Transplantation of autologous rabbit BM-derived mesenchymal stromal cells embedded in hyaluronic acid gel sponge into osteochondral defects of the knee

BACKGROUND: Mesenchymal stromal cells (MSC) have the potential to differentiate into distinct mesenchymal tissues including cartilage, suggesting that these cells are an attractive cell source for cartilage tissue engineering approaches. Various methods, such as using hyaluronan-based materials, have been employed to improve transplantation for repair. Our objective was to study the effects of autologous transplantation of rabbit MSC with hyaluronic acid gel sponges into full-thickness osteochondral defects of the knee. METHODS: Rabbit BM-derived MSC were cultured and expanded with fibroblast growth factor (FGF). Specimens were harvested at 4 and 12 weeks after implantation, examined histologically for morphologic features, and stained immunohistochemically for type II collagen and CD44. RESULTS: The regenerated area after autologous transplantation of hyaluronic acid gel sponge loaded with MSC into the osteochondral defect at 12 weeks after surgery showed well-repaired cartilage tissue, resembling the articular cartilage of the surrounding structure, of which the histologic score was significantly better than that of the untreated osteochondral defect. In the regenerated cartilage, type II collagen was found in the pericellular matrix of regenerative chondrocytes, while CD44 expression in the regenerative tissue could not be revealed. DISCUSSION: These data suggest that the autologous transplantation of MSC embedded in hyaluronan-based material may support chondrogenic differentiation and be useful for osteochondral defect repair.     

Demineralized Bone Matrix Combined Bone Marrow Mesenchymal Stem Cells,Bone Morphogenetic Protein-2 and Transforming Growth Factor-β3 Gene Promoted Pig Cartilage Defect Repair

Objectives

To investigate whether a combination of demineralized bone matrix (DBM) and bone marrow mesenchymal stem cells (BMSCs) infected with adenovirus-mediated- bone morphogenetic protein (Ad-BMP-2) and transforming growth factor-β3 (Ad-TGF-β3) promotes the repair of the full-thickness cartilage lesions in pig model.

Methods

BMSCs isolated from pig were cultured and infected with Ad-BMP-2(B group), Ad-TGF-β3 (T group), Ad-BMP-2 + Ad-TGF-β3(BT group), cells infected with empty Ad served as a negative group(N group), the expression of the BMP-2 and TGF-β3 were confirmed by immunofluorescence, PCR, and ELISA, the expression of SOX-9, type II collagen(COL-2A), aggrecan (ACAN) in each group were evaluated by real-time PCR at 1w, 2w, 3w, respectively. The chondrogenic differentiation of BMSCs was evaluated by type II collagen at 21d with immunohistochemical staining. The third-passage BMSCs infected with Ad-BMP-2 and Ad-TGF-β3 were suspended and cultured with DBM for 6 days to construct a new type of tissue engineering scaffold to repair full-thickness cartilage lesions in the femur condyles of pig knee, the regenerated tissue was evaluated at 1,2 and 3 months after surgery by gross appearance, H&E, safranin O staining and O''driscoll score.

Results

Ad-BMP-2 and Ad-TGF-β3 (BT group) infected cells acquired strong type II collagen staining compared with Ad-BMP-2 (B group) and Ad-TGF-β3 (T group) along. The Ad-BMP-2 and Ad-TGF-β3 infected BMSCs adhered and propagated well in DBM and the new type of tissue engineering scaffold produced hyaline cartilage morphology containing a stronger type II collagen and safranin O staining, the O''driscoll score was higher than other groups.

Conclusions

The DBM compound with Ad-BMP-2 and Ad-TGF-β3 infected BMSCs scaffold has a good biocompatibility and could well induce cartilage regeneration to repair the defects of joint cartilage. This technology may be efficiently employed for cartilage lesions repair in vivo.     

The stability of the collagen phenotype during stimulated collagen,glycosaminoglycan, and DNA synthesis by articular cartilage organ cultures

Rabbit articular cartilage slices were grown in organ culture for 9 weeks. Eightfold increases in the synthesis of both glycosaminoglycan and collagen were observed at 1 and 3 weeks, respectively. These levels of synthesis gradually declined in parallel to fourfold at 9 weeks. DNA synthesis was stimulated more than 30-fold at 3 weeks and then declined to sevenfold at 9 weeks. In contrast, the content of glycosaminoglycans and collagen per milligram of original wet slices did not vary significantly, while the number of cells increased 1.7-fold by the end of the study. The collagen phenotype of these cultures was determined by sodium dodecyl sulfate electrophoresis of recently synthesized, [³H]proline-labeled intact collagen chains and CNBr peptides. Throughout the study the major collagen synthesized was type II, ranging from 95 to 68% of the collagen synthesized at 0 and 5 weeks, respectively. Increases in the proportions of X₂Y and type III collagen were first observed at 3 weeks in culture. The synthesis of type I collagen was detected only after 5 weeks in culture and never represented more than 11% of the total collagen synthesized. The synthesis of type I trimer could not be verified at any time. This study demonstrates that in vitro organ culture of articular cartilage slices allows chondrocytes to maintain the normal chondrocyte collagen phenotype of predominantly type II synthesis while stimulating their proliferation and matrix synthesis.     

Differentiation of transplanted mesenchymal stem cells in a large osteochondral defect in rabbit

BACKGROUND: Although accumulating evidence shows that mesenchymal stem cells (MSC) are a promising cell source for articular cartilage repair, the fate of transplanted MSC has not been extensively studied. METHODS: To monitor their persistence and differentiation, we labeled uninduced MSC with a fluorescent dye, PKH26, and transplanted them, in a poly-glycolic-acid scaffold, to full-thickness defects made in the weight-bearing area of rabbit femoral trochleae with hyaluronate sheets. The fate of the labeled cells was monitored for up to 8 weeks. RESULTS: Two weeks after transplantation, immature cartilage containing collagen type II had formed. By 8 weeks, this cartilage had thinned and immunolabeling for collagen type II gradually disappeared from the basal region, which became positive for collagen type I. Most chondrocytes within the regenerated cartilage were PKH26-positive and, therefore, derived from transplanted MSC, whereas osteoblasts within the regenerated bone were a mixture of donor- and host-derived cells. The thickness of the cartilage became thinner up to 8 weeks and then remained stable up to 42 weeks after surgery. DISCUSSION: These results showed that uninduced MSC were able to survive osteochondral defects and differentiated according to the environment, making a major contribution to initial cartilage formation and a partial contribution to bone regeneration.     

Full-thickness cartilage defects are repaired via a microfracture technique and intraarticular injection of the small-molecule compound kartogenin

IntroductionMicrofracture does not properly repair full-thickness cartilage defects. The purpose of this study was to evaluate the effect of intraarticular injection of the small-molecule compound kartogenin (KGN) on the restoration of a full-thickness cartilage defect treated with microfracture in a rabbit model.MethodsFull-thickness cartilage defects (3.5 mm in diameter and 3 mm in depth) were created in the patellar groove of the right femurs of 24 female New Zealand White rabbits. The rabbits were divided into two groups (12 in each group) based on postsurgery treatment differences, as follows: microfracture plus weekly intraarticular injection of KGN (group 1) and microfracture plus dimethyl sulfoxide (group 2). Six rabbits from each group were illed at 4 and 12 weeks after surgery, and their knees were harvested. The outcome was assessed both macroscopically, by using the International Cartilage Repair Society (ICRS) macroscopic evaluation system, and histologically, by using the modified O’Driscoll histologic scoring system. Immunohistochemistry for type II and I collagen was also conducted.ResultsAt 4 weeks, group 1 showed better defect filling and a greater number of chondrocyte-like cells compared with group 2. At 12 weeks, group 1 showed statistically significantly higher ICRS scores and modified O’Driscoll scores compared with group 2. More hyaline cartilage-like tissue was found in the defects of group 1 at 12 weeks.ConclusionsIntraarticular injection of KGN enhances the quality of full-thickness cartilage defects repair after microfracture, with better defect filling and increased hyaline-like cartilage formation.     

Experiments with a biological material for the closure of incisional hernias

A new preparation process was studied which should allow the implantation of collagen type I in its native structure in reconstructive surgery, in this special case for closure of incisional hernias. As experimental animals we used 30 female Lewis rats. A defect of the anterior abdominal wall measuring 3 cm X 4 cm was closed with our collagen substitute. Biopsies taken after 4, 6 and 8 weeks were examined morphologically. As criteria for revitalization and revascularization we used the type of infiltrating cells, the depth and density of infiltration and the formation of new blood vessels. After 4 weeks the implants were infiltrated by fibroblasts that decreased in density towards the centre. Good revascularization could be seen on the muscle-implant interface. After 6 weeks the density of infiltrating cells had increased markedly even to the centre of the collagen implant. Sporadically small vessels could be seen. Eight weeks after implantation the density of infiltrated cells was at the same high level, and capillary bundles could be seen within the whole implant. We believe that this collagen implant is suitable for the closure of hernias as shown by its physical and morphological properties. In particular it appears to guarantee and earlier and tighter closure of hernias than other materials.     

Extent of cell differentiation and capacity for cartilage synthesis in human adult adipose‐derived stem cells: Comparison with fetal chondrocytes

This study evaluated the extent of differentiation and cartilage biosynthetic capacity of human adult adipose‐derived stem cells relative to human fetal chondrocytes. Both types of cell were seeded into nonwoven‐mesh polyglycolic acid (PGA) scaffolds and cultured under dynamic conditions with and without addition of TGF‐β1 and insulin. Gene expression for aggrecan and collagen type II was upregulated in the stem cells in the presence of growth factors, and key components of articular cartilage such as glycosaminoglycan (GAG) and collagen type II were synthesized in cultured tissue constructs. However, on a per cell basis and in the presence of growth factors, accumulation of GAG and collagen type II were, respectively, 3.4‐ and 6.1‐fold lower in the stem cell cultures than in the chondrocyte cultures. Although the stem cells synthesized significantly higher levels of total collagen than the chondrocytes, only about 2.4% of this collagen was collagen type II. Relative to cultures without added growth factors, treatment of the stem cells with TGF‐β1 and insulin resulted in a 59% increase in GAG synthesis, but there was no significant change in collagen production even though collagen type II gene expression was upregulated 530‐fold. In contrast, in the chondrocyte cultures, synthesis of collagen type II and levels of collagen type II as a percentage of total collagen more than doubled after growth factors were applied. Although considerable progress has been achieved to develop differentiation strategies and scaffold‐based culture techniques for adult mesenchymal stem cells, the extent of differentiation of human adipose‐derived stem cells in this study and their capacity for cartilage synthesis fell considerably short of those of fetal chondrocytes. Biotechnol. Bioeng. 2010;107: 393–401. © 2010 Wiley Periodicals, Inc.     

In vitro redifferentiation of culture-expanded rabbit and human auricular chondrocytes for cartilage reconstruction

To construct an autologous cartilage graft using tissue engineering, cells must be multiplied in vitro; they then lose their cartilage-specific phenotype. The objective of this study was to assess the capacity of multiplied ear chondrocytes to re-express their cartilage phenotype using various culture conditions. Cells were isolated from the cartilage of the ears of three young and three adult rabbits and, after multiplication in monolayer culture, they were seeded in alginate and cultured for 3 weeks in serum-free medium with insulin-like growth factor 1 (IGF-1) and transforming growth factor-beta2 (TGF-beta2) in three different dose combinations. As a control, cells were cultured in 10% fetal calf serum, which was demonstrated in previous experiments to be unable to induce redifferentiation. Chondrocytes from the ears of young, but not adult, rabbits, synthesized significantly more glycosaminoglycan when serum was replaced by insulin-like growth factor-1 and transforming growth factor-beta2. The number of collagen type II-positive cells was increased from 10 percent to 97 percent in young cells and to 33 percent in adult cells. Using human ear cells from 12 patients (aged 7 to 60 years), glycosaminoglycan synthesis could also be stimulated by replacing serum with insulin-like growth factor and transforming growth factor-beta. Although the number of collagen type II-positive cells could be increased under these conditions, it never reached above 10 percent. Data from five patients showed that further optimization of the culture conditions by adding ITS+ and cortisol significantly increased (doubled or tripled) both glycosaminoglycan synthesis and collagen type II expression. In conclusion, this study demonstrates a method to regain cartilage phenotype in multiplied ear cartilage cells. This improves the chances of generating human cartilage grafts for the reconstruction of external ears or the repair of defects of the nasal septum.     

The effect of embryo extract on the types of collagen synthesized by cultured chick chondrocytes.

Growth of embryonic chick chondrocytes in dialyzed embryo extract results in both a change in morphology of the cells toward that of a fibroblast and a change in the type of collagen synthesized from the cartilage-specific Type II collagen (chain composition [α1(II)]₃) to a mixture of Type I collagen (chain composition [α1(I)]₂α2) and the Type I trimer (chain composition [α1(I)]₃). Analyses after 6 days of growth in embryo extract show that the synthesis of only Type I collagen and the Type I trimer can be detected. However, on subculturing the cells to a low density and allowing a period of growth without embryo extract, colonies of chondrocytes reappear and the synthesis of Type II collagen apparently resumes. It is suggested that the observed changes represent a “modulation” in cell behavior, this being expressed not only by the morphological changes but also by changes in cell-specific protein synthesis as demonstrated by the changes in the type of collagen synthesized.     

Regulation of growth, protein synthesis, and maturation of fetal bovine epiphyseal chondrocytes grown in high-density culture in the presence of ascorbic acid, retinoic acid, and dihydrocytochalasin B

Phenotypic expression of chondrocytes can be modulated in vitro by changing the culture technique and by agents such vitamins and growth factors. We studied the effects of ascorbic acid, retinoic acid (0.5 and 10 microM), and dihydrocytochalasin B (3, 10, 20 microM DHCB), separately or in combination (ascorbic acid + retinoic acid or ascorbic acid + DHCB), on the induction of maturation of fetal bovine epiphyseal chondrocytes grown for up to 4 weeks at high density in medium containing 10% fetal calf serum and the various agents. In the absence of any agent or with retinoic acid or DHCB alone, the metabolic activity of the cells remained very low after day 6, with no induction of type I or X collagen synthesis nor increase in alkaline phosphatase activity. Chondrocytes treated with fresh ascorbic acid showed active protein synthesis associated with expression of types I and X after 6 and 13 days, respectively. This maturation was not accompanied by obvious hypertrophy of the cells or high alkaline phosphatase activity. Addition of retinoic acid to the ascorbic acid-treated cultures decreased the level of type II collagen synthesis and delayed the induction of types I and X collagen, which were present only after 30 days. A striking increase in alkaline phosphatase activity (15-20-fold) was observed in the presence of both ascorbic acid and the highest dose of retinoic acid (10 microM). DHCB was also a potent inhibitor of the maturation induced by treatment with ascorbic acid, as the chondrocytes maintained their rounded shape and synthesized type II collagen without induction of type I or X collagen. The pattern of protein secretion was compared under all culture conditions by two-dimensional gel electrophoresis. The different regulations of chondrocyte differentiation by ascorbic acid, retinoic acid, and DHCB were confirmed by the important qualitative and quantitative changes in the pattern of secreted proteins observed by two-dimensional gel electrophoresis along the study.     

Insulin-like growth factors.

The insulin-like growth factors I and II are single chain polypeptides homologous to proinsulin. IGF I and IGF II contribute to cell regulation and stimulate protein synthesis via signaling through type I receptors which are homologous to insulin receptors and activate phosphorylation cascades. IGFs enhance the proliferation of chondocytes and the proliferation of their collagen and proteoglycan matrix; IGFs stimulate longitudinal (endochondral) bone growth. Throughout life, IGFs are constitutvely expressed ubiquitous factors which help to maintain the survival of differentiated cells, Increased expression is found during growth and tissue repair, Six specific binding proteins, IGFBP 1-6, allow additional tissue compartment specific control of IGF activity; IGFBP production favours storage and IGFBP cleavage leads to activation.     

Growth factor effects on costal chondrocytes for tissue engineering fibrocartilage

Tissue-engineered fibrocartilage could become a feasible option for replacing tissues such as the knee meniscus or temporomandibular joint disc. This study employed five growth factors (insulin-like growth factor-I, transforming growth factor-beta1, epidermal growth factor, platelet-derived growth factor-BB, and basic fibroblast growth factor) in a scaffoldless approach with costal chondrocytes, attempting to improve biochemical and mechanical properties of engineered constructs. Samples were quantitatively assessed for total collagen, glycosaminoglycans, collagen type I, collagen type II, cells, compressive properties, and tensile properties at two time points. Most treated constructs had lower biomechanical and biochemical properties than the controls with no growth factors, suggesting a detrimental effect, but the treatment with insulin-like growth factor-I tended to improve the constructs. Additionally, the 6-week time point was consistently better than that at 3 weeks, with total collagen, glycosaminoglycans, and aggregate modulus doubling during this time. Further optimization of the time in culture and exogenous stimuli will be important in making a more functional replacement tissue.     

Regulation of growth,protein synthesis,and maturation of fetal bovine epiphyseal chondrocytes grown in high‐density culture in the presence of ascorbic acid,retinoic acid,and dihydrocytochalasin B

Phenotypic expression of chondrocytes can be modulated in vitro by changing the culture technique and by agents such vitamins and growth factors. We studied the effects of ascorbic acid, retinoic acid (0.5 and 10 μM), and dihydrocytochalasin B (3, 10, 20 μM DHCB), separately or in combination (ascorbic acid + retinoic acid or ascorbic acid + DHCB), on the induction of maturation of fetal bovine epiphyseal chondrocytes grown for up to 4 weeks at high density in medium containing 10% fetal calf serum and the various agents. In the absence of any agent or with retinoic acid or DHCB alone, the metabolic activity of the cells remained very low after day 6, with no induction of type I or X collagen synthesis nor increase in alkaline phosphatase activity. Chondrocytes treated with fresh ascorbic acid showed active protein synthesis associated with expression of types I and X after 6 and 13 days, respectively. This maturation was not accompanied by obvious hypertrophy of the cells or high alkaline phosphatase activity. Addition of retinoic acid to the ascorbic acid‐treated cultures decreased the level of type II collagen synthesis and delayed the induction of types I and X collagen, which were present only after 30 days. A striking increase in alkaline phosphatase activity (15–20‐fold) was observed in the presence of both ascorbic acid and the highest dose of retinoic acid (10 μM). DHCB was also a potent inhibitor of the maturation induced by treatment with ascorbic acid, as the chondrocytes maintained their rounded shape and synthesized type II collagen without induction of type I or X collagen. The pattern of protein secretion was compared under all culture conditions by two‐dimensional gel electrophoresis. The different regulations of chondrocyte differentiation by ascorbic acid, retinoic acid, and DHCB were confirmed by the important qualitative and quantitative changes in the pattern of secreted proteins observed by two‐dimensional gel electrophoresis along the study. J. Cell. Biochem. 76:84–98, 1999. © 1999 Wiley‐Liss, Inc.     

Immunological and biochemical studies of collagen type transition during in vitro chondrogenesis of chick limb mesodermal cells

This work describes an approach to monitor chondrogenesis of stage-24 chick limb mesodermal cells in vitro by analyzing the onset of type II collagen synthesis with carboxymethyl-cellulose chromatography, immunofluorescence, and radioimmunoassay. This procedure allowed specific and quantitative determination of chondrocytes in the presence of fibroblasts and myoblasts, both of which synthesize type I collagen. Chondrogenesis was studied in high-density cell preparations on tissue culture plastic dishes and on agar base. It was found that stage-24 limb mesenchymal cells initially synthesized only type I collagen. With the onset of chondrogenesis, a gradual transition to type II collagen synthesis was observed. In cell aggregates formed over agar, type II collagen synthesis started after 1 day in culture and reached levels of 80-90 percent of the total collagen synthesis at 6-8 days. At that time, the cells in the center of the aggregates had acquired the typical chondrocyte phenotype and stained only with type II collagen antibodies, whereas the peripheral cells had developed into a "perichondrium" and stained with type I and type II collagen antibodies. On plastic dishes plated with 5 X 10(6) cells per 35mm dish, cartilage nodules developed after 4-6 days, but the type II collagen synthesis only reached levels of 10-20 percent of the total collagen. The majority of the cells differentiated into fibroblasts and myoblasts and synthesized type I collagen. These studies demonstrate that analysis of cell specific types of collagen provides a useful method for detailing the specific events in the differentiation of mesenchymal cells in vitro.     

AUTORADIOGRAPHIC STUDY OF TYPE II-CELL HYPERPLASIA IN LUNGS OF MICE CHRONICALL EXPOSED TO URETHANE

Hyperplasia of pulmonary alveolar epithelium was induced by exposure of adult mice to 0–1% urethane in drinking water, and their lungs were analysed using combined autoradiographic and morphometric methods. The response of pulmonary epithelium showed three phases: an initial one of 3 weeks in which the number of type II cells was consistently low and, after a transient decrease in ³H-thymidine labeling index, the latter steadily increased. Degenerating or dead type II cells were found, consequently this period was considered one in which cell death was disproportionately increased over cell production. Between the 3rd and 6th weeks the number of type II cells doubled, and thereafter increased at a slower rate. The ³H-thymidine labeling index reached its peak at 6 weeks. The third phase was marked by a decline in labeling index which returned to near-normal levels by the 16th week. The number of type II cells declined slowly after the 10th week and was still elevated at the end of the observation period. Tumors consisting of type II cells continued to arise even during the period of declining labeling index. The dissociation between the proliferative response which was reversible, and the neoplastic response which was not, supports the assumption that the major part of the observed population growth or hyperplasia induced by urethane was a form of regeneration repair secondary to cell death and may be unrelated to tumor growth.     

Chondrogenesis of human periosteum-derived progenitor cells in atelocollagen

Periosteum-derived progenitor cells (PDPCs) could be differentiated into cartilage using atelocollagen as a carrier and in the presence of transforming growth factor-β3 (TGF-β3). Chondrogenesis was verified by RT-PCR and Western blotting. Expression of the type II collagen mRNA was found from the differentiated PDPCs in atelocollagen 3 weeks after chondrogenic induction. The chondrogenic potential of the PDPCs was also verified by histochemical staining for type II collagen protein. Increased production of glycosaminoglycan shows that the PDPCs in atelocollagen could differentiate into chondrocytes under a chondrogenic environment. PDPCs can therefore be used as a cell source for cell-based therapies targeted toward the articular cartilage of the knee.     

Periodic knee injections of collagen tripeptide delay cartilage degeneration in rabbit experimental osteoarthritis

Introduction

Collagen peptides have been reported to possess various biological activities for various cell types. The purposes of this study were, first, to examine the therapeutic effects of collagen tripeptide (Ctp) in rabbit osteoarthritis and, second, to explore a synergetic effect with hyaluronan (HA).

Methods

Osteoarthritis was induced by anterior cruciate ligament transection of the right knee in 72 Japanese white rabbits and they were divided into four groups (control, Ctp, HA and Ctp/HA). Each material was injected weekly into the knee, and knee joint samples were collected 5, 10 and 15 weeks after surgery. Macroscopic and histomorphological analyses of cartilage were conducted. Expression of type II collagen and matrix metalloproteinase-13 was also analyzed immunohistochemically. A Tukey''s honestly significant difference test was used to evaluate the statistical significance of difference in the macroscopic, histological and immnohistochemical results.

Results

All treatment groups exhibited slightly higher resistance to the progression of osteoarthritis than the control group macroscopically 15 weeks after surgery. Histologically, intra-articular injection of Ctp significantly reduced cartilage degradation 10 weeks after surgery, and Ctp/HA significantly reduced it 5 weeks after surgery in comparison with the control. Immunohistochemically, both Ctp-treated and Ctp/HA-treated groups had significantly increased type II collagen-positive chondrocytes at the fifth week after the surgery, although the numbers of matrix metalloproteinase-13-positive chondrocytes were not affected.

Conclusion

Periodical injections of Ctp and Ctp/HA delayed progression of cartilage degeneration of early osteoarthritis induced by anterior cruciate ligament transection in rabbits. This effect appears to be exerted by promotion of type II collagen synthesis predominantly.     

Potential use of the human amniotic membrane as a scaffold in human articular cartilage repair

The human amniotic membrane (HAM) is an abundant and readily obtained tissue that may be an important source of scaffold for transplanted chondrocytes in cartilage regeneration in vivo. To evaluate the potential use of cryopreserved HAMs as a support system for human chondrocytes in human articular cartilage repair. Chondrocytes were isolated from human articular cartilage, cultured and grown on the chorionic basement membrane side of HAMs. HAMs with chondrocytes were then used in 44 in vitro human osteoarthritis cartilage repair trials. Repair was evaluated at 4, 8 and 16 weeks by histological analysis. Chondrocytes cultured on the HAM revealed that cells grew on the chorionic basement membrane layer, but not on the epithelial side. Chondrocytes grown on the chorionic side of the HAM express type II collagen but not type I, indicating that after being in culture for 3–4 weeks they had not de-differentiated into fibroblasts. In vitro repair experiments showed formation on OA cartilage of new tissue expressing type II collagen. Integration of the new tissue with OA cartilage was excellent. The results indicate that cryopreserved HAMs can be used to support chondrocyte proliferation for transplantation therapy to repair OA cartilage.     

Synthesis of type III collagen by fibroblasts from the embryonic chick cornea

Synthesis of collagen types I, II, III, and IV in cells from the embryonic chick cornea was studied using specific antibodies and immunofluorescence. Synthesis of radioactively labeled collagen types I and III was followed by fluorographic detection of cyanogen bromide peptides on polyacrylamide slab gels and by carboxymethylcellulose chromatography followed by disc gel electrophoresis. Type III collagen had been detected previously by indirect immunofluorescence in the corneal epithelial cells at Hamburger-Hamilton stages 20--30 but not in the stroma at any age. Intact corneas from embryos older than stage 30 contain and synthesize type I collagen but no detectable type III collagen. However, whole stromata subjected to collagenase treatment and scraping (to remove epithelium and endothelium) and stromal fibroblasts from such corneas inoculated in vitro begin synthesis of type III collagen within a few hours while continuing to synthesize type I collagen. As demonstrated by double-antibody staining, most corneal fibroblasts contain collagen types I and III simultaneously. Collagen type III was identified biochemically in cell layers and media after chromatography on carboxymethylcellulose be detection of disulfide-linked alpha l (III)3 by SDS gel electrophoresis. The conditions under which the corneal fibroblasts gain the ability to synthesize type III collagen are the same as those under which they lose the ability to synthesize the specific proteoglycan of the cornea: the presence of corneal-type keratan sulfate.