Previous clinical studies have shown the efficacy of a foreign body-induced membrane combined with bone autograft for the reconstruction of traumatologic or pathologic large bone defects or, bone non union. This membrane, rich in mesenchymal stromal cells (MSC), avoids bone autograft resorption and promotes consolidation by revascularisation of the bone and secretion of growth factors. Reconstruction requires two different surgical stages: firstly, insertion of a cement spacer in the defect, and secondly, removal of the spacer, preservation of the foreign body-induced membrane and filling of the cavity by bone autograft. The optimal time to perform the second surgical stage remains unclear. So, we aimed to correlate bone healing and, phenotype and function of cells isolated from the induced membrane, in patients whose second surgery was performed on average after 6 months (i.e. beyond the recommended time of one month). Cell phenotype was determined by flow cytometry and cell function by: alkaline Phosphatase enzyme activity, secretion of calcium and von Kossa staining. Second, using histological and immunohistochemistry studies, we aimed to determine the nature and function of induced membrane over time. Seven patients were included with their consent. Results showed Treated patients achieved in all cases bone union (except for one patient) and in in vitro and histology and immunohistochemistry gave some indications which need to be completed in the future. First, patient age seemed to be an indicator of bone union speed and recurrent infection, appeared to influence in vitro MSC osteogenic potential and induced membrane structure. Second, we reported, in bone repair situation, the commitment over time in osteogenic lineage of a surprising multipotent tissue (induced membrane) able of vascularisation/ osteogenesis/ chondrogenesis at a precocious time. Finally, best time to perform the second stage (one month) could be easily exceeded since bone union occurred even at very late times

Spinal fusion is one of the most common surgical procedures in spine surgery, whose primary objective is the stabilization of the spine for the treatment of many degenerative, traumatic and oncological diseases of the spine. Autologous bone is still considered the “gold standard” technique for spinal fusion. However, biomaterials which are potentially osteogenic, osteoinductive and osteoconductive can be used to increase the process of spinal fusion. We evaluated two new bone substitutes as an alternative to autologous bone for spinal fusion, using an animal model of large size (adult sheep). A preclinical study was designed to compare the efficacy of SINTlife® Putty and DBSINT® biomaterials with conventional bone autograft in an ovine model of lumbar spine fusion. SINTlife® is a biomaterial made from hydroxyapatite enriched with magnesium ions, resulting to be very similar to natural bone. DBSint® is a paste composite bone, osteo-inductive, pliable and conformable, consisting of demineralized bone matrix (DBM) carried by hydroxyapatite biomimetics. Eighteen adult female sheep were selected for two-levels spine surgical procedures. The animals were divided in two groups: in Group A, one fusion level was treated with SINTlife® Putty and the other level received cortical-cancellous bone autograft; in Group B, one fusion level was treated with DBSINT® and the other level received cortical-cancellous bone autograft. At the end of the experimental time, all the animals were euthanized. The spine segments were analyzed macroscopically, radiographically, microtomographically, histologically and histomorphometrically. The SINT-Life® Putty shows a perfect osteointegration in all the histological specimens. A high percentage of newly formed bone tissue is detected, with lots of trabeculae having structure and morphology similar to the pre-existing bone. In all the specimens collected from DBSINT®-treated animals the presence of hydroxyapatite alone is reported but not the demineralized bone matrix. The presence of newly formed bone tissue can be detected in all the specimens but newly formed bone shows very thin and irregular trabeculae next to the cartilage zone, while away from the border of ossification there are thicker trabeculae similar to the pre-existing bone. The use of the experimental biomaterial SINT-Life® Putty in an ovine model of spine fusion leads to the development of newly formed bone tissue without qualitative and quantitative differences with the one formed with autologous bone. The experimental material DBSINT® seems to lead to less deposition of newly formed bone with wider intertrabecular spaces. Following these results, we planned and submitted to the Ethical Committee a clinical study to evaluate the safety and efficacy of SINT-Life® product in comparison to autologous bone, as an alternative treatment for spine fusion procedures

Joint surface restoration of deep osteochondral defects represents a significant unmet clinical need. Moreover, untreated lesions lead to a high rate of osteoarthritis. The current strategies to repair deep osteochondral defects such as osteochondral grafting or sandwich strategies combining bone autografts with ACI/MACI fail to generate long-lasting osteochondral interfaces. Herein, we investigated the capacity of juvenile Osteochondral Grafts (OCGs) to repair osteochondral defects in skeletally mature animals. With this regenerative model in view, we set up a new biological, bilayered, and scaffold-free Tissue Engineered (TE) construct for the repair of the osteochondral unit of the knee. Skeletally immature (5 weeks old) and mature (11 weeks old) Lewis rats were used. Cylindrical OCGs were excised from the intercondylar groove of the knee of skeletally immature rats and transplanted into osteochondral defects created in skeletally mature rats. To create bilayered TE constructs, micromasses of human periosteum-derived progenitor cells (hPDCs) and human articular chondrocytes (hACs) were produced in vitro using chemically defined medium formulations. These constructs were subsequently implanted orthotopically in vivo in nude rats. At 4 and 16 weeks after surgery, the knees were collected and processed for subsequent 3D imaging analysis and histological evaluation. Micro-computed tomography (µCT), H&E and Safranin O staining were used to evaluate the degree of tissue repair. Our results showed that the osteochondral unit of the knee in 5 weeks old rats exhibit an immature phenotype, displaying active subchondral bone formation through endochondral ossification, the absence of a tidemark, and articular chondrocytes oriented parallel to the articular surface. When transplanted into skeletally mature animals, the immature OCGs resumed their maturation process, i.e., formed new subchondral bone, partially established the tidemark, and maintained their Safranin O-positive hyaline cartilage at 16 weeks after transplantation. The bilayered TE constructs (hPDCs + hACs) could partially recapitulate the cascade of events as seen with the immature OCGs, i.e., the regeneration of the subchondral bone and the formation of the typical joint surface architecture, ranging from non-mineralized hyaline cartilage in the superficial layers to a progressively mineralized matrix at the interface with a new subchondral bone plate. Cell-based TE constructs displaying a hierarchically organized structure comprising of different tissue forming units seem an attractive new strategy to treat osteochondral defects of the knee

Objectives. To compare the therapeutic potential of tissue-engineered constructs (TECs) combining mesenchymal stem cells (MSCs) and coral granules from either Acropora or Porites to repair large bone defects. Materials and Methods. Bone marrow-derived, autologous MSCs were seeded on Acropora or Porites coral granules in a perfusion bioreactor. Acropora-TECs (n = 7), Porites-TECs (n = 6) and bone autografts (n = 2) were then implanted into 25 mm long metatarsal diaphyseal defects in sheep. Bimonthly radiographic follow-up was completed until killing four months post-operatively. Explants were subsequently processed for microCT and histology to assess bone formation and coral bioresorption. Statistical analyses comprised Mann-Whitney, t-test and Kruskal–Wallis tests. Data were expressed as mean and standard deviation. Results. A two-fold increaseof newly formed bone volume was observed for Acropora-TECs when compared with Porites-TECs (14 . sd. 1089 mm. 3. versus 782 . sd. 507 mm. 3. ; p = 0.09). Bone union was consistent with autograft (1960 . sd. 518 mm. 3. ). The kinetics of bioresorption and bioresorption rates at four months were different for Acropora-TECs and Porites-TECs (81% . sd. 5% versus 94% . sd. 6%; p = 0.04). In comparing the defects that healed with those that did not, we observed that, when major bioresorption of coral at two months occurs and a scaffold material bioresorption rate superior to 90% at four months is achieved, bone nonunion consistently occurred using coral-based TECs. Discussion. Bone regeneration in critical-size defects could be obtained with full bioresorption of the scaffold using coral-based TECs in a large animal model. The superior performance of Acropora-TECs brings us closer to a clinical application, probably because of more suitable bioresorption kinetics. However, nonunion still occurred in nearly half of the bone defects. Cite this article: A. Decambron, M. Manassero, M. Bensidhoum, B. Lecuelle, D. Logeart-Avramoglou, H. Petite, V. Viateau. A comparative study of tissue-engineered constructs from Acropora and Porites coral in a large animal bone defect model. Bone Joint Res 2017;6:208–215. DOI: 10.1302/2046-3758.64.BJR-2016-0236.R1

In the treatment of bone non-unions an alternative to bone autografts is the use of bone morphogenetic proteins (BMP-2, BMP-7) with powerful osteoinductive and osteogenic properties. In clinical settings, BMPs are applied using absorbable collagen sponges. Supraphysiological doses are needed and major side effects may occur as induce ectopic bone formation, chronic inflammation and excessive bone resorption. In order to increase the efficiency of the delivered for BMPs we designed cryostructured collagen scaffolds functionalized with hydroxyapatite, mimicking the structure of cortical bone (aligned porosity, anisotropic, ANI) or trabecular bone (random distributed porosity, isotropic, ISO). We hypothesize that anisotropic structure would enhance osteoconductive properties of the scaffolds increasing rhBMP-2 regenerative properties. In vitro, both scaffolds presented similar mechanical properties, rhBMP-2 retention and delivery capacity. For in vivo testing, a rat femoral critical size defect model was created. Four groups were assessed depending on the implant applied to the bone defect: ISO, unloaded isotropic sponge; ISO-BMP, isotropic sponge loaded with 5 μg of hrBMP-2; ANI, unloaded anisotropic sponge; and ANI-BMP, anisotropic sponge loaded with 5 μg of hrBMP-2. Regeneration was allowed for 10 weeks. X-ray, μCT, biomechanical testing and histology were used to evaluate repair. Independently of their structure, sponges loaded with rhBMP-2 demonstrate increased bone volume, and biomechanical properties than their controls (p<0.01 and p<0.05 respectively). Globally, ANI-BMP group demonstrated better bone regeneration outputs with increased defect bridging (p<0.05 when compared ANI-BMP vs ISO-BMP groups). In conclusion, anisotropic cryostructured collagen scaffolds improve the efficiency of rhBMP-2 in bone regeneration

Introduction. Augmentation of spinal fusion using bone grafts is largely mediated by the osteoinductive potential of mesenchymal stem cells (MSC) that reside in cancellous bone. Iliac crest (IC) is a common autograft, but its use presents an increased risk for donor-site pain, morbidity and infection. Degenerative facet joints (FJ) harvested during facetectomy might servce as alternative local grafts. In this study, we conducted an intra-individual comparison of the osteogenic potential of MSC from both sources. Methods. IC and degenerative FJ were harvested from 8 consecutive patients undergoing transforaminal lumbar interbody fusion surgery for spinal stenosis. MSC were isolated by collagenase digestion, selected by plastic adherence and minimally expanded for downstream assays. Clonogenic and osteogenic potential was evaluated by colony formation assays in control and osteogenic culture medium. Osteogenic properties, including alkaline phosphatase (ALP) induction, matrix mineralization and type I collagen mRNA and protein expression were characterized using quantitative histochemical staining and reverse transcription PCR. Spontaneous adipogenesis was analysed by adipocyte enumeration and gene expression analysis of adipogenic markers. Results. Average colony-forming efficiency in osteogenic medium was equal between IC (38±12%) and FJ (36±11%). Osteogenic potential at the clonal level was 55±26 and 68±17% for IC and FJ MSC, respectively. Clonogenic and osteogenic potential were significantly negatively associated with donor age. Osteogenic differentiation led to significant induction of ALP activity in IC (6-fold) and FJ (8-fold) MSC. Matrix mineralization quantified by Alizarin red staining was increased by osteogenic differentiation, yet similar between both MSC sources. Protein expression of type I collagen was enhanced during osteogenesis and significantly greater in IC MSC. Correspondingly, COL1A2 mRNA expression was higher in osteogenically differentiated MSC from IC. Adipocyte numbers showed significant differences between IC (63±60) and FJ (18±15) MSC under osteogenic conditions. Negative (GREM1) and positive (FABP4) adipogenic markers were not differentially expressed between sources. Conclusion. MSC from IC and degenerative FJ largely display similar clonogenic and osteogenic properties in vitro. Differences at the molecular level are not likely to impair the osteoinductive capacity of FJ MSC. Facetectomy samples are viable bone autografts for intervertebral spinal fusion

Introduction. Elevated remodelling of subchondral bone and marrow tissues has been firmly established as diagnostic and prognostic radiological imaging marker for human osteoarthritis. While these tissues are considered as promising targets for disease-modifying OA drugs, the development of novel treatment approaches is complicated by the lack of knowledge whether similar tissue changes occur in rodent OA models and poor understanding of joint-specific molecular and cellular pathomechanisms in human OA. Here, we describe the establishment of a human OA explant model to address this crucial niche in translational preclinical OA research. Methods. Osteochondral (knee, spine) and bone (iliac crest) clinical specimens were acquired from patients undergoing total knee arthroplasty (n=4) or lumbar spine fusion using bone autografts (n=6). Fresh specimens were immediately cut in equal-sized samples (50–500 mg wet weight) and cultured in 8 mL osteogenic medium for one week. Samples were either left untreated (control) or stimulated with lipopolysaccharide (LPS, 100 ng/mL) in the absence and presence of transforming growth factor-beta inhibitor (SB-505124, 10 μm). Pro-collagen-I (Col-I), interleukin-6 (IL-6) and monocyte chemoattractant protein 1 (MCP-1) secretion was determined in conditioned medium by ELISA. Tissue viability was assessed using MTT and alkaline phosphatase (ALP) activity staining. Results. Explanted tissues remained viable after one week culture in control and treatment conditions. Osteocytes, subchondral marrow spaces and calcified cartilage stained positive for ALP activity without gross morphological differences between groups. Median basal secretion levels were Col-I (2.3 ng/mg), IL-6 (90 pg/mg) and MCP-1 (25 pg/mg). LPS treatment led to a significant increase of IL-6 (330 pg/mg) and MCP-1 (70 pg/mg), but not Col-I secretion. Interestingly, inhibition of TGF-beta signalling in osteochondral tissues specifically reduced Col-I levels (0.4 ng/mg) compared to controls and LPS-treated samples. LPS-induced IL-6 and MCP-1 levels were slightly reduced (−120 pg/mg, p=0.03) and increased (+50 pg/mg) by SB-505124 treatment, respectively. IL-6 and MCP-1 levels were strongly correlated under basal (r=0.80) and treatment conditions (r=0.62). Conclusion. In this study, we provided proof of concept for the first ex vivo explant model of human osteoarthritis. Osteochondral tissue specimens can readily be cultured without loss of tissue viability and mount a robust inflammatory response upon LPS challenge. Treatment with a potential disease-modifying agent (TGF-beta signalling inhibitor) reduced collagen metabolism in bone and marrow and modified cytokine and chemokine expression. The osteochondral explant model might be highly valuable to evaluate disease-modifying OA drugs

INTRODUCTION. In the treatment of nonunions, and other complications of bone repair, an attractive alternative to bone autografts would be the use of a combination of autologous mesenchymal progenitors cells (MSCs), biomaterials and growth factors. Our goal was to determine the therapeutic potential and contribution to the repair process of different sources of mesenchymal stem cells for the treatment of nonunions. METHODS. The right femur of Sprague-Dawley (SD) rats was stabilized with an aluminum plate (20 mm long, 4 mm wide, 2 mm thick) and four screws (1.5 mm diameter, 8 mm long). A diaphyseal critical size defect was performed (5 mm). Six groups (n=6–8 animals each) were created. A nonunion group (Control group, empty defect); LBA group, live bone allograft; BMP2 group, rhBMP-2 (2 μg) in collagen sponge; PCL group, polycaprolactone scaffold; PMSCs group, PCL scaffold loaded with 5×10. 6. periosteum-derived MSCs; and BMSCs group, PCL scaffold loaded with 5×10. 6. bone marrow-derived MSCs. For cell tracking purposes, LBA and MSCs were derived from SD-GFP transgenic rats. The repair process was followed up by x-rays up to sacrifice, week 10. After sacrifice, femurs were analyzed by micro computed tomography (μCT), histology and immunohistochemistry. For multiple comparisons one-way ANOVA followed by Dunnett”s test for single comparisons was used. Statistical significance was established for p<0.05. RESULTS. Control group did not show healing during follow up or by μCT and histological analysis. Treatment groups BLA and BMP2 showed full healing by week 10 (LBA, 6 out of 6 animals; BMP2, 4 out of 6 animals). The repair callus was quantified by mCT, Control group showed limited formation of bone (11.47±2.01 mm. 3. ) while both LBA and BMP2 groups showed increased bone formation by week 10 when compared with control group (LBA, 35.36±2.24 mm. 3. , p=0.0022; BMP2, 33.32±1.84 mm. 3. , p=0.0022). Histological and μCT analysis confirmed the experimental nonunion model. In PCL treated groups a low number of animals showed radiographic healing: PCL group 1 out of 8 animals; PMSCs group, 2 out of 6 animals; BMSCs group, 0 out of 6 animals. Interestingly, quantification of the repaired callus showed that only PMSCs group produced a significant volume of bone when compared with the Control group (PMSCs, 24.97±6.03 mm. 3. , p=0.0411). PCL and BMSCs groups do not produced significant amount of bone in the repair callus (PCL, 19.00±4.25 mm. 3. , p=0.3095; BMSCs, 12.88±2.38 mm. 3. , p=0.9372). Healing was confirmed by histology and μCT analysis. Finally, the engraftment of transplanted cells was analysed by immunohistochemistry (anti-GFP antibody). Of the three groups receiving cells only the LBA group showed positive signal for GFP at week 10-post surgery. CONCLUSIONS. In conclusion, periosteum-derived progenitor cells are suitable for mimetic autograft design although integration is not yet achieved

Limited success in regenerating large bone defects has been achieved by bridging them with osteoconductive materials. These substitutes lack the osteogenic and osteoinductive properties of bone autograft. A direct approach would be to stimulate osteogenesis in these biomaterials by the addition of fresh bone-marrow cells (BMC). We therefore created osteoperiosteal gaps 2 cm wide in the ulna of adult rabbits and either bridged them with coral alone (CC), coral supplemented with BMC, or left them empty. Coral was chosen as a scaffold because of its good biocompatibility and resorbability. In osteoperiosteal gaps bridged with coral only, the coral was invaded chiefly by fibrous tissue. It was insufficient to produce union after two months. In defects filled with coral and BMC an increase in osteogenesis was observed and the bone surface area was significantly higher compared with defects filled with coral alone. Bony union occurred in six out of six defects filled with coral and BMC after two months. An increase in the resorption of coral was also observed, suggesting that resorbing cells or their progenitors were present in bone marrow and survived the grafting procedure. Our findings have shown that supplementation of coral with BMC increased both the resorption of material and osteogenesis in defects of a clinical significance

Short Summary. The present study demonstrated the feasibility of culturing a large number of standardised granular MSC-containing constructs in a packed bed/column bioreactor that can produce sheep MSC-containing constructs to repair critical-size bone defects in sheep model. Introduction. Endogenous tissue regeneration mechanisms do not suffice to repair large segmental long-bone defects. Although autologous bone graft remains the gold standard for bone repair, the pertinent surgical technique is limited. Tissue constructs composed of MSCs seeded onto biocompatible scaffolds have been proposed for repairing bone defects and have been established in clinically-relevant animal models. Producing tissue constructs for healing bone defects of clinically-relevant volume requires a large number of cells to heal an approximately 3 cm segmental bone defect. For this reason, a major challenge is to expand cells from a bone marrow aspirate to a much larger, and sufficient, number of MSCs. In this respect, bioreactor systems which provide a reproducible and well-controlled three-dimensional (3D) environment suitable for either production of multiple or large size tissue constructs are attractive approaches to expand MSCs and obtain MSC-containing constructs of clinical grade. In these bioreactor systems, MSCs loaded onto scaffolds are exposed to fluid flow, a condition that provides both enhanced access to oxygen and nutrients as well as fluid-flow-driven mechanical stimulation to cells. The present study was to evaluate bioreactor containing autologous MSCs loaded on coral scaffolds to repair critical-size bone defects in sheep model. Materials and Methods. Animals: 12 two-year-old, female Pre-Alpes sheep were used and reared in accordance with the European Committee for Care. Three-dimensional, porous scaffolds (each 3×3×3 mm) of natural coral exoskeleton were used as substrates for cell attachment. The packed bed/column bioreactor set-up used in the present study was composed of a vertical column filled with MSC-containing constructs. Sheep MSCs were isolated from sheep bone marrow. MSCs were seeded on scaffolds and cultured overnight under standard cell-culture condition. MSC-containing constructs were r placed into the perfusion bioreactor and were either exposed to a perfusion medium flow rate of 10 mL/min for 7 continuous days. Osteoperiosteal segmental (25 mm) defects were made in the left metatarsal bone of 12 sheep. The defect was either filled with coral scaffolds alone (Group 1; five sheep); or filled with coral scaffolds loaded with MSCs (Group 2; five sheep); or filled with autologous bone graft (Group 3; 2 sheep). Results. At 6 month after implantation, radiographs showed resorption of the coral scaffold in all animals but this process was not complete and not the same in all animal. At 6 month radiographs showed more bone formation in group 2 than in group 1. New bone formation volume in each defect was assessed by micro-computed tomography. Volume of bone healing was higher in group 2 than group 1. Discussion. The potential of MSC-containing constructs in a bioreactor for repairing long segmental critical-sized bone defects in sheep was investigated. In one animal of the group 2 the volume of new bone formation was 2066 mm3 and was similar to the bone volume of group 3 (2300 mm3). Our results may have important implications in bone tissue engineering. We observed that the bone tissue regenerationosteogenic ability of bone constructs processed in bioreactor approached the bone autografts

Objectives

To explore the therapeutic potential of combining bone marrow-derived mesenchymal stem cells (BM-MSCs) and hydroxyapatite (HA) granules to treat nonunion of the long bone.

Objectives

Osteophytes are products of active endochondral and intramembranous ossification, and therefore could theoretically provide significant efficacy as bone grafts. In this study, we compared the bone mineralisation effectiveness of osteophytes and cancellous bone, including their effects on secretion of growth factors and anabolic effects on osteoblasts.

External fixation of distal tibial fractures is often associated with delayed union. We have investigated whether union can be enhanced by using recombinant bone morphogenetic protein-7 (rhBMP-7).

Osteoinduction with rhBMP-7 and bovine collagen was used in 20 patients with distal tibial fractures which had been treated by external fixation (BMP group). Healing of the fracture was compared with that of 20 matched patients in whom treatment was similar except that rhBMP-7 was not used.

Significantly more fractures had healed by 16 (p = 0.039) and 20 weeks (p = 0.022) in the BMP group compared with the matched group. The mean time to union (p = 0.002), the duration of absence from work (p = 0.018) and the time for which external fixation was required (p = 0.037) were significantly shorter in the BMP group than in the matched group. Secondary intervention due to delayed healing was required in two patients in the BMP group and seven in the matched group.

RhBMP-7 can enhance the union of distal tibial fractures treated by external fixation.

Critical size defects in ovine tibiae, stabilised with intramedullary interlocking nails, were used to assess whether the addition of carboxymethylcellulose to the standard osteogenic protein-1 (OP-1/BMP-7) implant would affect the implant’s efficacy for bone regeneration. The biomaterial carriers were a ‘putty’ carrier of carboxymethylcellulose and bovine-derived type-I collagen (OPP) or the standard with collagen alone (OPC). These two treatments were also compared to “ungrafted” negative controls. Efficacy of regeneration was determined using radiological, biomechanical and histological evaluations after four months of healing. The defects, filled with OPP and OPC, demonstrated radiodense material spanning the defect after one month of healing, with radiographic evidence of recorticalisation and remodelling by two months. The OPP and OPC treatment groups had equivalent structural and material properties that were significantly greater than those in the ungrafted controls. The structural properties of the OPP- and OPC-treated limbs were equivalent to those of the contralateral untreated limb (p > 0.05), yet material properties were inferior (p < 0.05). Histopathology revealed no residual inflammatory response to the biomaterial carriers or OP-1. The OPP- and OPC-treated animals had 60% to 85% lamellar bone within the defect, and less than 25% of the regenerate was composed of fibrous tissue. The defects in the untreated control animals contained less than 40% lamellar bone and more than 60% was fibrous tissue, creating full cortical thickness defects. In our studies carboxymethylcellulose did not adversely affect the capacity of the standard OP-1 implant for regenerating bone.