一种骨种子细胞体外应力培养系统的建立

目的建立体外应力培养系统，观察应力刺激对骨种子细胞成骨分化的影响。方法选择具有明确成骨分化潜能的间充质干细胞(MSCs)作为种子细胞，以脱细胞骨基质为支架材料，以流体切应力作为对种子细胞的体外应力刺激。建立一种骨种子细胞体外三维应力培养系统——流动腔灌流体系，并利用该系统对MSCs的碱性磷酸酶(ALP)活性和骨钙素产物的影响进行评价。结果该系统可以明显促进ALP活性和骨钙素产物的表达，而细胞计数无明显改变。结论本系统为骨组织工程研究提供了一种有效的体外培养模型。     

天然生物材料构建组织工程支架的研究进展

细胞培养支架材料是组织工程的重要研究内容之一.本文综述近年来几种典型天然生物材料构建组织工程支架的研究进展,并详细介绍了适用于天然生物材料制备组织工程支架的致孔方法.     

Ligament tissue engineering: an evolutionary materials science approach

The anterior cruciate ligament (ACL) is important for knee stabilization. Unfortunately, it is also the most commonly injured intra-articular ligament. Due to poor vascularization, the ACL has inferior healing capability and is usually replaced after significant damage has occurred. Currently available replacements have a host of limitations, this has prompted the search for tissue-engineered solutions for ACL repair. Presently investigated scaffolds range from twisted fiber architectures composed of silk fibers to complex three-dimensional braided structures composed of poly (l-lactic acid) fibers. The purpose of these tissue-engineered constructs is to apply approaches such as the use of porous scaffolds, use of cells, and the application of growth factors to promote ligament tissue regeneration while providing mechanical properties similar to natural ligament.     

人表皮细胞分离培养最佳条件的选择

目的 确定表皮细胞分离培养的最佳条件，为进一步将其作为皮肤组织工程种子细胞奠定基础。方法 采用组织块法培养表皮细胞；分别以胰蛋白酶和分散酶分离表皮细胞，有血清培养法和无血清培养法进行表皮细胞的培养，并以克隆形成试验检测细胞存活和生长情况。结果 （1）表皮细胞以分散分离可量在多数基底细胞，且成纤维细胞污染少，而胰蛋白酶得到的表皮细胞少，且混杂有大量的成纤维细胞。（2）组织块法可观察到表皮细胞生长，但成纤维细胞污染严重，且不易得到成片生长的表皮。（3）有血清培养法表皮细胞需在3T3细胞的滋养层上生长，存在3T3细胞污染的可能。（4）无血清培养方法简便易行，更有利于表皮细胞的生长。结论 采用无血清培养法培养表皮细胞条件的最终确定，为进行相关的研究，尤其是皮肤组织工程的研究奠定了基础。     

Dynamic Mechanical Conditioning of Collagen-Gel Blood Vessel Constructs Induces Remodeling In Vitro

Dynamic mechanical conditioning is investigated as a means of improving the mechanical properties of tissue-engineered blood vessel constructs composed of living cells embedded in a collagen-gel scaffold. This approach attempts to elicit a unique response from the embedded cells so as to reorganize their surrounding matrix, thus improving the overall mechanical stability of the constructs. Mechanical conditioning, in the form of cyclic strain, was applied to the tubular constructs at a frequency of 1 Hz for 4 and 8 days. The response to conditioning thus evinced involved increased contraction and mechanical strength, as compared to statically cultured controls. Significant increases in ultimate stress and material modulus were seen over an 8 day culture period. Accompanying morphological changes showed increased circumferential orientation in response to the cyclic stimulus. We conclude that dynamic mechanical conditioning during tissue culture leads to an improvement in the properties of tissue-engineered blood vessel constructs in terms of mechanical strength and histological organization. This concept, in conjunction with a proper biochemical environment, could present a better model for engineering vascular constructs. © 2000 Biomedical Engineering Society. PAC00: 8719Rr, 8714Ee, 8718-h, 8768+z     

Long-term outcomes using vascular grafts sealed with fragmented autologous adipose tissue for aortoiliac occlusive disease

The aim of this study was to test the safety and efficacy of fragmented autologous adipose tissue (FAT) grafts for revascularization in aortoiliac occlusive disease. Twenty-seven patients with atherosclerotic aortoiliac occlusive disease underwent surgical treatment using FAT grafts. A piece of adipose connective tissue was obtained from the operative wound, cut into small pieces, and pressed into the wall of a fabric vascular prosthesis. Cumulative primary patency rates were 92% at 1 year, 92% at 3 years, and 86% at 6 years. Cumulative secondary patency rates were 96%, 96%, and 90% for the same intervals. In this clinical study, the FAT grafts demonstrated good long-term patency rates and no particular problems. This is the first clinical report of long-term outcomes using FAT grafts for aortofemoral or aortoiliac bypasses. FAT grafts are thus safe for revascularization in aortoiliac occlusive disease.     

心脏组织工程瓣脉动流培养系统的设计与构建

自行设计和制造平面和三维立体培养室及贮液室等构件,用医用硅胶管连接;转子泵作为动力源,贮液室通气口供给5%CO2 95%空气,恒温水浴箱保持构件37℃恒温,这样组成了种植细胞与生物瓣支架复合体的脉动培养系统,并进行生物力学和生物相容性测试,为心脏组织工程瓣的体外构建提供研究器材。结果显示,该装置密闭性能好,内环境能保持37±1℃、CO2浓度5%±1%、pH值6.8～7.5;流量在0.125～6.0L/min的范围内任意调节;同种瓣膜上的内皮细胞经2周培养后扩增约10倍;瓣膜支架的细菌和霉菌培养均为阴性,说明我们构建的脉动流培养系统能有效地模拟体内脉动流场实现种植细胞在体外的增殖、重塑,为心脏组织工程瓣的体外构建提供了一种新的实验方法。     

间充质干细胞在肌腱组织工程中的应用

在骨髓等组织内存在着一种非造血的干细胞——间充质干细胞，它可以在体内和体外被诱导，分化为骨细胞、软骨细胞、肌腱细胞、肌肉细胞和脂肪细胞等，具有多潜能的分化特性，而且比较易于提取和培养。随着肌腱组织工程理论和技术的不断发展，间充质干细胞的应用前景越来越广泛，并且发挥着重要的作用。就肌腱组织工程进行概述，对间充质干细胞的一般性质、来源以及将间充质干细胞作为种子细胞用于肌腱组织工程的进展等方面加以综述，并展望其发展前景。     

新型可降解聚合物聚乙二醇对苯二甲酸酯/聚对苯二甲酸丁二醇酯的细胞相容性研究

目的：研究新型可降解聚合物聚乙二醇对苯二甲酸酯／聚对苯二甲酸丁二醇酯(PEGT／PBT)的人脐静脉内皮细胞(HUVEC)相容性，对其在组织工程血管中的应用进行探讨。方法：对PEGT／PBT进行细胞毒性评价。观察并检测HUVEC在PEGB／PBT、Ⅰ型胶原改性(Col-)的PEGT／PBT、纤维连接蛋白改性(Fn-)的PEGT／PBT上的粘附和增殖，对细胞在粘附过程中的粘着斑蛋白进行免疫荧光染色观察。结果：PEGT／PBT细胞毒性不大于1级，能支持脐静脉内皮细胞的粘附和增殖。纤维连接蛋白和Ⅰ型胶原处理可促进HLIVEC在PEGT／PBT膜上的增殖，而且纤维连接蛋白可增加HUVEC在PEGT／PBT上20min、2h的粘附率，并促进细胞形成局部粘附结构。结论：新型可降解聚合物PEGT／PBT具有良好的血管细胞相容性，对其在组织工程血管中的应用值得进一步开发研究。     

尿道修复材料的研究及应用进展

尿道修复材料是尿道修复重建成败的关键,将尿道的修复材料分为自体组织材料、人工合成材料及组织工程化材料,从实验室和临床2方面对尿道修复材料的研究及应用进展进行综述.