微重力组织工程的产生与发展

概述了微重力组织工程的产生与发展趋势。动物细胞培养技术为研究细胞的形态、结构、功能与遗传特性 ,揭示细胞分裂、组织分化、器官组织形成等生命科学领域的基本问题发挥了巨大作用 ;大规模动物细胞培养技术已广泛应用于生物制药、生产疫苗以及生物学诊断试剂。但是 ,常规培养技术无法实现由细胞重建组织这一构想。微重力组织工程利用旋转培养器产生的微重力环境与动物细胞培养技术相结合 ,使组织重建成为可能 ,成为生命科学发展史上的一个新的里程碑。     

模拟微重力条件下心肌细胞的体外三维固定化培养

观察心肌细胞体外培养形成三维(3D)组织结构的能力和过程及心肌细胞在模拟微重力状态下的3D固定化培养效果。应用酶消化法从新生的乳鼠心室肌组织获取心肌细胞,以Cytodex3为心肌细胞的3D固定化培养载体,将心肌细胞固定化培养于Spinnerflask中,用扫描电镜观察心肌细胞体外培养形成的3D组织结构;以心肌细胞的代谢效率和细胞搏动强度为观察指标,比较心肌细胞在Spinnerflask及HARV(highaspectratevessel)生物反应器中3D固定化培养的差异。结果显示,心肌细胞不仅能贴附于Cytodex3上生长,且形成了具有同步自律收缩的3D组织样结构;心肌细胞在两种不同培养体系中的细胞接种效率和细胞形态没有明显差异,培养于HARV中的心肌细胞的代谢效率和细胞搏动强度均明显高于Spinnerflask培养体系。体外培养的乳鼠心肌细胞具有形成同步自律收缩的3D组织结构的能力;模拟微重力的培养环境有利于改善心肌细胞3D组织样培养物的代谢和功能 。     

联合细胞培养在组织工程血管化中的应用

自从1987年正式提出组织工程这一概念来以来,培养具有生物学活性组织器官替代物始终是组织工程学的发展方向。目前,虽然一些工程化组织如皮肤、软骨等已被成功构建,并应用于临床,但其他工程化组织如心脏、骨骼肌、肝脏等体积大、功能复杂,移植后难以及时建立血液供应。而及时建立的血管网络对组织器官的存活与功能实现至关重要。为此,国内外一些实验室采用联合细胞培养的方法,观察不同细胞间的相互作用对血管形成的影响。结果表明,联合细胞培养在血管的形成、稳定和成熟方面起着重要作用。     

红豆杉器官,组织,细胞培养和基因工程的研究进展

本文综述了红豆杉器官、组织、细胞培养和基因工程的研究文献,并对这些领域存在的问题及其发展前景进行了讨论。     

模拟微重力条件下大鼠肝细胞的三维培养及其功能

采用肝脏原位灌流法分离大鼠肝细胞,以血纤维蛋白膜作支架,在RWVB回转器提供的模拟微重力条件下,对肝细胞进行三维培养。肝细胞经连续培养28h后,细胞仍呈球状,并获得了三维培养条件下大鼠肝细胞团（约为200－300个／细胞团）。三维培养的肝细胞在培养期间具有持续分泌ALB和TBA的功能,而单层培养的肝细胞仅在接种后18d内具有一定分泌功能,之后细胞逐渐衰老死亡。三维培养的肝细胞培养至28d时仍可检测到G6PD,PFK,PGM三种糖代谢关键酶基因的转录,而单层培养的肝细胞在接种后第6d就检测不到PFK,PGM的转录。结果表明,模拟微重力条件下三维培养的肝细胞在培养期间不仅能维持正常细胞形态,而且具有稳定的分泌功能和糖代谢功能,而单层培养的肝细胞分泌功能显著下降,糖代谢功能出现异常。     

新型旋转壁式生物反应器内三维组织工程骨的构建

利用微载体悬浮培养法将成骨细胞在旋转壁式生物反应器内进行大规模扩增,并检测细胞的组织形态和生物功能.然后以此作为种子细胞,分别以2×10⁶个/ml和1×10⁶个/ml两种密度接种到支架材料上,于旋转壁式生物反应器(RWV)内进行三维组织工程骨的构建.并将所构建的骨组织分别进行倒置显微镜(inverted microscope)、扫描电镜(SEM)、碱性磷酸酶(ALP)、矿化结构和AO/EB双重荧光染色等生物学性能检测,以及对培养过程的营养物质代谢情况进行监控和分析.结果表明,在RWV中培养的骨组织生长良好,分泌大量胶原纤维,并有矿化基质和新骨样组织形成. 由上述结果可断定,通过RWV内部流体对流所产生的应力刺激,可提高成骨细胞碱性磷酸酶的活性表达,并加速矿化结节的形成,从而完成成骨细胞的快速增殖与分化以及工程化组织的三维构建.     

构建大段组织工程骨的新型生物反应器的设计与制造

目的:设计、制造一种新的灌注式生物反应器,专门用于高效地构建大体积、β-磷酸三钙组织工程骨。方法:在普通模式灌注生物反应器的灌流室内生成间断性低压环境(-0.01 mpa,0.5 Hz),用材料色素颗粒洗脱实验进行验证后,将复合兔骨髓间充质干细胞的大段、管状β-磷酸三钙材料分别在静态、反应器内常压灌注和间断低压灌注三种环境下培养4周。期间收集培养液检测葡萄糖日耗量、细胞活力(MTT比色法)、碱性磷酸酶比活性、骨桥蛋白水平,并进行硬组织切片检查。结果:色素颗粒洗脱实验证明,间断性低压可以改善低流量液流在材料内的分布;在培养2周和4周时,负压灌注组日均葡萄糖消耗量和细胞活力均显著高于常压灌注组:(t=20.254 P<0.05,t=64.794 P<0.05)及(t=17.586 P<0.05,t=7.583 P<0.05);碱性磷酸酶(ALP)比活性测定和骨桥蛋白水平(OPN)反映间断低压灌注组中骨髓间充质细胞向成骨细胞分化效率更高,但高峰相晚于常压灌注组和静态培养组;在间断低压灌注组中材料深部的占孔率最高,并且分布更均匀。结论:此新型灌注式生物反应器适用于构建大体积、特殊构型组织工程骨;其高效的促进细胞增殖效应可减少初始复合的种子细胞数量,缩短构建周期。     

细胞三维培养：组织工程的关键技术突破口

组织工程是有望从根本上解决组织,器官缺损或失能的医学难题的一门新兴边缘学科,组织,器官发育的细胞和分子机制的进一步揭示和体外构建工程组织,器官的细胞培养技术的进步将使组织工程在新的千年成为广泛应用的新的治疗模式。细胞三维培养要成为体外构建工程组织,器官的成熟技术体系需先解决以下问题;（1）细胞;（2）生物材料;（3）培养基;（4）培养装置;（5）异型细胞的共培养;（6）细胞三维培养物血管化。     

细胞培养系中的编程性细胞死亡

简要介绍了生物反应器中细胞培养系的编程性死亡和几种可能的控制细胞编程性死亡的途径。     

观赏植物组织培养与基因工程研究进展(综述)

本文综述近年来观赏植物组织培养和基因工程的研究进展。     

Microgravity tissue engineering

Summary Tissue engineering studies were done using isolated cells, three-dimensional polymer scaffolds, and rotating bioreactors operated under conditions of simulated microgravity. In particular, vessel rotation speed was adjusted such that 10 mm diameter × 2 mm thick cell-polymer constructs were cultivated in a state of continuous free-fall. Feasibility was demonstrated for two different cell types: cartilage and heart. Conditions of simulated microgravity promoted the formation of cartilaginous constructs consisting of round cells, collagen and glycosaminoglycan (GAG), and cardiac tissue constructs consisting of elongated cells that contracted spontaneously and synchronously. Potential advantages of using a simulated microgravity environment for tissue engineering were demonstrated by comparing the compositions of cartilaginous constructs grown under four different in vitro culture conditions: simulated microgravity in rotating bioreactors, solid body rotation in rotating bioreactors, turbulent mixing in spinner flasks, and orbital mixing in petri dishes. Constructs grown in simulated microgravity contained the highest fractions of total regenerated tissue (as a percent of construct dry weight) and of GAG, the component required for cartilage to withstand compressive force.     

植物组织培养生物反应器技术研究进展

从植物大规模组织培养的特点、反应器类型和反应器中微环境等方面介绍了生物反应器技术在药用植物微繁殖和天然产物细胞生产中的研究进展。     

Use of an adaptable cell culture kit for performing lymphocyte and monocyte cell cultures in microgravity

The results of experiments performed in recent years on board facilities such as the Space Shuttle/Spacelab have demonstrated that many cell systems, ranging from simple bacteria to mammalian cells, are sensitive to the microgravity environment, suggesting gravity affects fundamental cellular processes. However, performing well-controlled experiments aboard spacecraft offers unique challenges to the cell biologist. Although systems such as the European ‘Biorack’ provide generic experiment facilities including an incubator, on-board 1-g reference centrifuge, and contained area for manipulations, the experimenter must still establish a system for performing cell culture experiments that is compatible with the constraints of spaceflight. Two different cell culture kits developed by the French Space Agency, CNES, were recently used to perform a series of experiments during four flights of the ‘Biorack’ facility aboard the Space Shuttle. The first unit, Generic Cell Activation Kit 1 (GCAK-1), contains six separate culture units per cassette, each consisting of a culture chamber, activator chamber, filtration system (permitting separation of cells from supernatent in-flight), injection port, and supernatent collection chamber. The second unit (GCAK-2) also contains six separate culture units, including a culture, activator, and fixation chambers. Both hardware units permit relatively complex cell culture manipulations without extensive use of spacecraft resources (crew time, volume, mass, power), or the need for excessive safety measures. Possible operations include stimulation of cultures with activators, separation of cells from supernatent, fixation/lysis, manipulation of radiolabelled reagents, and medium exchange. Investigations performed aboard the Space Shuttle in six different experiments used Jurkat, purified T-cells or U937 cells, the results of which are reported separately. We report here the behaviour of Jurkat and U937 cells in the GCAK hardware in ground- based investigations simulating the conditions expected in the flight experiment. Several parameters including cell concentration, time between cell loading and activation, and storage temperature on cell survival were examined to characterise cell response and optimise the experiments to be flown aboard the Space Shuttle. Results indicate that the objectives of the experiments could be met with delays up to 5 days between cell loading into the hardware and initial in flight experiment activation, without the need for medium exchange. Experiment hardware of this kind, which is adaptable to a wide range of cell types and can be easily interfaced to different spacecraft facilities, offers the possibility for a wide range of experimenters successfully and easily to utilise future flight opportunities. J. Cell. Biochem. 70:252–267, 1998. © 1998 Wiley-Liss, Inc.     

Neonatal rat heart cells cultured in simulated microgravity

Summary In vitro characteristics of cardiac cells cultured in simulated microgravity are reported. Tissue culture methods performed at unit gravity constrain cells to propagate, differentiate, and interact in a two-dimensional (2D) plane. Neonatal rat cardiac cells in 2D culture organize predominantly as bundles of cardiomyocytes with the intervening areas filled by nonmyocyte cell types. Such cardiac cell cultures respond predictably to the addition of exogenous compounds, and in many ways they represent an excellent in vitro model system. The gravity-induced 2D organization of the cells, however, does not accurately reflect the distribution of cells in the intact tissue. We have begun characterizations of a three-dimensional (3D) culturing system designed to mimic microgravity. The NASA- designed High-Aspect Ratio Vessel (HARV) bioreactors provide a low shear environment that allows cells to be cultured in static suspension. HARV-3D cultures were prepared on microcarrier beads and compared to control-2D cultures using a combination of microscopic and biochemical techniques. Both systems were uniformly inoculated and medium exchanged at standard intervals. Cells in control cultures adhered to the polystyrene surface of the tissue culture dishes and exhibited typical 2D organization. Cells cultured in HARVs adhered to microcarrier beads, the beads aggregated into defined clusters containing 8 to 15 beads per cluster, and the clusters exhibited distinct 3D layers: myocytes and fibroblasts appeared attached to the surfaces of beads and were overlaid by an outer cell type. In addition, cultures prepared in HARVs using alternative support matrices also displayed morphological formations not seen in control cultures. Generally, the cells prepared in HARV and control cultures were similar; however, the dramatic alterations in 3D organization recommend the HARV as an ideal vessel for the generation of tissuelike organizations of cardiac cells in vitro.     

Analysis of cell growth and diffusion in a scaffold for cartilage tissue engineering

Developments in tissue engineering over the past decade have offered promising future for the repair and reconstruction of damaged tissues. To regenerate three dimensional and weight-bearing implants, advances in biomaterials and manufacturing technologies prompted cell cultivations with natural or artificial scaffolds, in which cells are allowed to proliferate, migrate, and differentiate in vitro. In this article, we develop a mathematical model for cell growth in a porous scaffold. By treating the cell-scaffold construct as a porous medium, a continuum model is set up based on basic principles of mass conservation. In addition to cell growth kinetics, we incorporate cell diffusion in the model to describe the effects of cell random walks. Computational results are compared to experimental data found in the literature. With this model, we are able to investigate cell motility, heterogeneous cell distributions, and non-uniform seeding for tissue engineering applications. Results show that random walks tend to enhance uniform cell spreads in space, which in turn increases the probabilities for cells to acquire nutrients; therefore random walks are likely to be a positive contribution to the overall cell growth on scaffolds.     

Historical reflections on cell culture engineering

Cell culture engineering has enabled the commercial marketing of about a dozen human therapeutic products derived from rDNA technology and numerous monoclonal antibody products as well. A variety of technologies have proven useful in bringing products to the marketplace. Comparisons of the technologies available 15 years ago are contrasted with those available today. A number of improvements in unit operations have greatly improved the robustness of the processes during the past 15 years. Further evolution of the technology is expected in several directions driven by commercial and regulatory pressures. Some problems remain for the next generation of cell culture engineers to solve. This revised version was published online in August 2006 with corrections to the Cover Date.     

Use of microgravity bioreactors for development of an in vitro rat salivary gland cell culture model

During development, salivary gland (SG) cells both secrete factors which modulate cellular behavior and express specific hormone receptors. Whether SG cell growth is modulated by an autocrine epidermal growth factor (EGF) receptor-mediated signal transduction pathway is not clearly understood. SG tissue is the synthesis site for functionally distinct products including growth factors, digestive enzymes, and homeostasis maintaining factors. Historically, SG cells have proven difficult to grow and may be only maintained as limited three-dimensional ductal-type structures in collagen gels or on reconstituted basement membrane gels. A novel approach to establishing primary rat SG cultures is use of microgravity bioreactors originally designed by NASA as low-shear culture systems for predicting cell growth and differentiation in the microgravity environment of space. These completely fluid-filled bioreactors, which are oriented horizontally and rotate, have proven advantageous for Earth-based culture of three-dimensional cell assemblies, tissue-like aggregates, and glandular structures. Use of microgravity bioreactors for establishing in vitro models to investigate steroid-mediated secretion of EGF by normal SG cells may also prove useful for the investigation of cancer and other salivary gland disorders. These microgravity bioreactors promise challenging opportunities for future applications in basic and applied cell research. © 1993 Wiley-Liss, Inc.     

Perfusion bioreactor system for human mesenchymal stem cell tissue engineering: dynamic cell seeding and construct development

Human mesenchymal stem cells (hMSCs) have great potential for therapeutic applications. A bioreactor system that supports long-term hMSCs growth and three-dimensional (3-D) tissue formation is an important technology for hMSC tissue engineering. A 3-D perfusion bioreactor system was designed using non-woven poly (ethylene terepthalate) (PET) fibrous matrices as scaffolds. The main features of the perfusion bioreactor system are its modular design and integrated seeding operation. Modular design of the bioreactor system allows the growth of multiple engineered tissue constructs and provides flexibility in harvesting the constructs at different time points. In this study, four chambers with three matrices in each were utilized for hMSC construct development. The dynamic depth filtration seeding operation is incorporated in the system by perfusing cell suspensions perpendicularly through the PET matrices, achieving a maximum seeding efficiency of 68%, and the operation effectively reduced the complexity of operation and the risk of contamination. Statistical analyses suggest that the cells are uniformly distributed in the matrices. After seeding, long-term construct cultivation was conducted by perfusing the media around the constructs from both sides of the matrices. Compared to the static cultures, a significantly higher cell density of 4.22 x 10(7) cell/mL was reached over a 40-day culture period. Cellular constructs at different positions in the flow chamber have statistically identical cell densities over the culture period. After expansion, the cells in the construct maintained the potential to differentiate into osteoblastic and adipogenic lineages at high cell density. The perfusion bioreactor system is amenable to multiple tissue engineered construct production, uniform tissue development, and yet is simple to operate and can be scaled up for potential clinical use. The results also demonstrate that the multi-lineage differentiation potential of hMSCs are preserved even after extensive expansion, thus indicating the potential of hMSCs for functional tissue construct development. The system has important applications in stem cell tissue engineering.