应用旋转生物反应器批量制备拟胚体的研究

以小鼠胚胎干细胞(ES-D3)为模型,应用新型细胞培养系统——STLV型旋转生物反应器(rotarycellculturesystem,RCCS)建立一种批量制备拟胚体(embryoidbodies,EBs)的新方法,研究不同细胞接种密度及培养时间对RCCS内EBs产生效率的影响。为了进一步研究该制备方法是否对EBs的分化潜能产生影响,对照传统方法制备的EBs,利用形态学及RT-PCR方法测定经旋转生物反应器制备的EBs在自发性或诱导条件下(1%DMSO)向心肌细胞的分化能力。结果表明:ES-D3在RCCS内能够高效形成EBs,与传统的直接悬浮法比较,其EBs的形成效率可达到后者的2倍。1×104个/ml为最佳细胞接种密度,培养时间也是在RCCS制备EBs过程中的重要因素之一,培养第4~5天为最佳收获EBs的时间。与悬滴法制备的EBs比较,该方法制备的EBs分化为心肌细胞的潜能未改变。由此,应用旋转生物反应器可以高效制备EBs,该方法制备的EBs可以用于发育生物学等基础及应用领域的相关研究。     

Bi-zonal cartilaginous tissues engineered in a rotary cell culture system

In this study, we aimed at validating a rotary cell culture system (RCCS) bioreactor with medium recirculation and external oxygenation, for cartilage tissue engineering. Primary bovine and human culture-expanded chondrocytes were seeded into non-woven meshes of esterified hyaluronan (HYAFF-11), and the resulting constructs were cultured statically or in the RCCS, in the presence of insulin and TGFbeta3, for up to 4 weeks. Culture in the RCCS did not induce significant differences in the contents of glycosaminoglycans (GAG) and collagen deposited, but markedly affected their distribution. In contrast to statically grown tissues, engineered cartilage cultured in the RCCS had a bi-zonal structure, consisting of an outgrowing fibrous capsule deficient in GAG and rich in collagen, and an inner region more positively stained for GAG. Structurally, trends were similar using primary bovine or expanded human chondrocytes, although the human cells deposited inferior amounts of matrix. The use of the presented RCCS, in conjunction with the described medium composition, has the potential to generate bi-zonal tissues with features qualitatively resembling the native meniscus.     

Transplantation of engineered bone tissue using a rotary three-dimensional culture system

Bone is a complex, highly structured, mechanically active, three-dimensional (3-D) tissue composed of cellular and matrix elements. We previously published a report on in situ collagen gelation using a rotary 3-D culture system (CG–RC system) for the construction of large tissue specimens. The objective of the current study was to evaluate the feasibility of bone tissue engineering using our CG–RC system. Osteoblasts from the calvaria of newborn Wistar rats were cultured in the CG–RC system for up to 3 wk. The engineered 3-D tissues were implanted into the backs of nude mice and calvarial round bone defects in Wistar rats. Cell metabolic activity, mineralization, and bone-related proteins were measured in vitro in the engineered 3-D tissues. Also, the in vivo histological features of the transplanted, engineered 3-D tissues were evaluated in the animal models. We found that metabolic activity increased in the engineered 3-D tissues during cultivation, and that sufficient mineralization occurred during the 3 wk in the CG–RC system in vitro. One mo posttransplantation, the transplants to nude mice remained mineralized and were well invaded by host vasculature. Of particular interest, 2 mo posttransplantation, the transplants into the calvarial bone defects of rats were replaced by new mature bone. Thus, this study shows that large 3-D osseous tissue could be produced in vitro and that the engineered 3-D tissue had in vivo osteoinductive potential when transplanted into ectopic locations and into bone defects. Therefore, this system should be a useful model for bone tissue engineering.     

Oxygen gradients correlate with cell density and cell viability in engineered cardiac tissue

For clinical utility, cardiac grafts should be thick and compact, and contain physiologic density of metabolically active, differentiated cells. This involves the need to control the levels of nutrients, and most critically oxygen, throughout the construct volume. Most culture systems involve diffusional transport within the constructs, a situation associated with gradients of oxygen concentration, cell density, cell viability, and function. The goal of our study was to measure diffusional gradients of oxygen in statically cultured cardiac constructs, and to correlate oxygen gradients to the spatial distributions of cell number and cell viability. Using microelectrodes, we measured oxygen distribution in a disc-shaped constructs (3.6 mm diameter, 1.8 mm thickness) based on neonatal rat cardiomyocytes cultured on collagen scaffolds for 16 days in static dishes. To rationalize experimental data, a mathematical model of oxygen distribution was derived as a function of cell density, viability, and spatial position within the construct. Oxygen concentration and cell viability decreased linearly and the live cell density decreased exponentially with the distance from the construct surface. Physiological density of live cells was present only within the first 128 microm of the construct thickness. Medium flow significantly increased oxygen concentration within the construct, correlating with the improved tissue properties observed for constructs cultured in convectively mixed bioreactors.     

In situ collagen gelation: a new method for constructing large tissue in rotary culture vessels

In situ collagen gelation is a method that combines a static three-dimensional culture technique with rotating bioreactors. This method was designed for large dense tissue engineering ex vivo. To challenge the current limitations on size, we combined the static collagen gel embedding method with high-aspect ratio rotating bioreactors. Rat calvarial cells in gelated collagens were cultured in rotating vessels with 5 mM beta-glycerophosphate-containing medium for 1, 2, or 3 wk and then analyzed for cell morphology, cell distribution, and viability, as well as for contraction of the collagen gel. The size of collagen gels with rat calvarial cells averaged 2.8 cm in diameter x 0.25 cm in thickness at the end of 3 wk. Scanning electron microscopy and laser scanning confocal microscopy of collagen gels revealed a homogeneous distribution of living cells. Despite the barrier effects from induced calcification, in collagen gels, cell metabolic activity (alkaline phosphatase assay and 3-[4,5-dimethyl-2-thiazolyl]-2,5-diphenyl-2H-tetrazolium bromide assay) increased over the 3 wk, and cell viability (trypan blue exclusion and flow cytometry analysis) remained at about 90% at the end of 3 wk. Based on our results, we determined that in situ collagen gelation provides a feasible method for engineering large dense tissue ex vivo.     

组织培养中畸形胚状体及超度含水态苗的研究

畸形胚状和超度含水态苗是组织培养中常见的2种形态、生理异常现象,由于其难以发育成苗或很难移栽成活而严重影响组织培养的成功率。概述了这2种畸形现象的的形态特征及防止方法等,并讨论了应进一步研究的问题。     

Rapid pacing of embryoid bodies impairs mitochondrial ATP synthesis by a calcium-dependent mechanism--a model of in vitro differentiated cardiomyocytes to study molecular effects of tachycardia

Tachycardia may cause substantial molecular and ultrastructural alterations in cardiac tissue. The underlying pathophysiology has not been fully explored. The purpose of this study was (I) to validate a three-dimensional in vitro pacing model, (II) to examine the effect of rapid pacing on mitochondrial function in intact cells, and (III) to evaluate the involvement of L-type-channel-mediated calcium influx in alterations of mitochondria in cardiomyocytes during rapid pacing. In vitro differentiated cardiomyocytes from P19 cells that formed embryoid bodies were paced for 24 h with 0.6 and 2.0 Hz. Pacing at 2.0 Hz increased mRNA expression and phosphorylation of ERK1/2 and caused cellular hypertrophy, indicated by increased protein/DNA ratio, and oxidative stress measured as loss of cellular thiols. Rapid pacing additionally provoked structural alterations of mitochondria. All these changes are known to occur in vivo during atrial fibrillation. The structural alterations of mitochondria were accompanied by limitation of ATP production as evidenced by decreased endogenous respiration in combination with decreased ATP levels in intact cells. Inhibition of calcium inward current with verapamil protected against hypertrophic response and oxidative stress. Verapamil ameliorated morphological changes and dysfunction of mitochondria. In conclusion, rapid pacing-dependent changes in calcium inward current via L-type channels mediate both oxidative stress and mitochondrial dysfunction. The in vitro pacing model presented here reflects changes occurring during tachycardia and, thus, allows functional analyses of the signaling pathways involved.     

A flexible bioreactor system for constructing in vitro tissue and organ models

To develop in vitro models of cells, tissues and organs we have designed and realized a series of cell culture chambers. Each chamber is purpose designed to simulate a particular feature of the in vivo environment. The bioreactor system is user friendly, and the chambers are easy to produce, sterilize and assemble. In addition they can be connected together to simulate inter-organ or tissue cross-talk. Here we discuss the design philosophy of the bioreactor system and then describe its construction. Preliminary results of validation tests obtained with hepatocytes and endothelial cells are also reported. The results show that endothelial cells are extremely sensitive to small levels of shear stress and that the presence of heterotypic signals from endothelial cells enhances the endogenous metabolic function of hepatocytes.     

应用旋转生物反应器培养小鼠胚胎干细胞的初步研究

目的 应用旋转生物反应器(RCCS)和微载体培养体系尝试建立一种实现批量培养干细胞的新方法.方法 应用RCCS和微载体培养体系对小鼠胚胎干细胞(mESCs)进行体外培养扩增,定期收集细胞样品,镜下观察mESCs在RCCS生长的形态特征,并定量绘制细胞生长曲线,利用MATLAB软件计算细胞生长参数并对照平面培养体系,利用H&E染色、免疫荧光及RT-PCR技术对RCCS内培养的mESCs的细胞形态,未分化标志蛋白(SSEA-1)和标志基因(oct-4)的表达进行定性或半定量分析.结果 mESCs可在RCCS内以贴附于微载体表面的形式实现三维生长,其生长增殖状态良好,且伴随培养时间的延长,SSEA-1蛋白及oct-4 基因的表达水平逐渐降低.这表明RCCS内培养扩增的mESCs逐渐走向分化,该分化进程同步于平面对照培养体系.结论 RCCS可以为mESCs的体外规模化扩增培养提供良好的培养体系.     

Mathematical model of oxygen distribution in engineered cardiac tissue with parallel channel array perfused with culture medium containing oxygen carriers

A steady-state model of oxygen distribution in a cardiac tissue construct with a parallel channel array was developed and solved for a set of parameters using the finite element method and commercial software (FEMLAB). The effects of an oxygen carrier [Oxygent; 32% volume perfluorocarbon (PFC) emulsion] were evaluated. The parallel channel array mimics the in vivo capillary tissue bed, and the PFC emulsion has a similar role as the natural oxygen carrier hemoglobin in increasing total oxygen content. The construct was divided into an array of cylindrical domains with a channel in the center and tissue space surrounding the channel. In the channel, the main modes of mass transfer were axial convection and radial diffusion. In the tissue region, mass transfer was by axial and radial diffusion, and the consumption of oxygen was by Michaelis-Menten kinetics. Neumann boundary conditions were imposed at the channel centerline and the half distance between the domains. Supplementation of culture medium by PFC emulsion improved mass transport by increasing convective term and effective diffusivity of culture medium. The model was first implemented for the following set of experimentally obtained parameters: construct thickness of 0.2 cm, channel diameter of 330 mum, channel center-to-center spacingof 700 microm, and average linear velocity per channel of 0.049 cm/s, in conjunction with PFC supplemented and unsupplemented culture medium. Subsequently, the model was used to define favorable scaffold geometry and flow conditions necessary to cultivate cardiac constructs of high cell density (10(8) cells/ml) and clinically relevant thickness (0.5 cm). In future work, the model can be utilized as a tool for optimization of scaffold geometry and flow conditions.     

Morphological criteria for the in vitro differentiation of embryoid bodies produced by a transplantable teratoma of mice

Embryoid bodies are produced when a transplantable testicular teratoma from strain 129 mice is serially passaged in the peritoneal cavity of these mice. These bodies are roughly spherical containing two morphologically distinct cell types. Scanning and transmission electron microscopy have been employed to show that the endodermal cells of embryoid bodies, like those of the mouse embryo, are on the outer surface and have highly convoluted surfaces containing numerous microvilli-like projections. The inner, embryonal carcinoma cells, are the pluripotent stem cells of this tumor. Intracisternal A-type particles have been observed in electron micrographs and are almost exclusively located in the endodermal cells of the embryoid bodies. The A-type complement-fixing antigen has been identified in extracts prepared from this tumor. When embryoid bodies are placed in culture and allowed to attach to the surface of a petri dish, a large number of new morphologically distinct cell types appear. Attachment to the petri dish surface is required for the generation of these new cell types. Cells of similar morphology in culture, display a distinctly “clonal” distribution on the petri dish surface.     

Genetical analysis of in vitro cell and tissue culture response in potato

The genetics of tissue culture response in potato has been examined by analysing a sample of dihaploids (2n=2x=24) extracted from tetraploid parents (4n=4x=48). The genotypes were screened for rate of nodal multiplication, in vitro tuberisation, regeneration from leaf discs and protoplast plating efficiency. Significant differences were detected between dihaploids for the traits measured and this indicates that tissue culture response in the tetraploid parents must be in the heterozygous condition. Estimates of the broad sense heritabilities were calculated together with the number of genes or effective factors involved in the control of the traits. These estimates indicate that tissue culture response in potato is under relatively simple genetic control and blocks of genes may be located on specific chromosomes. The inheritance of RFLP markers in the segregating dihaploid population was also monitored and the potential of using molecular markers linked to gene(s) controlling tissue culture response is discussed.     

In vitro culture increases mechanical stability of human tissue engineered cartilage constructs by prevention of microscale scaffold buckling

Many studies have measured the global compressive properties of tissue engineered (TE) cartilage grown on porous scaffolds. Such scaffolds are known to exhibit strain softening due to local buckling under loading. As matrix is deposited onto these scaffolds, the global compressive properties increase. However the relationship between the amount and distribution of matrix in the scaffold and local buckling is unknown. To address this knowledge gap, we studied how local strain and construct buckling in human TE constructs changes over culture times and GAG content. Confocal elastography techniques and digital image correlation (DIC) were used to measure and record buckling modes and local strains. Receiver operating characteristic (ROC) curves were used to quantify construct buckling. The results from the ROC analysis were placed into Kaplan-Meier survival function curves to establish the probability that any point in a construct buckled. These analysis techniques revealed the presence of buckling at early time points, but bending at later time points. An inverse correlation was observed between the probability of buckling and the total GAG content of each construct. This data suggests that increased GAG content prevents the onset of construct buckling and improves the microscale compressive tissue properties. This increase in GAG deposition leads to enhanced global compressive properties by prevention of microscale buckling.     

Surface coating materials regulates the attachment and differentiation of mouse embryonic stem cell derived embryoid bodies into mesoderm at culture conditions

Cytotechnology - Pluripotent stem cells as a promising cell source with unlimited proliferation and differentiation capacity hold great promise for cell-based therapies in regenerative medicine....     

Rapid propagation of agave by in vitro tissue culture

A procedure for rapid propagation of Agave (A. cantala Roxb., A. fourcroydes Lem. and A. sisalana Perrine, (Agavaceae) have been developed. The explants were excised from stolon plantlets, sterilized and cultivated on Murashige and Skoog (MS) basal medium containing 2% sucrose, 10% coconut water and 0.8% agar. The addition of following combination of growth substances—0.075 mgl^-1 naphthalenacetic acid (NAA)+0.1 mgl^-1 indolylbutyric acid (IBA)+0.5 mgl^-1 kinetin (KIN) caused an extensive proliferation of multiple shoot primordia. Subcultures of these on the same medium were successful for the multiplication with an index of 3–4 times per 4 weeks subculture period. Shoots were rooted on hormone free MS medium and then transferred into a sand bed for acclimation before field planting.     

Migratory behavior of cardiac cushion tissue cells in a collagen-lattice culture system

A culture system was devised for the study of factors which influence the migration of cardiac cushion tissue cells. Explants of isolated chick atrioventricular canal cushions were placed on hydrated collagen lattices. Cells grew out of the explants from the endocardium and across the surface of the collagen lattices. During further incubation, mesenchyme-type cells seeded from the surface population into the underlying collagen matrix. These cells were morphologically similar to the mesenchymal cushion tissue cells which are derived from the endocardium and which migrate into and through the cardiac jelly matrix in the embryonic heart. The events observed in the culture system mimicked those occurring in the developing chick atrioventricular cushion.     

Long-term culture of tissue engineered cartilage in a perfused chamber with mechanical stimulation

One approach to functional tissue engineering of cartilage is to utilize bioreactors to provide environmental conditions that stimulate chondrogenesis in cells cultured on biomaterial scaffolds. We report the combined use of a three-dimensional in vitro model and a novel bioreactor with perfusion of culture medium and mechanical stimulation in long-term studies of cartilage development and function. To engineer cartilage, scaffolds made of a non-woven mesh of polyglycolic acid (PGA) were seeded with bovine calf articular chondrocytes, cultured for an initial 30-day period under free swelling conditions, and cultured for an additional 37 day period in one of the three groups: (1) free-swelling, (2) static compression (on 24 h/day, strain control, static offset 10%), and (3) dynamic compression (on 1 h/day; off 23 h/day; strain control, static offset 2%, dynamic strain amplitude 5%; frequency 0.3 Hz). Constructs were sampled at timed intervals and assessed with respect to structure, biochemical composition, and mechanical function. Mechanical simulation had little effect on the compositions, morphologies and on mechanical properties of construct interiors discs, but it resulted in distincly different properties of the peripheral rings and face sides. Contructs cultured with mechanical loading maintained their cylindrical shape with flat and parallel top and bottom surfaces, and retained larger amounts of GAG. The modular bioreactor system with medium perfusion and mechanical loading can be utilized to define the conditions of cultivation for functional tissue engineering of cartilage.     

Comparative study on in vitro stationary culture system or superfusion culture system of cow mammary tissue]

Dairy cow mammary tissue was cultured in superfusion system or stationary system, and the influence of these two methods in the activity and ultrastructure of tissue was investigated according to LDH vigor, trypan blue dying, agrose gel electrophoresis, transmission microscope observation. The results showed that the mammary tissue cultured in superfusion system could keep normal tissue activity and ultrastructure within 12-60 h in DMEM plus 10% calf serum, while mammary tissue stationary culture could keep normal tissue activity and ultrastructure within 60-108 h. Both culture systems had some advantages and disadvantages.     

Wnt2 coordinates the commitment of mesoderm to hematopoietic, endothelial, and cardiac lineages in embryoid bodies

Our recent gene expression profiling analyses demonstrated that Wnt2 is highly expressed in Flk1(+) cells, which serve as common progenitors of endothelial cells, blood cells, and mural cells. In this report, we characterize the role of Wnt2 in mesoderm development during embryonic stem (ES) cell differentiation by creating ES cell lines in which Wnt2 was deleted. Wnt2(-/-) embryoid bodies (EBs) generated increased numbers of Flk1(+) cells and blast colony-forming cells compared with wild-type EBs, and had higher Flk1 expression at comparable stages of differentiation. Although Flk1(+) cells were increased, we found that endothelial cell and terminal cardiomyocyte differentiation was impaired, but hematopoietic cell differentiation was enhanced and smooth muscle cell differentiation was unchanged in Wnt2(-/-) EBs. Later stage Wnt2(-/-) EBs had either lower or undetectable expression of endothelial and cardiac genes compared with wild-type EBs. Consistently, vascular plexi were poorly formed and neither beating cardiomyocytes nor alpha-actinin-staining cells were detectable in later stage Wnt2(-/-) EBs. In contrast, hematopoietic cell gene expression was upregulated, and the number of hematopoietic progenitor colonies was significantly enhanced in Wnt2(-/-) EBs. Our data indicate that Wnt2 functions at multiple stages of development during ES cell differentiation and during the commitment and diversification of mesoderm: as a negative regulator for hemangioblast differentiation and hematopoiesis but alternatively as a positive regulator for endothelial and terminal cardiomyocyte differentiation.     

Biochemical and morphological effects of hypoxic environment on human embryonic stem cells in long-term culture and differentiating embryoid bodies

The mammalian reproductive tract is known to contain 1.5–5.3% oxygen (O₂), but human embryonic stem cells (hESCs) derived from preimplantation embryos are typically cultured under 21% O₂ tension. The aim of this study was to investigate the effects of O₂ tension on the long-term culture of hESCs and on cell-fate determination during early differentiation. hESCs and embryoid bodies (EBs) were grown under different O₂ tensions (3, 12, and 21% O₂). The expression of markers associated with pluripotency, embryonic germ layers, and hypoxia was analyzed using RTPCR, immunostaining, and Western blotting. Proliferation, apoptosis, and chromosomal aberrations were examined using BrdU incorporation, caspase-3 immunostaining, and karyotype analysis, respectively. Structural and morphological changes of EBs under different O₂ tensions were comparatively examined using azan- and hematoxylineosin staining, and scanning and transmission electron microscopy. Mild hypoxia (12% O₂) increased the number of cells expressing Oct4/Nanog and reduced BrdU incorporation and aneuploidy. The percentage of cells positive for active caspase-3, which was high during normoxia (21% O₂), gradually decreased when hESCs were continuously cultured under mild hypoxia. EBs subjected to hypoxia (3% O₂) exhibited well-differentiated microvilli on their surface, secreted high levels of collagen, and showed enhanced differentiation into primitive endoderm. These changes were associated with increased expression of Foxa2, Sox17, AFP, and GATA4 on the EB periphery. Our data suggest that mild hypoxia facilitates the slow mitotic division of hESCs in long-term culture and reduces the frequency of chromosomal abnormalities and apoptosis. In addition, hypoxia promotes the differentiation of EBs into extraembryonic endoderm.