Induction of chondrogenesis with a RANKL-binding peptide, WP9QY, in vitro and in vivo in a rabbit model.

WP9QY (W9) is a receptor activator of nuclear factor-κB ligand (RANKL)-binding peptide that inhibits osteoclastogenesis by blunting the RANKL-RANK interaction, and also increases osteoblastogenesis via RANKL reverse signaling. W9 has dual effects on osteoclasts and osteoblasts; however, it is unknown whether the peptide has an effect on chondrocytes. Here, we report that W9 induces proliferation and differentiation of chondrocytes in vitro and repairs full-thickness articular cartilage defects in vivo. W9 stimulated chondrocyte differentiation in a two-dimensional (2D) culture of human mesenchymal stem cells (hMSCs), and transforming growth factor ß3 (TGF-ß3) showed synergistic effects with W9 on chondrogenesis. W9 enlarged the size of 3D pellet cultures of hMSCs and produced chondrocyte-specific matrices, especially in combined treatment with TGF-ß3. The peptide also stimulated proliferation of hMSCs with induction of expression of chondrogenesis-related genes. Several RANKL inhibitors had no effect on chondrocytic differentiation. RANKL-knockdown experiments showed that W9 did not induce chondrogenesis through RANKL, but did induce osteoblastogenesis through RANKL. Intraarticular injection of W9 resulted in significant repair of full-thickness articular cartilage defects in rabbits. Taken together, these results suggest that W9 ameliorates the articular cartilage defects by increasing the volume of cartilaginous matrices with accompanying induction of proliferation and differentiation of chondrocytes via mechanisms independent of RANKL inhibition and RANKL reverse signaling. Since no pharmaceuticals are clinically available for treatment of cartilage damage such as osteoarthritis, our findings demonstrate the potential of W9 to address the unmet medical needs.

Transplantation of autologous bone marrow-derived mesenchymal stem cells under arthroscopic surgery with microfracture versus microfracture alone for articular cartilage lesions in the knee: A multicenter prospective randomized control clinical trial.

INTRODUCTION: To investigate the efficacy of the transplantation of autologous bone marrow-derived mesenchymal stem cells (BMSCs) under arthroscopy with microfracture (MFX) compared with microfracture alone. METHODS: Eleven patients with a symptomatic articular cartilage defect of the knee were included in the study. They were randomized to receive BMSCs with MFX (cell-T group, n=7) or MFX alone (control group, n=4). Clinical results were evaluated using International Knee Documentation committee (IKDC) knee evaluation questionnaires and the Knee Injury and Osteoarthritis Outcome Score (KOOS) before and 48 weeks after surgery. Quantitative and qualitative assessments of repair tissue were carried out at 48 weeks by T2 mapping of magnetic resonance images (MRIs) and the magnetic resonance observation of cartilage repair tissue (MOCART) scoring system with follow-up MRI. RESULTS: No significant differences between preoperative and postoperative IKDC and KOOS were observed in the cell-T or control group. However, forty-eight weeks after surgery, the cell-T group showed a trend for a greater KOOS QOL score compared with the control group (79.4 vs. 39.1, respectively; P=0.07). The T2 value did not differ significantly between the two groups, but the mean MOCART score was significantly higher in the cell-T group than in the control group (P=0.02). CONCLUSIONS: Compared with MFX alone, BMSC transplantation with MFX resulted in better postoperative healing of the cartilage and subchondral bone as determined by the MOCART score. Clinically, BMSC transplantation with MFX gave a higher KOOS QOL score after 48 weeks.

Quality Evaluation of Human Bone Marrow Mesenchymal Stem Cells for Cartilage Repair.

Quality evaluation of mesenchymal stem cells (MSCs) based on efficacy would be helpful for their clinical application. In this study, we aimed to find the factors of human bone marrow MSCs relating to cartilage repair. The expression profiles of humoral factors, messenger RNAs (mRNAs), and microRNAs (miRNAs) were analyzed in human bone marrow MSCs from five different donors. We investigated the correlations of these expression profiles with the capacity of the MSCs for proliferation, chondrogenic differentiation, and cartilage repair in vivo. The mRNA expression of MYBL1 was positively correlated with proliferation and cartilage differentiation. By contrast, the mRNA expression of RCAN2 and the protein expression of TIMP-1 and VEGF were negatively correlated with proliferation and cartilage differentiation. However, MSCs from all five donors had the capacity to promote cartilage repair in vivo regardless of their capacity for proliferation and cartilage differentiation. The mRNA expression of HLA-DRB1 was positively correlated with cartilage repair in vivo. Meanwhile, the mRNA expression of TMEM155 and expression of miR-486-3p, miR-148b, miR-93, and miR-320B were negatively correlated with cartilage repair. The expression analysis of these factors might help to predict the ability of bone marrow MSCs to promote cartilage repair.

Effect of epigallocatechin-3-gallate on the increase in type II collagen accumulation in cartilage-like MSC sheets.

With the aim to increase type II collagen content in the scaffold-free cartilage-like cell sheet using human bone marrow mesenchymal stem cells, we examined the effect of epigallocatechin-3-gallate (EGCG) addition to the chondrogenic medium for the cell sheet culture. The addition of EGCG (10 µM) increased the content of type II collagen 2-fold, while the addition did not markedly change the expression level of the genes encoding type II collagen and Sox 9. The reactive oxygen species level in the cells in cell sheets was thought to be too low to suppress the accumulation of type II collagen. On the other hand, the addition of EGCG markedly decreased both the matrix metalloproteinase-13 concentration in the supernatant of cell sheet culture and the type II collagen degradation activity in that supernatant. Taken together, EGCG may enhance the accumulation of type II collagen by suppressing type II collagen degradation.

Loss of lean body mass affects low bone mineral density in patients with rheumatoid arthritis - results from the TOMORROW study.

OBJECTIVES: Osteoporosis is one of the complications for patients with rheumatoid arthritis (RA). Rheumatoid cachexia, the loss of lean body mass, is another. However, the relationship between decreased lean body mass and reduced bone mineral density (BMD) in patients with RA has not been well studied. METHODS: This study included 413 participants, comprising 208 patients with RA and 205 age- and sex-matched healthy volunteers. Clinical data, BMD, bone metabolic markers (BMM) and body composition, such as lean body mass and percent fat, were collected. Risk factors for osteoporosis in patients with RA including the relationship BMD and body composition were analyzed. RESULTS: Patients with RA showed low BMD and high BMM compared with controls. Moreover, lean body mass was lower and percent fat was higher in patients with RA. Lean body mass correlated positively and percent fat negatively with BMD. Lean body mass was a positive and disease duration was a negative independent factor for BMD in multivariate statistical analysis. CONCLUSION: BMD and lean body mass were significantly lower in patients with RA compared to healthy controls. Lean body mass correlated positively with BMD and decreased lean body mass and disease duration affected low BMD in patients with RA. TRIAL REGISTRATION: [UMIN Clinical Trials Registry, http://www.umin.ac.jp/ctr/ , UMIN000003876].

Irx3 and Bmp2 regulate mouse mesenchymal cell chondrogenic differentiation in both a Sox9-dependent and -independent manner.

Sox9, a master regulator of cartilage development, controls the cell fate decision to differentiate from mesenchymal to chondrogenic cells. In addition, Sox9 regulates the proliferation and differentiation of chondrocytes, as well as the production of cartilage-specific proteoglycans. The existence of Sox9-independent mechanisms in cartilage development remains to be determined. Here, we attempted to identify genes involved in such putative mechanisms via microarray analysis using a mouse chondrogenic cell line, N1511. We first focused on transcription factors that exhibited upregulated expression following Bmp2 treatment, which was not altered by subsequent treatment with Sox9 siRNA. Among these, we selected positive regulators for chondrogenesis and identified Iroquois-related homeobox 3 (Irx3) as one of the candidate genes. Irx3 expression gradually increased with chondrocyte terminal differentiation in a reciprocal manner to Sox9 expression, and promoted the chondrogenic differentiation of mesenchymal cells upon Bmp2 treatment. Furthermore, Irx3 partially rescued impaired chondrogenesis by upregulating the expression of epiphycan and lumican under reduced Sox9 expression. Finally, Irx3 was shown to act in concert with Bmp2 signaling to activate the p38 MAPK pathway, which in turn stimulated Sox9 expression, as well as the expression of epiphycan and lumican in a Sox9-independent manner. These results indicate that Irx3 represents a novel chondrogenic factor of mesenchymal cells, acts synergistically with Bmp2-mediated signaling, and regulates chondrogenesis independent of the transcriptional machinery associated with Sox9-mediated regulation.

Magnetic Targeted Delivery of Induced Pluripotent Stem Cells Promotes Articular Cartilage Repair.

Cartilage regeneration treatments using stem cells are associated with problems due to the cell source and the difficulty of delivering the cells to the cartilage defect. We consider labeled induced pluripotent stem (iPS) cells to be an ideal source of cells for tissue regeneration, and if iPS cells could be delivered only into cartilage defects, it would be possible to repair articular cartilage. Consequently, we investigated the effect of magnetically labeled iPS (m-iPS) cells delivered into an osteochondral defect by magnetic field on the repair of articular cartilage. iPS cells were labeled magnetically and assessed for maintenance of pluripotency by their ability to form embryoid bodies in vitro and to form teratomas when injected subcutaneously into nude rats. These cells were delivered specifically into cartilage defects in nude rats using a magnetic field. The samples were graded according to the histologic grading score for cartilage regeneration. m-iPS cells differentiated into three embryonic germ layers and formed teratomas in the subcutaneous tissue. The histologic grading score was significantly better in the treatment group compared to the control group. m-iPS cells maintained pluripotency, and the magnetic delivery system proved useful and safe for cartilage repair using iPS cells.

Transplantation of Scaffold-Free Cartilage-Like Cell-Sheets Made from Human Bone Marrow Mesenchymal Stem Cells for Cartilage Repair: A Preclinical Study.

OBJECTIVE: The object of this study was to determine culture conditions that create stable scaffold-free cartilage-like cell-sheets from human bone marrow-derived mesenchymal stem cells (hBMSCs) and to assess their effects after transplantation into osteochondral defects in nude rats. DESIGN: (Experiment 1) The hBMSCs were harvested from 3 males, the proliferative and chondrogenic capacities were assessed at passage 1, and the cells were expanded in 3 different culture conditions: (1) 5% fetal bovine serum (FBS), (2) 10% FBS, and (3) 5% FBS with fibroblast growth factor 2 (FGF-2). The cells were harvested and made chondrogenic pellet culture. The cell proliferation rate, glycosaminoglycan/DNA ratio, and safranin-O staining intensity of pellets cultured condition 3 were higher than those of conditions 1 and 2. (Experiment 2) The hBMSCs were expanded and passaged 3 times under culture condition 3, and fabricate the cell-sheets in chondrogenic medium either with or without FBS. The cell-sheets fabricated with FBS maintained their size with flat edges. (Experiment 3) The cell-sheets were transplanted into osteochondral defects in nude rats. Histological analysis was performed at 2, 4, and 12 weeks after surgery. RESULTS: The osteochondral repair was better after sheet transplantation than in the control group and significantly improved Wakitani score. Immunostaining with human-specific vimentin antibody showed that the transplanted cells became fewer and disappeared at 12 weeks. CONCLUSIONS: These results indicate that culture with FGF-2 may help to quickly generate sufficient numbers of cells to create stable and reliable scaffold-free cartilage-like cell-sheets, which contribute to the regeneration of osteochondral defects.

Articular cartilage endurance and resistance to osteoarthritic changes require transcription factor Erg.

OBJECTIVE: To determine whether and how the transcription factor Erg participates in the genesis, establishment, and maintenance of articular cartilage. METHODS: Floxed Erg mice were mated with Gdf5-Cre mice to generate conditional mutants lacking Erg in their joints. Joints of mutant and control mice were subjected to morphologic and molecular characterization and also to experimental surgically induced osteoarthritis (OA). Gene expression, promoter reporter assays, and gain- and loss-of-function in vitro tests were used to characterize molecular mechanisms of Erg action. RESULTS: Conditional Erg ablation did not elicit obvious changes in limb joint development and overall phenotype in juvenile mice. However, as mice aged, joints of mutant mice degenerated spontaneously and exhibited clear OA-like phenotypic defects. Joints in juvenile mutant mice were more sensitive to surgically induced OA and became defective sooner than operated joints in control mice. Global gene expression data and other studies identified parathyroid hormone-related protein (PTHrP) and lubricin as possible downstream effectors and mediators of Erg action in articular chondrocytes. Reporter assays using control and mutated promoter-enhancer constructs indicated that Erg acted on Ets DNA binding sites to stimulate PTHrP expression. Erg was up-regulated in severely affected areas in human OA articular cartilage but remained barely appreciable in areas of less affected cartilage. CONCLUSION: The study shows for the first time that Erg is a critical molecular regulator of the endurance of articular cartilage during postnatal life and that Erg can mitigate spontaneous and experimental OA. Erg appears to do this through regulating expression of PTHrP and lubricin, factors known for their protective roles in joints.

Effect of the direct injection of bone marrow mesenchymal stem cells in hyaluronic acid and bone marrow stimulation to treat chondral defects in the canine model.

INTRODUCTION: The purpose of this study was to assess the direct injection of bone marrow-derived mesenchymal stem cells (BMSCs) suspended in hyaluronic acid (HA) combined with drilling as a treatment for chondral defects in a canine model. METHODS: Tibial bone marrow was aspirated, and BMSCs were isolated and cultured. One 8.0-mm diameter chondral defect was created in the femoral groove, and nine 0.9-mm diameter holes were drilled into the defect. BMSCs (2.14 × 107 cells) suspended in HA were injected into the defect. HA alone was injected into a similar defect on the contralateral knee as a control. Animals were sacrificed at 3 and 6 months. RESULTS: Although the percentage of coverage assessed macroscopically was significantly better at 6 months than at 3 months in both the BMSC (p = 0.02) and control (p = 0.001) groups, there were no significant differences in the International Cartilage Repair Society grades. The Wakitani histological score was significantly better at 6 months than at 3 months in the BMSC and control groups. While the control defects were mostly filled with fibrocartilage, several of the defects in the BMSC group contained hyaline-like cartilage. The mean Wakitani scores of the BMSC group improved from 7.0 ± 1.0 at 3 months to 4.6 ± 0.9 at 6 months, and those of the control group improved from 9.4 ± 1.2 to 6.0 ± 0.6. The BMSC group showed significantly better regeneration than the control group at 3 months (p = 0.04), but the difference at 6 months was not significant (p = 0.06). CONCLUSIONS: The direct injection of BMSCs in HA combined with drilling enhanced cartilage regeneration.

The limited effects of anti-tumor necrosis factor blockade on bone health in patients with rheumatoid arthritis under the use of glucocorticoid.

We investigated the effects of biologics for rheumatoid arthritis (RA) patients on bone mineral density (BMD) and bone metabolic markers (BMM), retrospectively, and also clarified the effects of bisphosphonates (alendronate or risedronate 35 mg/week) and glucocorticoids. Participants in this study comprised 219 patients with RA, including 117 patients treated with biologics (infliximab, n = 90; etanercept, n = 27) and 102 patients with conventional disease-modifying anti-rheumatic drugs (DMARDs) for 1 year. Changes in BMD at the lumbar spine and total hip and BMMs [urinary type I collagen cross-linked N-telopeptide (NTX) and bone-specific alkaline phosphatase] were measured. BMD of the lumbar spine in both groups and total hip BMD in the biologics group were unchanged during treatment with biologics. However, BMD of the total hip was significantly decreased in the DMARDs group (from 0.731 ± 0.135 to 0.706 ± 0.135 g/cm2). Patients receiving glucocorticoids without bisphosphonates showed significant decrease in BMD of the total hip compared with patients not receiving glucocorticoids or receiving glucocorticoids with bisphosphonates in both biologics and DMARDs groups. Furthermore, BMD of the lumbar spine increased (p < 0.05) for patients in the biologics group who received bisphosphonates. NTX was significantly decreased only in the biologics group. Multiple regression analysis showed that BMD and bone metabolic marker levels correlated positively with bisphosphonate and biologics use and negatively with glucocorticoid use. BMD of the total hip was maintained in the patients using biologics without glucocorticoids or with bisphosphonates, but it was not maintained in the DMARDs patients, even without glucocorticoids or with bisphosphonates. Even if biologics have protective effect against bone loss of RA patients, we should consider reducing the dose of glucocorticoids and adding bisphosphonates for the treatment of osteoporosis.

Nucleated cells circulating in the peripheral blood contribute to the repair of osteochondral defects only in the early phase of healing.

The role of cells circulating in the peripheral blood to participate in the natural repair process of osteochondral defects was evaluated in a green fluorescent protein (GFP) transgenic and wild rat parabiosis model. Two weeks after the parabiosis operation, vascular communication between the conjoined rats was confirmed by flow-cytometry analysis. A 1.5 mm diameter and 1.0 mm depth osteochondral defect was made in the patellar groove of each rat femoral bone. Histological examination was performed at 1, 2, 4 and 24 weeks following surgery. In the early postoperative phase (1-4 weeks) there were GFP-negative and -positive cells in the defects of both parabiotic rats. GFP-positive chondrocytes were confirmed partly in the repair tissue of the wild parabiotic rat. In the late postoperative phase (24 weeks), the repaired defects were occupied by cells originating from the adjacent tissue and not from the peripheral blood. The ratio of cells originating from the peripheral blood was approximately 30-40% in the repair tissue at 1 week after surgery, reduced to 0-7% at 24 weeks. From these results it is confirmed that cells circulating in the peripheral blood contributed to the repair of the osteochondral defects, particularly in the early phase of healing. Thus, peripheral blood not only supplies the factors needed for repair but also provides a cell population involved in the wound-healing process.

Systemic Administration of Granulocyte Colony-Stimulating Factor for Osteochondral Defect Repair in a Rat Experimental Model.

OBJECTIVE: The objective of this study was to assess the effect of granulocyte colony-stimulating factor (G-CSF) on osteochondral defect repair in the rat knee. DESIGN: Twenty-six 12-week-old male Lewis rats were randomly divided into 2 groups. From day 0 to day 4, the G-CSF group received glycosylated G-CSF, and the control group received phosphate-buffered saline. A 1.5-mm diameter and 1.0-mm deep osteochondral defect was introduced in the patellar groove of the bilateral femur in all rats on day 4. The peripheral blood nucleated cells were counted for 14 days from the first day of injection, the appearance of the cartilage repair was observed histologically and macroscopically for 2, 4, 8, 12, and 24 weeks after surgery. RESULTS: The number of peripheral blood leukocytes increased 3 days and returned to normal levels 7 days after the first injection. Compared with the control group, the G-CSF group had more fibrous and/or bony tissue at earlier points in time. The tissue repair rate, which is defined as the percentage of repaired osteochondral defects, was significantly higher in the G-CSF group 4 weeks after surgery. However, there were no significant differences in the cartilage repair rate and the modified Wakitani score between the 2 groups at each time point. CONCLUSIONS: The defect filling was significantly better in the G-CSF group in the early phases. Our findings suggest that G-CSF may promote the repair of osteochondral defects by mediating an increase in the number of peripheral blood nucleated cells.

Cartilage Repair With Autologous Bone Marrow Mesenchymal Stem Cell Transplantation: Review of Preclinical and Clinical Studies.

Clinical trials of various procedures, including bone marrow stimulation, mosaicplasty, and autologous chondrocyte implantation, have been explored to treat articular cartilage defects. However, all of them have some demerits. We focused on autologous culture-expanded bone marrow mesenchymal stem cells (BMSC), which can proliferate without losing their capacity for differentiation. First, we transplanted BMSC into the defective articular cartilage of rabbit and succeeded in regenerating osteochondral tissue. We then applied this transplantation in humans. Our previous reports showed that treatment with BMSC relieves the clinical symptoms of chondral defects in the knee and elbow joint. We investigated the efficacy of BMSC for osteoarthritic knee treated with high tibial osteotomy, by comparing 12 BMSC-transplanted patients with 12 cell-free patients. At 16-month follow-up, although the difference in clinical improvement between both groups was not significant, the arthroscopic and histological grading score was better in the cell-transplanted group. At the over 10-year follow-up, Hospital for Special Surgery knee scores improved to 76 and 73 in the BMSC-transplanted and cell-free groups, respectively, which were better than preoperative scores. Additionally, neither tumors nor infections were observed in all patients, and in the clinical study, we have never observed hypertrophy of repaired tissue, thereby guaranteeing the clinical safety of this therapy. Although we have never observed calcification above the tidemark in rabbit model and human histologically, the repair cartilage was not completely hyaline cartilage. To elucidate the optimum conditions for cell therapy, other stem cells, culture conditions, growth factors, and gene transfection methods should be explored.

[Cartilage repair and regenerative medicine ; past, present, and future].

Since the days of ancient Greece, it has been known that articular cartilage has poor potential to repair. In April, 2013, autologous chondrocyte implantation (ACI) was approved by the Japanese ministry of Health, Labour and Welfare, as the first orthopedic cell therapy in Japan. Half a century has passed since Chesterman's report on rabbit allogeneic chondrocyte implantation, and approximately 20 years since the first human ACI report by Brittberg. In Japan, 24 years has passed since Wakitani's allogeneic chondrocyte implantation, and over 10 years since the human ACI report by Ochi. A long-term follow-up clinical trial with the high statistical power is needed to verify the safety and efficacy of new cartilage joint therapy. Moreover, we need the infrastructure, including drug and/or device regulation and timely approved by the government, to apply new therapies in similar time frames to other developed nations.

Xeno-free and shrinkage-free preparation of scaffold-free cartilage-like disc-shaped cell sheet using human bone marrow mesenchymal stem cells.

Aiming for the clinical application of cartilage regeneration, the xeno-free cultivation method to obtain a scaffold-free cartilage-like disc-shaped cell sheet using mesenchymal stem cells (MSCs) derived from human bone marrow without the shrinkage of the sheet was investigated. MSCs were inoculated into Cell Culture Insert (0.3 cm(2), pore size; 0.4 µm, pore density; 1.0 × 10(8)/cm(2)) using serum-free chondrogenic differentiation medium containing TGF-ß3, IGF-1 and dexamethasone or other modified media, and cultured at 37 °C in 5% CO2 for 3 weeks. Sheet thickness, cartilage specific genes expression, ECM accumulation were determined, and the sections of sheets were stained with alcian blue. A novel mixed medium consisting of a growth medium (10% FCS) with a serum-free chondrogenic differentiation medium could prevent the shrinkage of the sheet and produced a disc-shaped cell sheet. The depth of the sheet was approximately 0.7 mm and the gene expression levels were higher than those in cells in normal human cartilage. The use of human serum instead of FCS did not cause shrinkage and did not decrease the accumulation levels of sGAG and type 2 collagen in the sheet. The cultivation of MSCs grown with completely xeno-free materials using the mixed medium containing human serum in a cell culture insert showed a sheet depth of 1.0 mm and gene expression levels higher than those in normal cartilage. The scaffold-free and xeno-free cartilage-like cell sheet was successfully formed without shrinkage using human bone marrow MSCs and the chondrogenic differentiation medium containing human serum.

Construction of an osteochondral-like tissue graft combining ß-tricalcium phosphate block and scaffold-free mesenchymal stem cell sheet.

BACKGROUND: Aiming to construct an osteochondral-like structure, the combination of a ß-tricalcium phosphate (ßTCP) block with a scaffold-free sheet formed using mesenchymal stem cells (MSCs) was investigated. METHODS: Human bone marrow MSCs in a cell culture insert that was set in a 24-well plate were cultivated using a chondrogenic medium containing dexamethasone, IGF-1, and TGFß3 for 3 weeks during which a cylindrical ßTCP block was put on the sheet at day 1, and the cell sheet construct was harvested. In other experiments, at day 14, the construct was put on a cell sheet that was prepared the day before and cultivated for 3 weeks. RESULTS: The addition of a ßTCP block resulted in a combined osteochondral-like construct and comparable staining intensity by Alcian blue, while the expression levels of the aggrecan and type II collagen genes decreased a little. During the culture with the ßTCP block, the expression levels of the aggrecan gene increased monotonically. The increase in the inoculum cell number from 1.86 to 3.72 × 10(6) cells resulted in marked increases in the thickness of cell sheet parts in the ßTCP block and expression levels of the aggrecan and type II collagen genes, while the thickness of cell sheet parts on the ßTCP block scarcely changed. On the other hand, the addition of a cell sheet that was prepared a day before to the construct at day 14 resulted in the marked increase in thickness of the cell sheet part on the ßTCP block, while the thickness of that in the ßTCP block did not increase. CONCLUSION: A combined osteochondral-like structure was produced by putting a ßTCP block on the sheet of MSC. The thickness of the cell sheet parts in and on the ßTCP block could be increased by the increase in inoculum cell number and by providing an additional cell sheet, respectively.

Comparison of joint destruction between standard- and low-dose etanercept in rheumatoid arthritis from the Prevention of Cartilage Destruction by Etanercept (PRECEPT) study.

OBJECTIVE: To evaluate the prevention of joint destruction and clinical efficacy of low-dose etanercept (ETN) (25 mg/week) compared with standard-dose ETN (50 mg/week) in RA. METHODS: In this prospective, randomized, open-label study, 70 patients were assigned to receive ETN at either 50 or 25 mg/week for 52 weeks. The primary endpoint was the variation in modified total Sharp score (mTSS), and secondary endpoints were variations in disease activity score in 28 joints (DAS-28), modified HAQ and adverse event rate. Values of mTSS were calculated at baseline and after 52 weeks. Non-progression was estimated as ΔmTSS ≤0.5, and the non-progression rate was compared between groups. RESULTS: Mean values at baseline were as follows: disease duration 9.2 years; DAS-28 5.45; and annual progression of mTSS 26.1. No significant differences in background were seen between groups. At 52 weeks, the non-progression rate was significantly less in the 25 mg/week group (36.7%) than in the 50 mg/week group (67.7%) (P = 0.041). Mean ΔmTSS was higher at 25 mg/week (1.03) than at 50 mg/week (-0.13). DAS-28 was significantly improved at 4 weeks, and the effect of treatment lasted for 52 weeks in both groups. No differences in adverse event rates were seen between groups. CONCLUSION: Low-dose ETN is not inferior to standard-dose ETN in terms of effects on clinical manifestations. However, in terms of the radiographic non-progression rate, the effects of low-dose ETN may be inferior to the effects of standard-dose ETN. TRIAL REGISTRATION: UMIN Clinical Trials Registry, http://www.umin.ac.jp/ctr/, UMIN000001798.

Regenerative repair of bone defects with osteoinductive hydroxyapatite fabricated to match the defect and implanted with combined use of computer-aided design, computer-aided manufacturing, and computer-assisted surgery systems: a feasibility study in a canine model.

BACKGROUND: Currently, regenerative repair of large bone defects that result from bone tumor resection or severe trauma is a challenging issue because of the limited regenerative potential of bone and treatment modalities. The aim of this study was to achieve repair of large bone defects to the original three-dimensional (3D) anatomical state by combining computer-aided technologies and local delivery of bone morphogenetic protein (BMP) in a canine model. METHODS: Computed tomography (CT) images of the pelvic bone of each dog were obtained, and an imaginary spherical malignant bone tumor of 15-mm diameter was placed in the left ilium of a canine on the 3D CT image. Resection of the whole tumor with a 10-mm margin of healthy bone was planned preoperatively by using computer-aided design (CAD) software. In addition, an image of the implant to be used to fill the resulting bone defect was constructed on the computer image. A porous hydroxyapatite (HA) implant identical to the imaged bone defect was made by shaving a tetragonal porous apatite block (40 × 20 × 10 mm) with a computer-aided manufacturing system operated by using the CT-image data of the bone defect obtained from the CAD system. To resect the iliac bone as planned preoperatively on the 3D CT image, computer-aided surgery was performed using the CT data. The defect was filled with the HA implant fabricated as described and coated with a putty carrier either with BMP-2 (BMP group, n = 6) or without BMP-2 (control group, n = 6). RESULTS: In the BMP group, new bone formation was noted around each implant on CT images at 3 weeks after surgery and was remodeled to restore the original anatomy of the ilium on serial CT images. At 12 weeks, the implant was enclosed within new bone, and histological analysis revealed bone formation on and within the implant. Little bone formation was noted in the control group. CONCLUSIONS: This new method may enable efficacious and precise regenerative repair of large bone defects without bone grafting.