中,至术后8周时,Micro-CT检查显示实验组植入的材料和周围骨-软骨整合良好,其表面及内部均有部分骨长入,对照组软骨及软骨下层仍然存在明显的缺损,未形成有效修复;苏木精-伊红与甲苯胺蓝染色显示,实验组植入复合水凝胶4-8周后即与周围骨软骨发生整合,随着时间的延长材料表面逐渐有新生软骨形成,至12周时缺损处大部分被新生软骨覆盖,软骨下层也出现良好的骨长入;对照组至术后12周虽然深层骨缺损大部分修复、浅层的软骨及软骨下骨缺损也有一定程度修复,但主要被纤维组织及部分纤维软骨替代;④结果表明,羟基磷灰石-聚乙烯醇/胶原-壳聚糖-明胶复合水凝胶材料可仿生天然软骨的结构和功能,在动物实验中能有效修复骨软骨缺损。

载雷奈酸锶海藻酸钠/胶原水凝胶促进骨性关节炎骨缺损的修复

背景:软骨退行性变和软骨下骨损伤是骨性关节炎的主要病理特征,根据这一病理特征进行局部调控将是骨性关节炎治疗的有前景改进方案。目的:设计并研究一种可注射载雷奈酸锶药物递送系统,观察其在骨性关节炎局部促进软骨修复并改善软骨下骨结构的治疗效果。方法:①体外实验:将雷奈酸锶搭载于海藻酸钠/胶原水凝胶基质中构建原位药物递送系统,表征该系统的体外缓释性能。将载雷奈酸锶海藻酸钠/胶原水凝胶(实验组)、海藻酸钠/胶原水凝胶(对照组)分别与骨髓间充质干细胞共培养,以单独培养的细胞为空白对照组,检测细胞增殖活性;在成软骨诱导分化后,分别进行番红O染色、阿利新蓝染色及RT-qPCR检测。将两种水凝胶分别与成骨细胞共培养,以单独培养的细胞为空白对照组,进行免疫荧光染色及RT-qPCR检测。②体内实验:取18只成年SD大鼠,通过内侧半月板切除的方法建立右后侧膝骨性关节炎模型,造模后1周,采用随机数字表法分3组处理:空白组不进行任何处理,对照组膝关节腔内注射海藻酸钠/胶原水凝胶,实验组右膝关节腔内注射载雷奈酸锶海藻酸钠/胶原水凝胶,每组6只。造模后第6周取材,分别进行Micro-CT扫描、苏木精-伊红染色、番红O染色及免疫荧光染色。结果与结论:①体外实验:载雷奈酸锶海藻酸钠/胶原水凝胶具有疏松多孔的微观结构,可持续释放雷奈酸锶,至21 d时累计释放量(60.89±0.58)%。骨髓间充质干细胞活死染色显示,两种水凝胶均具有良好的细胞相容性。CCK-8检测显示,载雷奈酸锶海藻酸钠/胶原水凝胶可促进骨髓间充质干细胞的增殖;番红O染色、阿利新蓝染色、免疫荧光染色及RT-qPCR检测显示,载雷奈酸锶海藻酸钠/胶原水凝胶可促进骨髓间充质干细胞的成软骨分化。免疫荧光染色及RT-qPCR检测显示,载雷奈酸锶海藻酸钠/胶原水凝胶可通过增加骨保护素/核因子κB受体活化因子配体比值而降低骨吸收活性。②体内实验:Micro-CT扫描显示,与空白组、对照组比较,实验组大鼠膝关节软骨下骨骨体积分数与骨密度升高(P<0.05,P<0.01)。组织学染色显示,与空白组、对照组比较,实验组大鼠膝关节软骨损伤明显减轻,促进Ⅱ型胶原蛋白的表达、抑制基质金属蛋白酶2蛋白的表达(P<0.05,P<0.01)。③结果表明:载雷奈酸锶海藻酸钠/胶原水凝胶能促进骨性关节炎软骨缺损的修复、重建软骨和软骨下骨之间的复杂界面。

EDC/NHS交联重组胶原蛋白水凝胶修复关节软骨缺损

关节软骨损伤、缺损是一种常见且严峻的临床挑战,没有有效的治疗方法,基于胶原蛋白的水凝胶是软骨组织工程的研究热点之一,但在开发具有良好生物相容性且可安全交联的胶原蛋白产品,并提高软骨修复有效性方面仍然存在巨大挑战。将重组Ⅰ型胶原蛋白和重组Ⅲ型胶原蛋白通过EDC/NHS交联,制备了2种水凝胶,均表现出良好的三维孔隙结构以及优异的力学性能和可降解性。研究发现,重组Ⅰ型胶原蛋白水凝胶(Gel-Ⅰ)和重组Ⅲ型胶原蛋白水凝胶(Gel-Ⅲ)能促进人骨髓间充质干细胞(human bone-marrow mesenchymal stem cells,HBMSCs)糖胺聚糖的分泌,Gel-Ⅰ可以显著上调HBMSCs表达COLⅡ基因和SOX9基因,Gel-Ⅲ可以显著上调SOX9基因表达。在兔子膝关节软骨修复模型中,与对照组和Gel-Ⅲ组相比,Gel-Ⅰ组在骨体积大小方面表现出明显优势,软骨下骨已形成并有效恢复,小梁的数量和厚度最高,小梁分布更均匀,并且缺损处新软骨厚度与相邻软骨厚度相同。因此,Gel-Ⅰ在软骨修复有效性以及安全性方面具有极大的临床应用潜力。

漆酶-原儿茶醛交联鱼皮胶原蛋白水凝胶的研究

与哺乳动物蛋白相比,鱼皮胶原蛋白未受到克雅氏病和牛海绵状脑病流行的限制,具有较大的应用潜力,然而较差的力学性能和耐降解性质限制了鱼皮胶原的应用。论文探究了漆酶(LAC)和原儿茶醛(PAL)交联制备胶原蛋白水凝胶的交联机理,凝胶微观结构,力学性能和耐降解性质。结果表明,漆酶能够交联胶原成胶。同时,原儿茶醛的引入增强了漆酶交联胶原的作用,提升了胶原蛋白水凝胶的结构稳定性和耐降解性质。LAC-PAL交联胶原是一种构建胶原蛋白水凝胶的有效策略。

琼脂糖/胶原复合水凝胶的制备及性能研究

针对胶原水凝胶力学性能及成形性能差的问题,采用琼脂糖与胶原复合的方法制备了一种兼备良好生物学、力学及成形性能的琼脂糖/胶原复合水凝胶材料。研究了胶原与琼脂糖溶液的复合方式,制备了具有相同胶原质量浓度、不同琼脂糖质量浓度的琼脂糖/胶原复合水凝胶。以胶原水凝胶为对照组,从力学强度、微结构成形性和细胞相容性方面综合评价了不同琼脂糖/胶原复合水凝胶材料的性能。结果表明:随着琼脂糖浓度的提高,复合水凝胶的力学性能成倍增加,微结构的成形性能也逐步改善,但细胞相容性却逐渐降低。琼脂糖质量浓度为0.004g/mL、胶原质量浓度为0.003g/mL的复合水凝胶能较好,兼顾了水凝胶的力学性能、成形性及细胞性能。体内植入实验发现,该配比的复合水凝胶在体内能有效减缓胶原水凝胶的降解,并产生较低的免疫排斥反应。研究的琼脂糖/胶原复合水凝胶有望用于构建具有仿生血管系统的组织工程支架。

胶原基水凝胶的制备、结构性能表征及其在生物医学中的应用

作为一种具有特殊网络结构和功能的天然高分子材料,胶原基水凝胶已在医用敷料、药物载体、组织工程支架等生物医学领域得到了广泛应用。对近几年胶原基水凝胶的研究应用现状进行了全面综述,从胶原的结构与性能入手,着重对胶原基水凝胶的制备、结构性能表征及其在生物医学中的应用进行了阐述,同时对制备过程条件的控制对水凝胶结构性能的影响进行了重点讨论,对胶原基水凝胶的未来前景和发展重点进行了展望,有望为将来有关胶原基水凝胶的研究和应用提供数据参考。

辐射交联PVA/PVP/胶原复合水凝胶的制备及性能

采用辐射交联与冻融循环相结合的方法,将胶原引入聚乙烯醇(PVA)/聚乙烯基吡咯烷酮(PVP)水凝胶体系,制备具有较高生物活性的PVA/PVP/胶原复合水凝胶。通过含水率、溶胀性能、力学性能及微观结构研究胶原对复合水凝胶结构与性能的影响,并优选最佳体系进行体外细胞毒性实验(MTT法)。研究结果表明,复合水凝胶具有均匀分布的三维多孔结构,胶原的添加增大水凝胶网络空间结构,其初始含水率达92%,并在10 h内达到溶胀平衡,但力学性能降低。辐射交联与冻融循环相结合的方法有利于提高胶原水凝胶制备效率,胶原结构不改变,其体外细胞存活率从PVA/PVP水凝胶的77.3%提高到93.8%,细胞相容性提高。

基于多巴胺的黏合水凝胶的制备及表征

以1-(3-二甲氨基丙基)-3-乙基碳二亚胺/N-羟基琥珀酰亚胺(EDC/NHS)为催化剂,将多巴胺通过酰胺化反应连接到氧化海藻酸钠上,制得含邻苯二酚结构的氧化海藻酸钠(COA),将COA与胶原(COL)复合,制得具有黏合性能的COA-COL水凝胶,通过紫外-可见光谱(UV-Vis)、傅里叶变换红外光谱(FTIR)和核磁共振波谱(1H NMR)方法表征了COA的结构,用扫描电子显微镜、体外膨胀降解、万能电子拉力机和噻唑蓝(MTT)法分别表征了COA-COL水凝胶的形貌结构、平衡溶胀率、降解率、黏合强度和细胞毒性.研究结果表明,多巴胺已引入到氧化海藻酸钠上,取代度分别为12.5%,18%和22%;COA-COL水凝胶的内部形成了典型的海绵体多孔网状结构,平衡溶胀率随着多巴胺取代度的提高先减小后增大,降解率随着取代度的提高依次减小,COA-COL水凝胶的黏合强度从未经多巴胺改性时的(20.43±4.21)k Pa提高到多巴胺取代度为22%时的(29.91±6.10)k Pa,而且具有良好的生物相容性.

胶原-PVA复合水凝胶的制备

目的通过反复冻融法制备胶原-聚乙烯醇(PVA)复合水凝胶材料。方法制备组分比例(胶原固含量为0%、5%、10%、15%、20%)不同的5组胶原-PVA复合水凝胶试样,对其进行一些物理和化学性能的表征,选出性能最优的胶原/PVA配比。将最优配比制备出的胶原-PVA复合水凝胶进行细胞毒性实验的生物学评价。结果实验制备所得胶原-PVA复合水凝胶的红外图谱可见明显的酰胺谱带;差动扫描式热量法(DSC)图出现2个热吸收峰,峰值温度分别为65℃～72℃、222℃～225℃;扫描电子显微镜显示材料为多孔结构;X射线衍射(XRD)峰值为20°;溶胀值最高为24 g/g;透水气性最高的达1 400 g/(m2.24 h);降解性能良好,15 d内大部分降解率达80%;细胞毒性为0～1级。结论胶原-PVA复合水凝胶作为体表创伤敷料具有良好的应用前景,但尚需对其进行体表创伤修复效果及其他生物相容性的评价。

胶原蛋白水凝胶在软骨组织工程中的应用

由创伤或骨病所致的关节骨软骨损伤在临床中十分常见,其中软骨缺损者达40.31%。由于关节软骨自身修复能力低下,采用组织工程技术对关节软骨损伤进行修复是目前采用再生医学治疗关节软骨损伤的新方法。组织工程支架按照性状可分为预成型支架材料及水凝胶材料两大类。传统的预成型支架材料移植技术容易给缺损周边软骨带来继发损伤,也存在支架与缺损整合不紧密等问题。如何在避免二次损伤的基础上,应用理想的仿生材料复合种子细胞修复关节不规则软骨损伤将成为未来软骨损伤修复的主要问题。选取微创、仿生并且可以原位塑形的胶原蛋白水凝胶复合种子细胞修复关节软骨损伤为损伤关节软骨的修复带来了希望。本文结合国内外相关文献对目前胶原蛋白水凝胶在软骨组织工程中的应用做一综述。

胶原基复合水凝胶的制备与表征(Ⅰ)——力学性能的响应曲面分析

以丁二酸酐对聚乙烯醇进行改性制备改性聚乙烯醇,使其在EDC/NHS交联反应体系下与胶原共价交联。然后,再采用反复冻融物理交联的方式予以强化,制备化学交联-互穿网络共存的胶原基复合水凝胶。为了更好地掌握过程中各因素对交联反应的影响,采用响应曲面设计方法研究了改性聚乙烯醇中的羧基含量、改性聚乙烯醇与胶原质量比、交联剂用量以及冻融循环次数对水凝胶力学性能的影响。结果表明,响应面模型可以很好地拟合试验条件下所得到的各响应值。与各单因素相比,各平方项对水凝胶力学性能的影响更为明显。然而,仍需进一步对其进行结构、化学性能、生物学性能及其体表创伤修复效果等方面的评价。

胶原-聚乙烯醇水凝胶溶胀特性的研究

采用经化学改性的含羧基的聚乙烯醇、胶原为原料,经物理交联,即反复冻融法制备了胶原-聚乙烯醇水凝胶。研究了不同原料配比的胶原-聚乙烯醇水凝胶的溶胀动力学、pH敏感性及pH溶胀-消胀特性,并利用数学方程拟合的方法计算其平衡溶胀比,尽量减少了因样品溶胀不足或测量误差导致平衡溶胀比估算的不准确性,使所得数据更加科学准确。结果显示:制备的胶原-聚乙烯醇水凝胶具有很快的溶胀速率,如胶原含量为9.09%的4号水凝胶可在100min内达到90%的平衡溶胀率,且随着胶原含量的增加,溶胀速率随之加快;电解质可降低其平衡溶胀比;有一定的pH敏感性和pH溶胀-消胀特性,胶原含量的增加可使水凝胶的pH溶胀-消胀特性更加显著。

新型胶原基pH敏感水凝胶的制备及性能

在紫外光辐照下,以H2O2为引发剂,采用接枝共聚法制备胶原/聚乙烯吡咯烷酮/丙烯酰胺(Collagen/PVP/AM)pH敏感水凝胶。考察了原料配比和干燥方法对凝胶溶胀性能的影响,研究了其pH敏感性及pH溶胀-退胀特性。制备的水凝胶具有较快的溶胀速率,在5min时的吸水率可达94%左右。所制备的水凝胶有明显的pH敏感性且pH溶胀-退胀的可逆性良好。傅里叶变换红外光谱法(FTIR)和示差扫描量热法(DSC)结果表明,在保持胶原三股螺旋结构的同时,材料间发生了化学交联,材料的热稳定性显著提高,从而扩大了材料的应用范围。

胶原基医用复合水凝胶的制备及性质研究

以胶原蛋白和透明质酸为基材,用碳化二亚胺交联合成可用于药物的控制释放的医用可降解水凝胶。考察了不同胶原蛋白与透明质酸配比对水凝胶吸水率和表面形状的影响,采用生理盐水、磷酸盐缓冲液、I型胶原蛋白酶和透明质酸酶评价了这种水凝胶的生物降解性,并对载药水凝胶进行了体外降解释药实验。研究表明:胶原蛋白与透明质酸的配比为1.5:2时得到的复合水凝胶吸水率和表面形状等因素都较好;水凝胶在混合酶溶液中降解较为迅速;布洛芬(IBF)采用包埋方式载药的药物释放速率比浸泡方式的速率慢。

神经干细胞联合胶原蛋白支架移植脊髓损伤大鼠脑细胞的凋亡

背景:目前的研究表明,从胚胎大鼠大脑皮质分离的神经干细胞在胶原蛋白凝胶中可增殖并分化为神经元、星形胶质细胞和少突胶质细胞。目的:观察神经干细胞联合胶原蛋白支架移植对脊髓损伤后鼠大脑神经细胞凋亡的影响。方法:取45只SD大鼠制作脊髓半切损伤模型,随机分为3组,造模1周后,细胞移植组大鼠运动皮质后部在脊髓损伤部位注入同种异体神经干细胞悬液,联合组在脊髓损伤部位注入同种异体神经干细胞结合胶原蛋白悬液,模型组不植入任何物质。结果与结论:移植后1-8周,3组大鼠肢体运动功能均有不同程度恢复,且联合组移植后8周BBB运动评分明显高于其他两组(P<0.05)。移植后1周苏木精-伊红染色显示3组均可见少量凋亡细胞及Bcl-2抗凋亡蛋白阳性细胞,大量Bax阳性细胞;随时间的推移,3组Bax凋亡蛋白阳性细胞、Bcl-2抗凋亡蛋白阳性细胞逐渐减少,并且移植后8周联合组、细胞移植组Bax阳性细胞明显低于模型组(P<0.05),Bcl-2抗凋亡蛋白阳性细胞高于模型组(P<0.05),此时3组均无凋亡细胞。表明神经干细胞联合胶原蛋白支架移植可抑制脊髓损伤后鼠大脑神经细胞的凋亡,促进脊髓神经功能的恢复。