Marcus Egermann

Calcification or dedifferentiation: Requirement to lock mesenchymal stem cells in a desired differentiation stage†

A current challenge in mesenchymal stem cell (MSC)‐based cartilage repair is to solve donor and tissue‐dependent variability of MSC cultures and to prevent chondrogenic cells from terminal differentiation like in the growth plate. The aim of this study was to select the best source for MSC which could promise stable cartilage formation in the absence of hypertrophy and ectopic in vivo mineralization. We hypothesized that MSC from synovium are superior to bone marrow‐ and adipose tissue‐derived MSC since they are derived from a joint tissue. MSC were characterized by flow cytometry. MSC pellets were cultured under chondrogenic conditions and differentiation was evaluated by histology, gene expression analysis, and determination of alkaline phosphatase activity (ALP). After chondrogenic induction, pellets were transplanted subcutaneously into SCID mice. MSC from bone marrow, adipose tissue, and synovium revealed similar COL2A1/COL10A1 mRNA levels after chondrogenic induction and were positive for collagen‐type‐X. Bone marrow‐derived and adipose tissue‐derived MSC showed significantly higher ALP activity than MSC from synovium. Low ALP‐activity before transplantation of pellets correlated with marginal calcification of explants. Surprisingly, non‐mineralizing transplants specifically lost their collagen‐type II, but not collagen‐type I deposition in vivo, or were fully degraded. In conclusion, the lower donor‐dependent ALP activation and reduced mineralization of synovium‐derived heterotopic transplants did not lead to stable ectopic cartilage as known from articular chondrocytes, but correlated with fibrous dedifferentation or complete degeneration of MSC pellets. This emphasizes that beside appropriate induction of differentiation, locking of MSC in the desired differentiation state is a major challenge for MSC‐based repair strategies. J. Cell. Physiol. 219: 219–226, 2009.

Delayed administration of adenoviral BMP-2 vector improves the formation of bone in osseous defects

The direct, local, administration of adenovirus carrying human BMP-2 cDNA (Ad.BMP-2) heals critical-sized femoral bone defects in rabbit and rat models. However, the outcome is suboptimal and the technology needs to provide a more reliable and uniform outcome. To this end, we investigated whether the timing of Ad.BMP-2 administration influenced the formation of mineralized tissue within the defect. Critical-sized defects were created in the femora of 28 Sprague–Dawley rats. Animals were injected intralesionally with a single, percutaneous injection of Ad.BMP-2 (4 × 108 plaque-forming units) either intraoperatively (day 0) or 24 h (day 1), 5 days or 10 days after surgery. The femora were evaluated 8 weeks after surgery by X-ray, microcomputed tomography, dual-energy X-ray absorptiometry and biomechanical testing. The incidence of radiological union was markedly increased when administration of Ad.BMP-2 was delayed until days 5 and 10, at which point 86% of the defects healed. These time points also provided greater bone mineral content within the defect site and improved the average mechanical strength of the healed bone. Thus, delaying the injection of Ad.BMP-2 until 5 or 10 days after surgery enables a greater percentage of critical-sized, segmental defects to achieve radiological union, producing a repair tissue with enhanced mineralization and greater mechanical strength.

Effect of BMP-2 gene transfer on bone healing in sheep

Critical size defects of bone and delayed fracture healing due to metabolic disorders are still problems in orthopaedic surgery. Adenoviral vectors encoding bone morphogenetic protein-2 (Ad.BMP-2) have been used to stimulate bone formation in small animals. The present study evaluated the use of direct adenoviral gene transfer for inducing bone formation in a large animal. Standardized iliac crest defects were created surgically on both sides of the pelvic bone of white mountain sheep. The efficiency of gene transfer was evaluated using recombinant adenoviruses carrying the cDNA for luciferase. High levels of transgene expression, restricted to the site of injection, were found for the 1st week. Transgene expression then fell considerably, but could still be detected for up to 5 weeks. To investigate the effect on bone healing, Ad.BMP-2 (1011 particles in 200 μl saline) was unilaterally injected into iliac crest defects and into tibial osteotomies. The contralateral defects remained untreated to evaluate possible systemic effects. The controls were treated with saline solution. Bone formation within the defect, assessed by micro-computed tomography (CT) measurement at 8 weeks, and callus formation after osteotomy were significantly reduced following direct application of Ad.BMP-2. The retardation compared to untreated control animals was additionally found at the contralateral iliac crest indicating a systemic inhibitory effect. Histological analysis confirmed the CT measurement and showed an increased number of inflammatory cells within both defects. Antibodies against the adenovirus and the transgene product were detected in all treated animals. These data show a systemic retardation of bone formation following a single local injection of Ad.BMP-2 in sheep. This finding stands in contrast to the data obtained from small animal models. Further studies are needed to determine the contribution of the immune response to these results, and whether a lower dose of Ad.BMP-2 would be advantageous.

Leptin Inhibits Bone Formation Not Only in Rodents, but Also in Sheep

This study examines the effect of long‐term ICV administration of leptin in ewes. We found that central application significantly decreased osteoblast activity as measured by serum analysis as well as by histomorphometry, resulting in decreased trabecular bone volume. These data provide additional evidence that bone formation and therefore bone remodeling is at least in part centrally controlled.

The potential of gene therapy for fracture healing in osteoporosis

Osteoporosis-associated fractures impair a patient’s function and quality of life and represent one of the major public health burdens. Demographic changes predict a dramatic increase in osteoporotic fractures. Experimental data have shown that osteoporosis impairs fracture healing. Clinical observations demonstrate high failure rates of implant fixation in osteoporosis. The reduced healing capacity, including impaired bone formation, in osteoporotic humans might be due to defects in mesenchymal stem cells that lead to reduced proliferation and osteoblastic differentiation. Growth factors show remarkable promise as agents that can improve the healing of bone or increase the proliferation and differentiation capacities of mesenchymal stem cells. Their clinical utility is limited by delivery problems. The attraction of gene-transfer approaches is the unique ability to deliver authentically processed gene products to precise anatomical locations at therapeutic levels for sustained periods of time. Unlike the treatment of chronic diseases, it is neither necessary nor desirable for transgene expression to persist beyond the few weeks or months needed to achieve healing. This review presents different approaches of gene therapy to enhance fracture healing and summarizes the promising results of preclinical studies. It focuses on applications of this new technique to fracture healing in osteoporosis. In our opinion, these applications represent some of the few examples in which gene therapy has a good chance of early clinical success.

The long-term effects of ovariectomy on bone metabolism in sheep

Osteoporosis and associated fractures are major public health concerns, and as such require appropriate large animal models to further our understanding of this disease. Although sheep appear to be an ideal model with which to study bone loss caused by estrogen depletion, limited data are available concerning the long-term effect of ovariectomy on bone in sheep. The goal of the present study was to observe the ovariectomy-induced changes in bone mass, structure, and metabolism in sheep over a period of 18 months. Six ewes were ovariectomized (OVX) and compared to an age-matched control group by analyzing bone mineral density, trabecular structure, biochemical markers of bone formation and resorption, and plasma estrogen levels. Bone loss (13%, P < 0.01) occurred during the first 4 months after surgery, then stabilized and returned to pre-OVX levels for the remainder of the study. Trabecular architecture was also altered and tended toward osteopenia with recovery to baseline values. Markers of bone formation and resorption were elevated up to 6 months postovariectomy, after which time levels returned to baseline values. Although estradiol measurements demonstrated a clear decline following surgical ovariectomy, levels returned to normal after 6 months. Therefore, the detrimental effect of ovariectomy on sheep bone metabolism seems to be reversible, with normal bone parameters being reestablished within 6 months after surgery. These data seem to indicate that the sheep is not an appropriate model for human postmenopausal osteoporosis.

A sheep model for fracture treatment in osteoporosis: benefits of the model versus animal welfare

Summary Animal models are necessary to evaluate new options for the treatment of fractures in osteoporotic bone. They permit both the biological response of a living system and the influence of the pathological processes to be taken into account. A sheep model for osteoporosis was established by combining oestrogen deficiency, calcium and vitamin D-deficient diet with steroid medication. Bone mineral density (BMD) was reduced by >30% after 12 weeks of combined treatment. Osteoporosis similar to the human situation with corresponding changes in the micro-architecture and mechanical properties of bone was observed. This publication focuses on the impressive results obtained with the model and contrasts them with considerations of animal welfare. Considerable side-effects associated with steroid medication became manifest. Animals in the treatment groups showed signs of infection of various degrees due to the immunosuppressive effect of the medication. The infections were mostly caused by Corynebacterium pseudotuberculosis. Antibody testing revealed a 100% prevalence of infection in this breed of sheep. A modification of the steroid treatment, i.e. less-frequent injections, reduced the incidence of side-effects. This sheep model shows a significant and reproducible reduction in cancellous BMD of >30%, including relevant changes in biomechanical properties and increased fracture risk. However, the severity of the side-effects cannot be overlooked. The model must be improved if it is to be used in the future. Options to reduce the side-effects are discussed.

Core decompression and autologous bone marrow concentrate for treatment of femoral head osteonecrosis: a randomized prospective study

The aim of this study was to investigate the safety of injection of bone marrow aspirate concentrate during core decompression and to study its clinical (visual analogue scale; Harris-Hip-score) and radiological outcomes (magnetic resonance imaging). In this prospective and randomized clinical trial we evaluated 24 consecutive patients with non-traumatic femoral head necrosis (FHN) during a period of two years after intervention. In vitro analysis of mesenchymal stem cells was performed by evaluating the fibroblast colony forming units (CFU-Fs). Postoperatively, significant decrease in pain associated with a functional benefit lasting was observed. However, there was no difference in the clinical outcome between the two study groups. Over the period of two years there was no significant difference between the head survival rate between both groups. In contrast to that, we could not perceive any significant change in the volume of FHN in both treatment groups related to the longitudinal course after treating. The number of CFU showed a significant increase after centrifugation. This trial could not detect a benefit from the additional injection of bone marrow concentrate with regard to bone regeneration and clinical outcome in the short term.

The collagen component of biological bone graft substitutes promotes ectopic bone formation by human mesenchymal stem cells

Synthetic bone substitutes are attractive materials for repairing a variety of bone defects. They are readily available in unlimited quantities, have a defined composition without batch variability and bear no risk of disease transmission. When combined with mesenchymal stem cells (MSCs), bone healing can be further enhanced due to the osteogenic potential of these cells. However, human MSCs showed considerable donor variability in ectopic bone formation assays on synthetic bone substitutes, which may limit clinical success. This study addresses whether bone formation variability of MSCs is cell-intrinsic or biomaterial-dependent and may be improved using biological bone substitutes with and without collagen. Ectopic bone formation of MSCs from nine donors was tested in immune-deficient mice on biological bone substitutes of bovine and equine origin, containing collagen (bHA-C; eHA-C) or not (bHA; eHA). Synthetic β-TCP was used for comparison. Histology of 8-week explants demonstrated a significant influence of the bone graft substitute (BGS) on donor variability of ectopic bone formation with best results seen for eHA-C (15/17) and β-TCP (16/18). Bone was of human origin in all groups according to species-specific in situ hybridization, but MSCs from one donor formed no bone with any bone substitute. According to histomorphometry, most neo-bone was formed on eHA-C with significant differences to bHA, eHA and β-TCP (p<0.001). Collagen-free biological BGSs were inferior to biological BGSs with collagen (p<0.001), while species-origin was of little influence. In conclusion, BGS composition had a strong influence on ectopic bone formation ability of MSCs, and biological BGSs with a collagen component seem most promising to display the strong osteogenic potential of MSCs.

Interobserver Reliability of Radiographic Measurements of Contralateral Feet of Pediatric Patients with Unilateral Clubfoot

BACKGROUND Radiographs have traditionally been used to describe and quantify foot deformities in infants and children. We hypothesized that the interobserver reliability of measurements obtained from radiographs of pediatric feet would be low, especially with regard to the infant foot, and that normal ranges and standard deviations would decrease in association with increasing patient age. METHODS We retrospectively reviewed 494 radiographs of 121 patients treated for unilateral clubfoot at our institution and studied the contralateral normal foot. All anteroposterior radiographs, lateral radiographs, and lateral radiographs made with the foot in maximum dorsiflexion were analyzed by three observers, and the values were recorded. The databases created by the three observers were statistically analyzed according to five predefined age groups (birth to less than three months, three months to less than twelve months, twelve months to less than three years, three years to less than seven years, and seven years to less than fourteen years). RESULTS The anteroposterior talocalcaneal angle was rated as having good interobserver reliability (i.e., an intraclass correlation coefficient of 0.61 to 0.80) for all patients in each age group. Other angles that were associated with good interobserver reliability were the anteroposterior calcaneus-fifth metatarsal angle in the twelve months to less than three-year age group, the three-year to less than seven-year age group, and the seven-year to less than fourteen-year age group; the lateral talocalcaneal angle in the three-year to less than seven-year age group; the lateral tibiotalar angle in the three-year to less than seven-year age group; and the lateral talus-first metatarsal angle in the seven-year to less than fourteen-year age group. All other angles were rated as having very good interobserver reliability (i.e., an intraclass correlation coefficient of 0.81 to 1). The mean difference and the maximum difference among the observers decreased for all angles in nearly all age groups. CONCLUSIONS Interobserver reliability with regard to the radiographic measurement of pediatric feet was higher than expected, although measurement discrepancies can be as great as 30° with the infant foot. Interobserver reliability tended to improve with increasing patient age. The standard deviation showed a trend toward a decrease as patient age increased, although the trend was less notable than expected.