Tissue-engineered heart valve leaflets: an effective method for seeding autologous cells on scaffolds

BACKGROUND: A precondition for the successful formation of tissue-engineered heart valves is the generation of a proper matrix on biodegradable scaffolds over a limited period of time. The aim of this study was to find an effective method of seeding autologous cells on these scaffolds to create a new matrix for heart valves. METHODS: Myofibroblasts and endothelial cells were isolated and cultured from an ovine artery. A synthetic biodegradable scaffold consisting of polyglycolic and polylactic acids was seeded first with the myofibroblasts, then coated with endothelial cells. Three different methods of myofibroblast seeding were compared: I) daily seeding of myofibroblasts (1x10(6)) for ten days and culture for four days; II) seeding of myofibroblasts (1x10(7)) and culture for 14 days with the use of a simple medium; III) seeding of myofibroblasts (1x10(7)) with the use of a medium containing collagen and culture for 14 days. Light and electron microscopic analyses were performed. RESULTS: The group that used the medium containing collagen showed the best results in terms of seeding efficiency. CONCLUSION: Seeding autologous cells with a medium containing collagen onto the scaffold showed the largest cell population and might generate the best matrix on the scaffold.     

Engineering of a dermal equivalent: seeding and culturing fibroblasts in PEGT/PBT copolymer scaffolds

The engineering of dermal skin substitutes, using autologous fibroblasts, requires high seeding efficiencies, a homogeneous cell distribution in the scaffolds, and optimal culture conditions. Dynamic seeding in spinner flasks was used to seed and subsequently culture fibroblasts in three-dimensional scaffolds. Several seeding and culture variables were investigated. Simulation of medium movement with microspheres showed that three different regions existed in medium (outer, middle, and inner), where overall particle movement was different. In the middle region the flow was turbulent and scaffolds were best placed in this region. After fibroblast seeding, methylene blue staining and scanning electron microscopy analysis of the scaffolds showed that at a low stirring speed (20 rpm) fibroblasts attached mainly onto the upper part of the scaffold, and at 40 and 60 rpm fibroblasts attached and spread throughout the scaffolds. Measurements of total DNA content per scaffold showed that lower stirring speeds (20 and 40 rpm) resulted in significantly higher cell-seeding efficiencies (20 rpm, 99.8 +/- 11.3%; 40 rpm, 93.8 +/- 10.5%) compared with 60 rpm (85.9 +/- 5.3%). Seeding kinetics were comparable for all three speeds investigated. In subsequent studies, 40 rpm was chosen for seeding. Using initial cell numbers ranging from 0.3 x 10(6) to 1.5 x 10(6) fibroblasts per scaffold, seeding efficiencies higher than 85% were consistently found (n = 4). The culture of fibroblast-seeded scaffolds at different stirring speeds (10-80 rpm) showed that stirring speeds higher than 10 rpm significantly stimulated fibroblast proliferation and glycosaminoglycan and collagen deposition as compared with 10 rpm. After 21 days, scaffolds cultured at 80 rpm showed significantly more collagen deposition as compared with those maintained at lower speeds. In conclusion, to achieve high seeding efficiencies, uniform fibroblast distribution and tissue formation in a three-dimensional scaffold, fibroblasts can be dynamically seeded at 40 rpm and subsequently cultured at a stirring speed of 60-80 rpm in spinner flasks. This flexible system shows that it is feasible to tissue engineer autologous dermal substitutes in a clinically acceptable time frame.     

Native and DPPA cross-linked collagen sponges seeded with fetal bovine epiphyseal chondrocytes used for cartilage tissue engineering

Collagen-based biomaterials in the form of sponges (bovine type I collagen, both native and cross-linked by treatment with diphenylphosphorylazide, noted control and DPPA sponges respectively) were tested as three-dimensional scaffolds to support chondrocyte proliferation with maintenance of the phenotype in order to form neocartilage. Control and DPPA sponges were initially seeded with 10(6) or 10(7) foetal bovine epiphyseal chondrocytes and maintained for 4 weeks in culture under static conditions in RPMI/NCTC medium with 10% FCS and without addition of fresh ascorbic acid. Both supports were always present during the study and a partial decrease in size and weight was detected only with control sponges, both seeded and unseeded. Cell proliferation was only noted in the 10(6) cells-seeded sponges (4-fold increase after 4 weeks of culture). Specific cartilage collagens (types II and XI) were deposited in the matrix throughout the culture and traces of type I collagen were noticed only in the culture medium after 2-3 weeks and 4 weeks in the case of 10(6) and 10(7) cells-seeded sponges, respectively. Glycosaminoglycans accumulated in the matrix, up to 1.8 and 9.8% of total dry weight after one month with both seeding conditions, which was much lower than in the natural tissue. In the 10(7) cells-seeded sponges, mineral deposition, observed with unseeded sponges, was significantly decreased (2- to 3-fold). These in vitro results indicate that both collagen matrices can support the development of tissue engineered cartilage.     

血管组织工程支架材料的细胞相容性

背景：胶原与透明质酸均有利于组织培养中细胞的黏附、增殖和分化。 目的：观察血管内皮细胞、平滑肌细胞与胶原/透明质酸膜、明胶海绵的细胞相容性,并筛选最佳种植方法。 方法：将第3-5代兔血管平滑肌细胞种植在胶原/透明质酸膜(或明胶海绵)材料上,连续培养2周后将兔内皮细胞接种在平滑肌细胞-胶原/透明质酸膜(或明胶海绵)复合体上,并设置单纯平滑肌细胞与内皮细胞共同接种组。 结果与结论：①光镜和扫描电镜观察：细胞在两种材料上均随着培养时间,接种次数增加而生长加快,其中在胶原/透明质酸膜上的细胞生长更好,细胞连接更致密。②WST-1法检测：胶原/透明质酸膜组平滑肌细胞的黏附率及增殖率均高于明胶海绵组(P < 0.05),且细胞在材料上的生长随着接种次数的增加有不同程度提高。③³H-TDR掺入法检测DNA合成率：在胶原/透明质酸膜上的细胞DNA合成最高,明胶海绵上的较差。表明胶原/透明质酸膜具有较理想的细胞相容性,采用适当间隔、反复接种的方法可提高细胞的黏附和增殖。     

Engineering three-dimensional bone tissue in vitro using biodegradable scaffolds: investigating initial cell-seeding density and culture period

New three-dimensional (3D) scaffolds for bone tissue engineering have been developed throughout which bone cells grow, differentiate, and produce mineralized matrix. In this study, the percentage of cells anchoring to our polymer scaffolds as a function of initial cell seeding density was established; we then investigated bone tissue formation throughout our scaffolds as a function of initial cell seeding density and time in culture. Initial cell seeding densities ranging from 0.5 to 10 x 10(6) cells/cm(3) were seeded onto 3D scaffolds. After 1 h in culture, we determined that 25% of initial seeded cells had adhered to the scaffolds in static culture conditions. The cell-seeded scaffolds remained in culture for 3 and 6 weeks, to investigate the effect of initial cell seeding density on bone tissue formation in vitro. Further cultures using 1 x 10(6) cells/cm(3) were maintained for 1 h and 1, 2, 4, and 6 weeks to study bone tissue formation as a function of culture period. After 3 and 6 weeks in culture, scaffolds seeded with 1 x 10(6) cells/cm(3) showed similar tissue formation as those seeded with higher initial cell seeding densities. When initial cell seeding densities of 1 x 10(6) cells/cm(3) were used, osteocalcin immunolabeling indicative of osteoblast differentiation was seen throughout the scaffolds after only 2 weeks of culture. Von Kossa and tetracycline labeling, indicative of mineralization, occurred after 3 weeks. These results demonstrated that differentiated bone tissue was formed throughout 3D scaffolds after 2 weeks in culture using an optimized initial cell density, whereas mineralization of the tissue only occurred after 3 weeks. Furthermore, after 6 weeks in culture, newly formed bone tissue had replaced degrading polymer.     

Hydrogel optimization for cultured elastic chondrocytes seeded onto a polyglycolic acid scaffold

The purpose of this study was to compare the effect of different hydrogels on the production of tissue-engineered cartilage based on polyglycolic acid (PGA). Chondrocytes were isolated from adult sheep auricles. Alginate, Type I collagen, methylcellulose, and pluronic F127 hydrogels were evaluated, as were controls prepared without hydrogels. Proliferated chondrocytes were mixed with each hydrogel at 20 x 10(6) cells/mL and seeded onto PGA (1 x 1 x 0.2 cm, n = 60). The constructs were cultured with serum-free medium containing 5 ng/mL TGF-beta(2) and 5 ng/mL des(1-3)IGF-I in rotational bioreactors for up to 6 weeks. The cellular morphology, histology, and biochemistry were analyzed. Type I collagen, methylcellulose, and pluronic F127 displayed improved cartilage matrix deposition in terms of histology and biochemistry compared to alginate. It was not concluded that the combined seeding of chondrocytes and hydrogels on a PGA scaffold had significantly better effects than cell seeding without hydrogels. However, the histology and other useful findings in this ECM analyses suggested that Type I collagen and MC hydrogels were the best candidates for cartilage regeneration, because of their stimulation for chondrocyte proliferation in a three-dimensional culture as well as cartilage regeneration.     

A novel rat tail collagen type-I gel for the cultivation of human articular chondrocytes in low cell density

Collagen type-I matrix systems have gained growing importance as a cartilage repair device. However, most of the established matrix systems use collagen type-I of bovine origin seeded in high cell densities. Here we present a novel collagen type-I gel system made of rat tail collagen for the cultivation of human chondrocytes in low cell densities. Rat tail collagen type-I gel (CaReS, Arthro Kinetics, Esslingen, Germany) was seeded with human passage 2 chondrocytes in different cell densities to evaluate the optimal cell number. In vitro, the proliferation factor of low density cultures was more than threefold higher compared with high density cultures. After 6 weeks of in vitro cultivation, freshly prepared chondrocytes with an initial cell density of 2x10(5) cells/mL showed a proliferation factor of 33. A cell density of 2x10(5) cells/mL was chosen for in vitro and in vivo cultivation using the common nude mouse model as an in vivo system. Chondrocytes stayed viable as a Live/Dead fluorescence assay and TUNEL staining revealed. During in vitro cultivation, passage 0 cells partly dedifferentiated morphologically. In vivo, passage 0 cells maintained the chondrocyte phenotype and demonstrated an increased synthesis of collagen type-II protein and gene expression compared to passage 2 cells. Passage 2 cells did not redifferentiate in vivo. Cultivating a cell-seeded collagen gel of bovine origin as a control (AtelocollagenTM, Koken, Tokyo, Japan) did not lead to superior results with regard to cell morphology, col-II protein production and col-II gene expression. With the CaReS collagen gel system the best quality of repair tissue was obtained by seeding freshly isolated chondrocytes.     

A novel use of centrifugal force for cell seeding into porous scaffolds

A novel rotor was constructed to allow for the seeding of porous scaffolds via centrifugal force. Using cell seeding times of 10 min, this method placed significantly (roughly 3-fold) more cells into poly(glycolic acid) scaffolds than 24 h of spinner flask seeding or static seeding. There were no significant differences in the mitochondrial activity per cell between the 3 seeding methods. Cell distribution was noted to be homogeneous throughout the scaffold thickness for the centrifugation method, as opposed to surface seeding for the spinner flask method. Centrifugation was especially efficient at low cell concentrations (1.33 x 10(5) cells/ml). This system is useful for the seeding of biomaterials having cylindrical or planar geometries, and may be used under conditions that require low cell numbers and/or short seeding time periods.     

Capability of human umbilical cord blood progenitor-derived endothelial cells to form an efficient lining on a polyester vascular graft in vitro

One of the goals of vascular tissue engineering is to create functional conduits for small-diameter bypass grafting. The present biocompatibility study was undertaken to check the ability of cord blood progenitor-derived endothelial cells (PDECs) to take the place of endothelial cells in vascular tissue engineering. After isolation, culture and characterization of endothelial progenitor cells, the following parameters were explored, with a commercial knitted polyester prosthesis (Polymaille C, Laboratoires Pérouse, France) impregnated with collagen: cell adhesion and proliferation, colonization, cell retention on exposure to flow, and the ability of PDECs to be regulated by arterial shear stress via mRNA levels. PDECs were able to adhere to commercial collagen-coated vascular grafts in serum-free conditions, and were maintained but did not proliferate when seeded at 2.0 x 10(5) cm(-2). Cellularized conduits were analyzed by histology and histochemical staining, demonstrating collagen impregnation and the endothelial characteristics of the colonizing cells. Thirty-six hours after cell seeding the grafts were maintained for 6 h of either static conditions (controls) or application of pulsatile laminar shear stress, which restored the integrity of the monolayer. Finally, quantitative real-time RT-PCR analysis performed at 4 and 8 h from cells lining grafts showed that MMP1 mRNA only was increased at 4h whereas vWF, VE-cadherin and KDR were not significantly modified at 4 and 8 h. Our results show that human cord blood PDECs are capable of forming an efficient lining and to withstand shear stress.     

Proliferation and Osteogenic Differentiation of Mesenchymal Stem Cells Cultured onto Three Different Polymers <Emphasis Type="Italic">In Vitro</Emphasis>

In this study, the osteoinductive and cell-binding properties of three different resorbable polymers were evaluated by human mesenchymal stem cells (MSCs). MSCs were isolated, expanded, and cultivated onto resorbable D,D,L,L-polylactide (PLLA), collagen I/III, and polygalactin-910/polydioxanone (PGPD) scaffolds in vitro. To evaluate the influence of dexamethasone, ascorbic acid, and beta-glycerolphosphate (DAG) on osteoblast differentiation, MSCs were incubated in a DAG-enriched medium. After a 28-day period in vitro, the cellular loaded polymers were digested enzymatically by papain and HCl. The Ca(2+) content of the biomembranes was evaluated by an o-kresolphthalein-complexon reaction via photometer. A PicoGreen assay was performed for dsDNA quantification. Significant differences between the number of adherent MSCs were documented (collagen > PLLA > PGPD). Compared to the initial number of adherent cells, all biomaterials induced a significant decrease in cellular adherence after 28 days in vitro. The presence of DAG-enriched culture medium stimulated the cellular proliferation for PLLA and slightly for PGPD, whereas cell proliferation was inhibited when MSCs were cultivated onto collagen I/III. In comparison with the control groups, all biomaterials (PLLA, PGPD, and collagen I/III) showed a significant increase in local Ca(2+) accumulation under DAG stimulation after 28 days in vitro. Furthermore, collagen I/III and PLLA scaffolds showed osteoinductive properties without DAG stimulation. These results were verified by immunocytochemical stainings against osteoblast-typical markers (osteopontin and alkaline phosphatase) and completed by calcified matrix detection (von Kossa staining). MSCs were identified by CD105 and CD13 antigen expression. Corresponding to an absence of CD34, CD45, and collagen II expression, we found no chondrogenic or hematopoietic cell differentiation. The results indicate significant differences for the proliferation, differentiation, adherence, and Ca(2+) accumulation between the tested polymers in a MSC culture.     

Extracellular matrix protein gene expression of bovine chondrocytes cultured on resorbable scaffolds

It has been demonstrated that using cultured chondrocytes that have been seeded onto various biomatrices can enhance the quality of the articular cartilage repair tissue. As tissue-engineering becomes increasingly more complex there is a need to understand how a specific biomaterial may influence gene expression. In this study several commonly used scaffold materials for cartilage tissue engineering were evaluated with respect to their influence on matrix gene expression. Primary cultures of bovine chondrocytes were established in monolayer then seeded onto polylactic acid (PLLA), polyglycolic acid (PGA), collagen matrices. The induction of collagen type I, collagen type II, and aggrecan was observed at various time points on these biomaterials using RT-PCR. The collagen type I gene was upregulated on collagen scaffolds throughout the culture period. PLLA and PGA showed initial induction followed by downregulation. Monolayer culture did not induce collagen I message. Collagen II genes were selectively upregulated after 72 and 96 h post seeding depending the scaffold material. Monolayer culture had strong induction of collagen II. The aggrecan protein was consistently expressed in all scaffold materials cultures and monolayer.     

组织工程化肌腱种子细胞深低温保存的实验研究

对肌腱种子细胞进行深低温保存，研究保存过程中多个环节的影响因索对细胞存活率的影响及深低温保存对种子细胞生物学特性、胶原分泌功能的影响。实验结果表明二甲基亚砜是肌腱种子细胞深低温保存中比较好的抗冻保护剂；冻存后使用与培养时不同的营养血清处理对细胞有损害，可降低细胞存活率；在冷冻保存过程中，细胞存活率与细胞浓度有一定关系，浓度太低可能降低细胞存活率；细胞在冷冻保存时，降温速度对细胞存活率有影响，慢速的分步降温组细胞存活率明显高于直接人液氮的快速降温组；采用10％二甲基亚砜加15%小牛血清加75% DMEM配方保存肌腱种子细胞，对其分泌胶原功能无明显影响，对其生长曲线、细胞周期及染色体众数无明显改变，适于肌腱种子细胞的保存。     

The effect of dynamic culture conditions on endothelial cell seeding and retention on small diameter polyurethane vascular grafts

Due to the limited number of cells available in endothelial cell (EC) seeding of small diameter vascular grafts, high seeding rate and ideal proliferation are normally required and can be achieved by optimizing the EC seeding and culture procedures. In this study, by using rotational seeding at 0.16 rpm for 12 h in an incubator, 90% cells were successfully seeded on the polyurethane vascular grafts. Following a period of 72 h of static culture, the cell retention after 6 h of flushing could reach 90%. The retention was further enhanced after perfuse culture (9 cm/s). The optimal procedures to prepare a polyurethane vascular graft (4-mm i.d., 4 cm long) populated with firmly attached EC were therefore: (1) seeding the graft with 0.5 ml of cell suspension containing approximately 10(5) cells rotated at 0.16 rpm for 12 h; (2) culturing the seeded graft in static for 72 h; and (3) culturing the graft by perfusion (9 cm/s) for another 72 h to 7 days. These procedures consistently resulted in a graft covered with confluent vein EC that fully retained on the surface after 6 h of in vitro flushing.     

New experimental models for the in vitro reconstitution of human bladder mucosa

This study describes two experimental models for the in vitro reconstitution of the human bladder mucosa (neo-bladder): human urothelial stabilized cell lines were cultured on three-dimensional matrices, collagen or platelet-fibrin gels, containing murine fibroblast 3T3-J2 cells. Low-density seeding (2x10(4) cells/ml) of both normal (TCA-48) and neoplastic cell lines (TCA-47) on collagen matrix gave rise to isolated papillar colonies, while high-density seeding (3.75x10(6) cells/ml) led to the formation of wide pluristratified epithelial sheets, resembling the normal transitional epithelium. In contrast, high-density seeding (5x10(5) cells/ml) on platelet-fibrin matrix did not allow the formation of epithelial sheets: only isolated voluminous colonies of normal TCA-48 cells, and sparse and small colonies of neoplastic TCA-47 could be observed. Growth assays and cytotoxicity reduction tests showed that the growth inhibitory effect of platelet-fibrin gel on urothelial cells was probably due to the aspecific activation of the complement contained in the plasmatic fraction, whose precipitation forms fibrin-glue. Collectively, these findings allow us to draw the following conclusions: i) neobladders obtained by culturing urothelial cells on collagen matrix reproduce normal bladder mucosa and could be utilized in pharmacological studies; and ii) platelet-fibrin gels, that specifically inhibit neoplastic urothelial cell growth, could be used as scaffolds in surgical bladder reconstitution.     

Recellularization of biological heart valves with human vascular cells: in vitro hemocompatibility assessment

Coverage of cardiovascular bioprostheses with autologous endothelium is used for the purpose of improving blood compatibility. The aim of our study was to analyze endothelialization potential of glutaraldehyde-fixed heart valves, cellular functions of seeded endothelial cells (EC), and the impact of a two-stage seeding protocol using human vascular fibroblasts (FB) and EC from saphenous veins (HSVEC) on cellular functional properties in vitro. Adherence and morphology of adhered cells were assessed by scanning electronic microscopy and immunohistochemistry. Reproducible, complete surface coverage with EC was established on decellularized and glutaraldehyde-fixed bovine pericardium. Analyzing functional properties of cells directly adhered to biomaterial revealed nonproliferative cells, which were capable of inflammatory stimulation in terms of TNF-induced increase in interleukin-6 secretion and adhesion of inflammatory cells. Furthermore, EC showed sustained antithrombotic properties quantified by platelet adhesion onto EC and prostacyclin secretion by EC. Preseeding with vascular fibroblasts using a two-stage seeding protocol induced EC proliferation and improved inflammatory and anti-thrombotic functions. Cardiovascular biomaterials differ significantly in their potential to allow for adhesion of human EC. Successfully endothelialized biomaterial, however, revealed cellular properties which are likely to be favorable to improving performance of biomaterials. Two-stage seeding adds regenerative potential and improves cell functions of adherent EC.     

Effect of seeding and bioreactor culture conditions on the development of human tissue-engineered cartilage

Human cartilage was produced using fetal chondrocytes seeded into polyglycolic acid (PGA) mesh scaffolds and cultured in recirculation bioreactors. The effect of scaffold thickness, seeding cell density, and bioreactor operating conditions on the quality of the engineered cartilage was investigated. Thin (2.15-mm-thick) PGA scaffolds lost their structural integrity during bioreactor culture and the resulting constructs were small and misshapen compared with tissues generated using 4.75-mm-thick scaffolds. Increasing the seeding cell number from 1.2 x 10(7) to 2.2 x 10(7 )per 4.75-mm-thick scaffold resulted in a doubling of the construct wet weight, a 4.4-fold increase in glycosaminoglycan (GAG) concentration, and a 2.9-fold increase in total collagen concentration in the tissues. Levels of GAG and total collagen were also improved significantly when 100 mL or 50% v/v of the culture medium was replaced periodically during operation of the bioreactors compared with 50, 25, or 5 mL. The proportion of GAG lost from the tissues into the medium was reduced by increasing the seeding cell number and replaced medium volume. This work demonstrates that the quality of tissue-engineered cartilage can be manipulated substantially depending on the cell seeding and bioreactor culture conditions employed.     

Oscillatory perfusion seeding and culturing of osteoblast-like cells on porous beta-tricalcium phosphate scaffolds

Perfusion culture systems have proven to be effective bioreactors for constructing tissue engineered bone in vitro, but existing circuit-based perfusion systems are complicated and costly for conditioned culture due to the large medium volume required. A compact perfusion system for artificial bone fabrication using oscillatory flow is described here. Mouse osteoblast-like MC 3T3-E1 cells were seeded at 1.5 x 10(6) cells/100 microL and cultured for 6 days in porous ceramic beta-tricalcium phosphate scaffolds (10 mm in diameter, 8 mm in height) by only 1.5 mL culture media per scaffold. The seeding efficiency, cell proliferation, distribution and viability, and promotion of early osteogenesis by both a static and an oscillatory perfusion method were evaluated. The oscillatory perfusion method generated higher seeding efficiency, alkaline phosphatase activity, and scaffold cellularity (by DNA content) after 6 days of culture. Stereomicroscopic observation of 3(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide staining and Calcein-AM/propidium iodide double staining also demonstrated homogeneous seeding, proliferation, and viability of cells throughout the scaffolds in the oscillatory perfusion system. By contrast, the static culture yielded polarized seeding and proliferation favoring the outer and upper scaffold surfaces, with only dead cells in the center of the scaffolds. Thus, these results suggest that the oscillatory flow condition not only allow a better seeding efficiency and homogeneity, but also facilitates uniform culture and early osteogenic differentiation. The oscillatory perfusion system could be a simple and effective bioreactor for bone tissue engineering.     

New type of matrix support for bone marrow cell cultures: in vitro culture and in vivo transplantation experiments

A new type of bone marrow cell culture system was developed by using a highly porous substrate matrix, i.e., porous polyvinyl formal (PVF) resin. Murine bone marrow (BM) cells were cultured without the use of exogenous growth factors in a three-dimensional matrix support made of collagen coated porous PVF resin. To examine the optimal conditions for highest stromal cell density, short-term and long-term in vitro culture experiments using PVF were performed. In the short-term culture experiments, it was found that cubes of PVF (10 x 10 x 2 mm and 130 microm in pore size) coated with type I collagen with a seeding density of 2x10(7) BM cells offered the most appropriate culture conditions. In the long-term cultures, BM cells in PVF maintained their viability for up to 6 weeks. In another series of re-inoculation experiments, freshly isolated BM cells were inoculated onto the already developed stromal layer. In this study, a higher cell density of the stromal layer was obtained in the PVF culture compared with those in the control dish culture. Based upon the results of in vitro experiments, in vivo transplantation studies were also performed. Histologic examinations of the subcutaneously transplanted PVF with stroma revealed host derived hematopoiesis inside the PVF matrix. Moreover, survival of approximately 15% of the transplanted BM cells that were cultured in PVF were confirmed in X-ray irradiated recipients. From these results, it is suggested that PVF resin is a promising three-dimensional substrate for BM cell culture and that it can maintain hematopoietic stem cells or progenitor cells after transplantation.     

Ascorbate modulation of bovine chondrocyte growth,matrix protein gene expression and synthesis in three-dimensional collagen sponges

This report completes a previous study on the growth and metabolism of fetal bovine epiphyseal chondrocytes cultured, within native or cross-linked collagen sponges carried out without the addition of fresh ascorbate. At low initial cell density (2.3 x 10(6)cells/cm(3)) cell proliferation and a low matrix deposition were observed, whereas at high initial cell density (2.3 x 10(7)cells/cm(3)) there was an absence of cell proliferation, but the deposition of a cartilage-like matrix was measured. In both cases, only traces of type I collagen (marker of chondrocyte dedifferentiation) were detected. In this report, we observed, after 1 month in culture with ascorbate, in both type of scaffolds and initial cell densities, an increase in cell proliferation (2-fold) and in expression of genes encoding for collagen types I, II, X and MMP-2 and -13, but no change in the level of matrix deposition (collagen and GAG). With regard to the proteins present, the main differences with or without ascorbate concerned the increase of neosynthesised type I collagen (up to 35% of the total collagen deposited in the sponge) and of the MMP-2 active form. In conclusion, these results show that ascorbate is an important factor to consider when preparing cartilage constructs for its action on chondrocyte phenotype modulation and proliferation.     

不同蛋白涂层在脱细胞牛心包片上对骨髓间充质细胞黏附生长的影响

为观察和评价不同蛋白涂层对骨髓间充质细胞在脱细胞牛心包片上黏附生长的影响,采用酶消化结合去污剂洗涤法制作脱细胞牛心包片,在其表面用不同蛋白(纤维连接蛋白、明胶蛋白、型胶原蛋白)均匀涂层。提取并培养大鼠骨髓间充质细胞,将其接种到预涂层的牛心包片上,未涂层组作为对照。在不同时间点采用Hochest染色观察细胞贴附生长情况,48h采用MTT法定量分析。纤维连接蛋白涂层及明胶蛋白涂层与型胶原蛋白涂层和不涂层组相比,对骨髓间充质细胞贴附增殖能力均有显著提高(P<0.001);纤维连接蛋白涂层和明胶蛋白涂层之间(P>0.05)以及型胶原蛋白涂层和不涂层对照组之间(P>0.05)对细胞的贴附生长没有显著差异。结果表明:脱细胞牛心包片上纤维连接蛋白涂层及明胶蛋白涂层能明显提高骨髓间充质细胞的贴附增殖能力,而型胶原蛋白涂层对骨髓间充质细胞的贴附增殖没有明显的改善。