A modified rhTGF-beta1 and rhBMP-2 are effective in initiating a chondro-osseous differentiation pathway in bone marrow cells cultured in vitro

Rat bone marrow cells were cultured in vitro in a collagen-gel medium at 0.5% fetal bovine serum concentration for 10 days in the presence of recombinant human transforming growth factor-beta-1, genetically engineered to contain a collagen binding domain (rhTGF-beta1-F2), or a commercial rhTGF-beta1. To compare the effects of TGF-betas with other growth factors in which the osteogenic capacity has been widely documented, a recombinant human bone morphogenetic protein (rhBMP-2) was evaluated. Once serum conditions compatible with growth were re-established, the selected cells were cultured for 6 more days in the presence of the growth factor. In the last 2 days, dexamethasone (dex) and beta-glycerophosphate (beta-GP) were added to promote osteogenesis. After this 16-day period, cells were placed into diffusion chambers or demineralized bone matrix (DBM) implants, and implanted subdermally on the backs of rats for 28 days. Biochemical, histological, and immunohistochemistry analysis provided evidence of cartilage (commercial rhTGF-beta1-treated cells), osteoid (rhTGF-beta1-F2-treated cells), and bone tissues (rhBMP-2 treated cells), inside the diffusion chambers, whereas bone, cartilage, and osteoid were observed inside the DBM implants under any of the three growth factors effect. Our study advances the technology capable of selecting a cell population from bone marrow that, in the presence of rhTGF-beta1 or rhBMP-2 in vitro, achieves chondro-osteogenic potential in vitro and in vivo.     

A Modified rhTGF-β1 and rhBMP-2 Are Effective in Initiating a Chondro-Osseous Differentiation Pathway in Bone Marrow Cells Cultured In Vitro

Rat bone marrow cells were cultured in vitro in a collagen-gel medium at 0.5% fetal bovine serum concentration for 10 days in the presence of recombinant human transforming growth factor-beta-1, genetically engineered to contain a collagen binding domain (rhTGF- &#103 1-F2), or a commercial rhTGF- &#103 1. To compare the effects of TGF- &#103 s with other growth factors in which the osteogenic capacity has been widely documented, a recombinant human bone morphogenetic protein (rhBMP-2) was evaluated. Once serum conditions compatible with growth were re-established, the selected cells were cultured for 6 more days in the presence of the growth factor. In the last 2 days, dexamethasone (dex) and &#103 -glycerophosphate ( &#103 -GP) were added to promote osteogenesis. After this 16-day period, cells were placed into diffusion chambers or demineralized bone matrix (DBM) implants, and implanted subdermally on the backs of rats for 28 days. Biochemical, histological, and immunohistochemistry analysis provided evidence of cartilage (commercial rhTGF- &#103 1-treated cells), osteoid (rhTGF- &#103 1-F2-treated cells), and bone tissues (rhBMP-2 treated cells), inside the diffusion chambers, whereas bone, cartilage, and osteoid were observed inside the DBM implants under any of the three growth factors effect. Our study advances the technology capable of selecting a cell population from bone marrow that, in the presence of rhTGF- &#103 1 or rhBMP-2 in vitro, achieves chondro-osteogenic potential in vitro and in vivo.     

Gla-Containing Proteins of Bone

Bone has high levels of two proteins which contain the vitamin Kdependent Ca²⁺ binding amino acid, γ-carboxyglutamic acid (Gla). Bone Gla protein (BGP, osteocalcin) is a 49 residue water soluble protein and matrix Gla protein (MGP) is a 79 residue water insoluble protein. BGP is synthesized only by calcified tissues while MGP is synthesized by calcified tissues, cartilage, and all soft tissues tested. The synthesis of both proteins in osteoblastic cells is stimulated by 1,25(OH)2D3. Treatment of rats with the vitamin K antagonist Warfarin causes secretion of a non-γ-carboxylated BGP which cannot bind to hydroxyapatite. Warfarin treatment reduces bone levels of BGP to 2% of normal, but does not appear to affect the structure of bone. The only abnormality seen in rats treated with Warfarin is the mineralization of several cartilages. The pattern of cartilage calcification is similar to that seen in the fetal Warfarin syndrome in humans, and may be due to abnormal synthesis of MGP.     

Gla-containing proteins of bone

Bone has high levels of two proteins which contain the vitamin K-dependent Ca2+ binding amino acid, gamma-carboxyglutamic acid (Gla). Bone Gla protein (BGP, osteocalcin) is a 49 residue water soluble protein and matrix Gla protein (MGP) is a 79 residue water insoluble protein. BGP is synthesized only by calcified tissues while MGP is synthesized by calcified tissues, cartilage, and all soft tissues tested. The synthesis of both proteins in osteoblastic cells is stimulated by 1,25(OH)2D3. Treatment of rats with the vitamin K antagonist Warfarin causes secretion of a non-gamma-carboxylated BGP which cannot bind to hydroxyapatite. Warfarin treatment reduces bone levels of BGP to 2% of normal, but does not appear to affect the structure of bone. The only abnormality seen in rats treated with Warfarin is the mineralization of several cartilages. The pattern of cartilage calcification is similar to that seen in the fetal Warfarin syndrome in humans, and may be due to abnormal synthesis of MGP.     

Evaluation of bone regeneration at critical-sized calvarial defect by DBM/AM composite

This study investigated the bone-regenerative potential of a demineralized bone and acellular matrix (DBM/AM) composite (AlloCraft DBM) in comparison with autologous bone using an in vivo model. Critical-sized calvarial defects (5 mm) were created in athymic rats. The defects were grafted with either the DBM/AM composite or the acellular human dermal matrix (AM), and compared with the defects filled with autologous bone (positive control) and the empty defect (negative control). Histological and radiographic assessments were carried out at 4 and 8 weeks after surgery to determine the biological healing, the amount and type of new bone formation and the percentage of new bone filled in the critical defects. At 4 weeks, DBM/AM composite group had the highest percentage of the defect filled with new bone (84%), which was significantly greater than autologous bone (62%), AM (41%), and untreated control (32%) groups. At 8 weeks, the DBM/AM continued to have the highest percentage of the defect filled with new bone (91%). The autologous bone group increased the percentage of bone fill to 83%. The defects either filled with AM or left untreated still had less of the defect filled with new bone, 57% and 33%, respectively. The total healing of defects grafted with DBM/AM was comparable with autologous bone group at 8 weeks. The results demonstrated that the DBM/AM composite promoted new bone formation more rapidly than autologous bone at calvarial defect in athymic rats. The study supports that DBM/AM is a potential substitute of autologous bone for bone repair.     

The role of trabecular demineralized bone in combination with perichondrium in the generation of cartilage grafts

The use of a composite graft of bovine trabecular demineralized bone matrix (DBM) and perichondrium has been found a reliable method for in vivo generation of cartilage. In the present study, the mechanism whereby this commercially available matrix increases cartilage formation was investigated. First, the time course of cartilage formation in vivo, in the combined implant of perichondrium and DBM in the rabbit ear was studied, with special focus on tissue reactions to DBM. DBM was colonized by macrophages from day 3 post-operatively, reaching a maximum after 2 weeks. Only a minimal number of neutrophils was found. After 3 weeks the DBM appeared to be resorbed. In the first week the DBM was invaded with chondroblasts, and chondrogenesis occurred between the first and second week of implantation. After 3 weeks, the initially formed islets of cartilage had fused. Next, the chondrogenic capacity of DBM itself was investigated by implantation of DBM without perichondrium. This never resulted in cartilage formation. Immunohistochemistry showed only a faint staining of the DBM for growth factors. This indicates a minimal chondrogenic effect of DBM alone and the requirement of perichondrium as cell provider. In order to define the conditions which cause chondrogenesis in composites of perichondrium and DBM, a series of in vitro culture experiments was performed in which the in vivo situation was mimicked step by step. The basic condition was perichondrium cultured in medium with 10% FCS. In this condition, cartilage formation was variable. Because in the in vivo situation both DBM and macrophages can release growth factors, the effect of IGF1, TGFbeta2 or OP1 added to the culture medium was tested. Neither the incidence nor the amount of cartilage formation was stimulated by addition of growth factors. Perichondrium wrapped around DBM in vitro gave cartilage formation in the perichondrium but the incidence and amount were not significantly stimulated compared to cultures of perichondrium without DBM. However, cartilage-like cells were found in the DBM suggesting an effect of DBM on perichondrium-derived cells. Finally, macrophages and/or blood were added to the composite DBM-perichondrium to mimic the in vivo situation as close as possible. However, no effect of this treatment was found. In conclusion, this study indicates that DBM itself has few chondrogenic qualities but functions merely as a spacer for cell ingrowth. The fast resorption of DBM by macrophages in vivo seems of importance for the cartilage forming process, but in vitro the presence of macrophages (in combination with blood) could not enhance chondrogenesis.     

Synthetic biodegradable hydrogel delivery of demineralized bone matrix for bone augmentation in a rat model

There exists a strong clinical need for a more capable and robust method to achieve bone augmentation, and a system with fine-tuned delivery of demineralized bone matrix (DBM) has the potential to meet that need. As such, the objective of the present study was to investigate a synthetic biodegradable hydrogel for the delivery of DBM for bone augmentation in a rat model. Oligo(poly(ethylene glycol) fumarate) (OPF) constructs were designed and fabricated by varying the content of rat-derived DBM particles (either 1:3, 1:1 or 3:1 DBM:OPF weight ratio on a dry basis) and using two DBM particle size ranges (50–150 or 150–250 μm). The physical properties of the constructs and the bioactivity of the DBM were evaluated. Selected formulations (1:1 and 3:1 with 50–150 μm DBM) were evaluated in vivo compared to an empty control to investigate the effect of DBM dose and construct properties on bone augmentation. Overall, 3:1 constructs with higher DBM content achieved the greatest volume of bone augmentation, exceeding 1:1 constructs and empty implants by 3- and 5-fold, respectively. As such, we have established that a synthetic, biodegradable hydrogel can function as a carrier for DBM, and that the volume of bone augmentation achieved by the constructs correlates directly to the DBM dose.     

Age-related decrease in the activity of UDP-xylose:Core protein xylosyltransferase in rat costal cartilage

The activity of UDP-xylose:core protein xylosyltransferase (EC 2.4.2.26) in costal cartilage of young rats (3 months) and old rats (36 months) was measured. The enzyme activity in cartilage of young rats (mean ± S.D.) is 3370 ± 1440 Bq h^?1 mg^?1 DNA, which is about three times higher than that determined in cartilage of old rats (1090 ± 520 Bq h^?1 mg^?1 DNA). A similar decrease is found if the enzyme activity is referred to the concentration of extracted protein (young rats 240 ± 90 Bq h^?1 mg^?1 protein, old rats 70±30 Bq h^?1 mg^?1 protein). The amount of galactosamine-containing proteoglycosaminoglycans that are extractable with 4 M guanidinium chloride from cartilage is significantly higher in young rats (29.1 ± 4.8 nmol GalN per mg cartilage wet weight) than in old animals (5.8 ± 3.0 nmol GalN per mg cartilage wet weight). Thus, if xylosyltransferase activity is referred to the amount of galactosamine-containing proteoglycans in cartilage, nearly identical values are obtained (young rats, 80 ± 30 Bq h^?1 μmol^?1 GalN; old rats, 85 ±35 Bq h^?1 μmol^?1 GalN). The results support the assumption that the synthesis of proteochondroitin sulfate is diminished in costal cartilage of old rats by a mechanism involving a reduced activity of xylosyltransferase.     

Bone ingrowth in bFGF-coated hydroxyapatite ceramic implants

This experimental study was performed to evaluate angiogenesis, bone formation, and bone ingrowth in response to osteoinductive implants of bovine-derived hydroxyapatite (HA) ceramics either uncoated or coated with basic fibroblast growth factor (bFGF) in miniature pigs. A cylindrical bone defect was created in both femur condyles of 24 miniature pigs using a saline coated trephine. Sixteen of the 48 defects were filled with HA cylinders coated with 50 microg rhbFG, uncoated HA cylinders, and with autogenous transplants, respectively. Fluorochrome labelled histological analysis, histomorphometry, and scanning electron microscopy were performed to study angiogenesis, bone formation and bone ingrowth. Complete bone ingrowth into bFGF-coated HA implants and autografts was seen after 34 days compared to 80 days in the uncoated HA group. Active ring-shaped areas of fluorochrome labelled bone deposition with dynamic bone remodelling were found in all cylinders. New vessels could be found in all cylinders. Histomorphometric analysis showed no difference in bone ingrowth over time between autogenous transplants and bFGF-coated HA implants. The current experimental study revealed comparable results of bFGF-coated HA implants and autogenous grafts regarding angiogenesis, bone synthesis and bone ingrowth.     

Osteochondritis dissecans of the elbow: histopathological assessment of the articular cartilage and subchondral bone with emphasis on their damage and repair

Osteochondritis dissecans (OCD) of the elbow is a localized injury of the articular cartilage and subchondral bone that is commonly seen in the young athlete. In the present study, the extent of damage and repair on the articular cartilage and subchondral bone was examined histologically using specimens of 25 osteochondral cylinders and seven loose bodies obtained from 25 young athletes who had undergone osteochondral autograft surgery. Terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end-labeling (TUNEL) assays for detecting apoptotic cells and immunohistochemistry of matrix metalloproteinases (MMP) were performed on the osteochondral cylinder specimens. The histological findings of the OCD of the elbow showed that the articular cartilage exhibited degenerative change, mimicking osteoarthritis, and was markedly damaged as the lesion progressed. TUNEL-positive cells and MMP-3- and -13-expressing cells were distributed in the degenerative articular cartilage and reparative fibrocartilage tissue. Separation occurred at either the deep articular cartilage or the subchondral bone, with the former being dominant in the early OCD lesions. The present results suggest that the primary pathological changes in OCD of the elbow were due to damage of articular cartilage induced by repeated stress following degenerative and reparative process of articular cartilage and subchondral fracturing, and separation subsequently occurred on the cartilage and developed onto the subchondral bone in its advanced stages.     

In vivo magnetic resonance imaging explorative study of ectopic bone formation in the rat

In animal studies of tissue engineering of bone, histology remains the standard for assessing bone formation. As longitudinal studies with this method are feasible only at the cost of large numbers of animals, we looked for an alternative. Therefore, demineralized bone matrix (DBM) and inactivated demineralized bone matrix (iDBM) implants were subcutaneously implanted in a rat. At 1, 3, 5, and 7 weeks postimplantation soft X-ray and magnetic resonance imaging (MRI) were done to monitor bone formation in the implants. At 7 weeks, the animal was killed and the implants were retrieved for histology. Our results showed that in vivo MRI is well suited to assess bone formation larger than 0.5 mm in diameter and to monitor the complete three-dimensional shape of the newly formed bone noninvasively and longitudinally. The MRI results matched well with the histology results obtained at 7 weeks. In contrast, X-ray imaging appeared inappropriate to monitor the bone formation process in DBM.     

凝胶包埋骨髓基质干细胞复合脱钙骨基质修复关节软骨缺损简

目的探索Ⅱ型胶原凝胶包埋的自体骨髓基质干细胞（BMSCs）接于同种异体脱钙骨基质（DBM）材料修复兔关节软骨缺损的效果。方法15只健康成年新西兰大白兔,雌雄不限,体质量约3．0kg,兔龄6。9个月;以Urist方法制作同种异体DBM材料。以Ⅱ型胶原蛋白配制水凝胶．以水凝胶包埋兔BMSCs并接种于同种异体DBM材料,构建组织工程复合物。在新西兰大白兔股骨髁关节面制造软骨缺损。分组进行修复。将健康成年新西兰大白兔27只（雌雄不限,体质量约2．5kg．兔龄3～4个月）共54侧膝关节随机分为Ⅱ型胶原／DBM／BMSCs修复组（实验组）、Ⅱ型胶原／DBM修复组（实验对照组）及空白对照组。于术后4周、8周及12周各处死9只动物,取材对修复组织进行大体及组织学观察,根据Wakitani法对修复组织进行评分．数据输入SPSS11．5软件进行统计学分析,比较各组的评分差异是否具有统计学意义。结果实验组Ⅱ型胶原／DBM／BMSCs植入后形成透明软骨样修复．表面光滑平坦,与周围软骨及软骨下骨结合良好;实验对照组Ⅱ型胶原／DBM植入后有部分软骨样修复：而空白对照组仅有少量纤维性修复。根据组织学评分标准,实验组组织学评分为（20．25±1．64）分,高于实验对照组[（7．46±1．29）分]及空白对照组[（6．00±2．09）分]。结论Ⅱ型胶原自体BMSCs复合同种异体DBM支架材料修复全层关节软骨缺损的效果良好,是一种修复软骨缺损的行之有效的方法。     

A new in vivo model for testing cartilage grafts and biomaterials: the 'rabbit pinna punch-hole' model

In this study an animal model was developed for evaluation of the feasibility of cartilage grafts. In the cartilage of the external ear of the rabbit multiple holes, 6 mm in diameter, were punched, leaving the adherent skin intact. Different experimental groups were evaluated. First, the punch-hole model was validated under various conditions to study spontaneous or perichondrial initiated regeneration of the cartilage defect. When both cartilage and perichondrium was excised no spontaneous repair of the cartilage defect was observed. When perichondrium is present, variable patch-like closure of the punch hole was found. As 'golden standard' a punched out piece of cartilage was reimplanted directly. This condition showed adequate closure of the punch hole, however, no perfect integration of graft and surrounding cartilage was observed. Secondly, to evaluate the 'punch-hole model' a biomaterial, trabecular demineralized bovine bone matrix (DBM), was implanted and tested as a scaffold for tissue engineering techniques in vivo and in vitro. Direct implantation of DBM did not lead to any cartilage formation to close the defect. In vivo engineered cartilage, generated by enveloping DBM in perichondrium for 3 weeks, could adequately close the punch hole. When DBM was seeded with isolated chondrocytes in vitro before implantation in the defect, a highly fragmented graft, with some islets of viable cells was seen. To promote an efficient and reliable evaluation of cartilage grafts a semi-quantitative grading system was developed. Items such as quality, quantity and integrity of the cartilage graft were included in a histomorphological grading system to provide information about the properties of a specific cartilage graft. To validate the grading system, all conditions were scored by two independent observers. An excellent reliability (R = 0.96) was seen between the observers. In summary, the rabbit pinna punch-hole model is a reliable and efficient method for first evaluation of cartilage grafts. The results can be easily analyzed using a semi-quantitative grading system.     

Reconstruction of cartilage,bone, and hematopoietic microenvironment with demineralized bone matrix and bone marrow cells

Highly specialized hard tissues, such as cartilage, bone, and stromal microenvironment supporting hematopoiesis, originate from a common type of mesenchymal progenitor cell (MPC). We hypothesized that MPCs present in bone marrow cell suspension and demineralized bone matrix (DBM) that possess natural conductive and inductive features might constitute a unit containing all the essential elements for purposive bone and cartilage induction. Using a rodent preclinical model, we found that implantation of a composite comprising DBM and MPCs into A) a damaged area of a joint; B) an ablated bone marrow cavity, and C) a calvarial defect resulted in the generation of A) a new osteochondral complex comprising articular cartilage and subchondral bone; B) trabecular bone and stromal microenvironment supporting hematopoiesis, and C) flat bone, respectively. The new tissue formation followed differentiation pathways controlled by site-specific physiological conditions, thus developing tissues that precisely met local demands.     

Calcium sulfate-carboxymethylcellulose bone graft binder: Histologic and morphometric evaluation in a critical size defect

Calcium sulfate (CS) is widely used as a bone graft binder and expander. Recent reports indicate that carboxymethylcellulose (CMC) can improve the clinical properties of CS when used as binder for particulate bone grafts; however, limited information is available on the effects of CMC on bone regeneration. The purpose of this study was to evaluate the histologic and morphometric characteristics of bone formation in calvarial defects grafted with a CS-based putty containing 10% CMC in combination with allogeneic demineralized bone matrix (DBM). Bone formation and graft/binder resorption were compared with a surgical grade CS and DBM in paired critical-sized calvarial defects in 25 Wistar rats (350-450 g). Six animals each provided paired defects at 7, 14, 21, and 28 days postsurgery for nondecalcified processing and microscopic analysis. Defects grafted with CS or CS-CMC putty as the DBM binder exhibited similar patterns and proportions of bone formation, fibrous tissue/marrow, and residual DBM particles. Comparable mean +/- SD proportions of new bone formation (31.7 +/- 9.5 and 33.7 +/- 12.9), fibrous tissue/marrow (54.2 +/- 8.3 and 53.0 +/- 10.8), residual DBM particles (8.3 +/- 6.8 and 10.1 +/- 6.3), and residual binder material (5.5 +/- 4.6 and 3.7 +/- 3.5) were found at 28 days for defects grafted with CS and CS-CMC putty, respectively. Thus, CMC was found to improve the handling characteristics of CS and, when used in conjunction with DBM, supported comparable levels bone formation and patterns of binder/scaffold resorption as CS and DBM in a calvarial defect model.     

Histological characterization of the early stages of bone morphogenetic protein-induced osteogenesis

On the basis of currently available knowledge, we hypothesize that the initial bone formation, as induced by bone morphogenetic protein (BMP), is influenced by the chemical composition and three-dimensional spatial configuration of the used carrier material. Therefore, in the current study, the osteoinductive properties of porous titanium (Ti) fiber mesh with a calcium phosphate (Ca-P) coating (Ti-CaP), insoluble bone matrix (IBM), fibrous glass membrane (FGM), and porous particles of hydroxy apatite (PPHAP) loaded with rhBMP-2 were compared in a rat ectopic assay model at short implantation periods. Twelve Ti-CaP, 12 IBM, 12 FGM, and 12 PPHAP implants, loaded with rhBMP-2, were subcutaneously placed in 16 Wistar King rats. The rats were sacrificed at 3, 5, 7, and 9 days post-operative, and the implants were retrieved. Histological analysis demonstrated that IBM and Ti-CaP had induced ectopic cartilage and bone formation by 5 and 7 days, respectively. However, in PPHAP, bone formation and cartilage formation were seen together at 7 days. At 9 days, in Ti-CaP, IBM, and PPHAP, cartilage was seen together with trabecular bone. At 9 days, in FGM, only cartilage was observed. Quantitative rating of the tissue response, using a scoring system, demonstrated that the observed differences were statistically significant (Wilcoxon rank sum test, p < 0.05). We conclude that IBM, CaP-coated Ti mesh, FGM, and PPHAP provided with rhBMP-2 can indeed induce ectopic bone formation with a cartilaginous phase in a rat model at short implantation periods. Considering the different chemical composition and three-dimensional spatial configuration of the carrier materials used, these findings even suggest that endochondral ossification is present in rhBMP-2-induced osteogenesis, even though the amount of cartilage may differ.     

Behavior of dense and porous hydroxyapatite implants and tissue response in rat femoral defects

Porous and dense hydroxyapatite cylinders (PHA and DHA) were implanted into cavities produced in rat femora and the sites of implantation were examined at different times over a period of 24 weeks by microradiologic and histological techniques. Microradiographs showed the presence of a layer of trabecular bone around the implants, which became more radiopaque and thinner along the experimental time. The microradiologic methodology used was suitable for the evaluation of the interface between hydroxyapatite and newly formed bone in nondecalcified materials. Microscopic observations showed that young bone grew over the surface of both types of implants after 1 and 2 weeks of surgery and that bone also grew inside PHA implants. Progressive bone absorption was observed in both types of implants after the fourth week. A layer of fibrous tissue was formed in the interface between new bone and DHA. Mature bone with haversian systems surrounded DHA implants and filled the pores of PHA implants throughout the experimental period. The pores of PHA implants were smaller than those commonly reported, which should have been a disadvantage, although it was observed that the extra cellular fluid induced disintegration of the ceramic granules, allowing the gradual growth of bone tissue into the spaces among them, without the interposition of fibrous tissue.     

Use of dual-energy X-ray absorptiometry (DEXA) to follow mineral content changes in small ceramic implants in rats.

Dual energy X-ray absorptiometry (DEXA) imaging was used to quantify bone ingrowth into hydroxyapatite (HA) ceramic implants in rats. HA cylinders implanted in the proximal tibiae were followed for 13 wk. The increase in alkaline phosphatase (ALP) activity within the implants preceded the increase in mineral content as measured non-invasively by the DEXA technique. This was consistent with the timing of ALP activity in respect of mineralization as they occur during fracture healing. The results show that DEXA imaging is useful in measuring bone ingrowth into small ceramic HA implants in vivo, despite the high mineral content background of the implant scaffold.     

Stem cell-coated titanium implants for the partial joint resurfacing of the knee

The goal of the present study was to evaluate the partial surface replacement of the knee with stem cell-coated titanium implants and to provide a basis for a successful treatment of large osteochondral defects. Mesenchymal stem cells (MSCs) were isolated from bone marrow aspirates of adult sheep. Round titanium implants with a diameter of 2 x 7.3 mm were seeded with autologous MSC and inserted into an osteochondral defect in the medial femoral condyle. As controls, defects received either an uncoated implant or were left untreated. Nine animals with 18 defects were sacrificed after 6 months. Histological evaluation was performed by intravital polychrome fluorescent labelling, intravital perfusion with Indian ink, microradiographs and differential staining with toluidine blue. The quality of regenerated cartilage was assessed by in situ hybridization of collagen type II and immunohistochemistry of collagen types I and II. In 50% of the cases, defects treated with MSC-coated implants showed a complete regeneration of the subchondral bone layer. In these cases collagen type II and only traces of collagen type I were detected. A high level of collagen type II mRNA expression compared to articular cartilage indicates regenerating hyaline-like cartilage. A total of 50% of MSC-coated and uncoated implants failed to osseointegrate and formation of fibrocartilage was observed. Untreated defects as well as defects treated with uncoated implants demonstrated incomplete healing of subchondral bone and formation of fibrous cartilage. A modified histological score according to Wakitani significantly demonstrated better results for cell-coated implants (8.8+/-6.4) than for uncoated implants (5.5+/-3.9) and for untreated defects (2.8+/-2.5). Our results demonstrate that, in a significant number of cases, a partial joint resurfacing of the knee with stem cell-coated titanium implants occur. A slow bone and cartilage regeneration and an incomplete healing in half of the MSC-coated implants are limitations of the presented method. To improve our approach and optimize the experimental parameters, further investigations are needed prior to clinical application.     

硫酸钙/脱钙骨基质颗粒在颈椎椎体间融合中的应用

目的观察应用硫酸钙/脱钙骨基质颗粒作为植骨替代材料促进颈椎椎体间融合的效果。方法对35例患者﹙59个节段﹚行颈椎前路间隙减压植骨融合钛板固定术,椎体间植骨采用填充硫酸钙/脱钙骨基质颗粒的聚醚醚酮﹙PEEK﹚融合器。其中男19例,女16例,年龄32~65岁,平均53.2±12.5岁。其中神经根型颈椎病12例,脊髓型颈椎病15例,混合型颈椎病8例。术后观察JOA评分、颈椎曲度、椎体间融合情况。结果 35例均获随访,随访时间24个月。JOA评分术前为7.7±2.1,随访终止时为14.2±2.9﹙<0.01﹚,恢复率为69.9%。术后无钛板、螺钉断裂或松动,无融合器移位现象发生。所有融合节段均融合。结论颈椎前路减压融合术中使用填充硫酸钙/脱钙骨基质颗粒的PEEK椎体间融合器能够获得满意的椎体间融合。