A critical bone defect may be more frequently the consequence of a trauma, especially when a fracture occurs with wide exposure, but also of an infection, of a neoplasm or congenital deformities. This defect needs to be treated in order to restore the limb function. The treatments most commonly performed are represented by implantation of autologous or homologous bone, vascularized fibular grafting with autologous or use of external fixators; all these treatments are characterized by several limitations.

Nowadays bone tissue engineering is looking forward new solutions: magnetic scaffolds have recently attracted significant attention. These scaffolds can improve bone formation by acting as a “fixed station” able to accumulate/release targeted growth factors and other soluble mediators in the defect area under the influence of an external magnetic field. Further, magnetic scaffolds are envisaged to improve implant fixation when compared to not-magnetic implants.

We performed a series of experimental studies to evaluate bone regeneration in rabbit femoral condyle defect by implanting hydroxyapatite (HA), polycaprolactone (PCL) and collagen/HA hybrid scaffolds in combination with permanent magnets.

Our results showed that ostetoconductive properties of the scaffolds are well preserved despite the presence of a magnetic component. Interestingly, we noticed that, using bio-resorbable collagen/HA magnetic scaffolds, under the effect of the static magnetic field generated by the permanent magnet, the reorganization of the magnetized collagen fibers produces a highly-peculiar bone pattern, with highly-interconnected trabeculae orthogonally oriented with respect to the magnetic field lines. Only partial healing of the defect was seen within the not magnetic control groups.

Magnetic scaffolds developed open new perspectives on the possibility to exploiting magnetic forces to improve implant fixation, stimulate bone formation and control the bone morphology of regenerated bone by synergically combining static magnetic fields and magnetized biomaterials. Moreover magnetic forces can be exploited to guide targeted drug delivery of growth factors functionalized with nanoparticles.

TRIM32 is a candidate gene at the 9q33.1 genetic susceptibility locus for hip osteoarthritis (OA). Increased cartilage degradation typical of OA has previously been demonstrated in Trim32 knockout mice.

Our aim is to investigate the role of TRIM32 in human and murine articular tissue.

TRIM32 expression in human articular cartilage was examined by immunostaining. TRIM32 expression was compared in femoral head chondrocytes from patients with and without primary hip OA (n=6/group) and examined by Western blotting. Aggrecanolysis by femoral head explants from Trim32 knockout (T32KO) and wild-type (WT) mice was compared following stimulation with IL1α or retinoic acid (RA) and was assessed by DMMB assay (n=4/group). Expression of chondrocyte phenotype markers was measured by qPCR and compared between articular chondrocytes from WT and T32KO mice following catabolic (IL1α/TNFα) or anabolic (Oncostatin-M (OSM)/IGF1) stimulation.

TRIM32 expression was demonstrated in human articular cartilage; TRIM32 expression by chondrocytes was reduced in patients with hip OA (p=0.03). Greater aggrecanolysis occurred in cartilage explants from T32KO mice after treatment with no stimulation (p=0.03), IL1α (p=0.02), and RA (p=0.001). Unstimulated T32KO chondrocytes expressed reduced Col2a1 (p=8.53×10⁻⁵), and Sox9 (p=2.35×10⁻⁶). Upon IL1α treatment, T32KO chondrocytes expressed increased Col10a1 (p=0.0003). Upon anabolic stimulation, T32KO chondrocytes expressed increased Col2a1 (OSM: p=0.001; IGF: p=0.001), and reduced Sox9 (OSM: p=0.0002; IGF: p=0.0006).

These results indicate that altered TRIM32 expression in human articular tissue is associated with OA, and that Trim32 knockout results in increased cartilage degradation in murine femoral head explants. Predisposition to cartilage degeneration with reduced Trim32 expression may involve increased chondrocyte hypertrophy upon catabolic cytokine stimulation and dysregulation of Col2a1 and Sox9 expression upon anabolic stimulation.

The cartilage diseases such as osteoarthritis and chondral injuries are considered irreversible and the result of recent treatments remains not optimal. One of the reasons is due to the poor understanding of chondrocyte behaviours. To understand more about cartilage, we designed a series of novel experiments. First, a total joint of bovine metatarsophalanges was isolated as our novel model. We chose it because the configuration and the healing potential were similar to human, and many variables of large animal studies could be controlled in laboratory. The model not only provided a good ex vivo platform for cartilage researches but also connected in vitro cellular studies and in vivo animal studies. To mimic joint movement a special driving machine was designed. To characterise the novel model viabilities of chondrocytes and contents of sulphated glycosaminoglycan (GAGs) in extracellular matrixes were measured every seven days. The preliminary results revealed the viabilities of chondrocytes remained above 80% alive in the middle zone after four-weeks culture. The GAGs contents decreased after this culturing period. The experiments still carry on going to compare the static and dynamic models which joint movement could be a determinative factor to the viability of chondrocytes. Cellular treatment is the recent mainstream for cartilage diseases. If advanced knowledge in chondrocyte behaviours could be obtained from this model, development of optimal treatment will be possible in the future.

Background

Hyperlaxity is associated with a high incidence of sporting injuries. Collagen V regulates the diameter of fibrils of the abundant collagen type I. Decorin and biglycan are members of the small leucine rich proteoglycans(SLRP's)family and play important roles in the regulation of collagen fibrillogenesis. The aim of this study was to identify if there was a link in hyperlaxity, tissue strength, collagen V and SLRP's expression.

Background

Hyperlaxity is associated with a high incidence of shoulder dislocations. Collagen V regulates the diameter of fibrils of the abundant collagen type I. Decorin and biglycan are members of the small leucine rich proteoglycans(SLRP's)family and play important roles in the regulation of collagen fibrillogenesis. The aim of this study was to identify if there was a link in hyperlaxity, capsule strength, collagen V and SLRP's expression.

Fractures repair by two mechanisms; direct fracture healing and indirect fracture healing via callus formation. Research concerning the effects of bisphosphonate on fracture repair has solely assessed indirect fracture healing. Patients with osteoporosis on bisphosphonates continue to sustain fragility fractures. A proportion of osteoporotic fractures require plate fixation. Bisphosphonates impair osteoclast activity and therefore, may adversely affect direct fracture healing that predominates with plate fixation.

Five skeletally mature Sprague-Dawley rats received daily subcutaneous injections of 1mg/kg Ibandronate (IBAN). Similarly, five control rats received saline (CONTROL). Three weeks following commencement of injections a tibial osteotomy was rigidly fixed with compression plating similar to that seen in routine clinical practice. Fracture healing was monitored with radiographs. Six weeks post plate fixation, animals were sacrificed. Radiographs were performed of the extricated tibiae following plate removal. The visibility of the osteotomy site was scored as totally visible, partially visible or absent as previously described. Mechanical testing was conducted on the healing osteotomies via 4-point bending.

Fractures healed without visible external callus. In the IBAN group three animals had totally visible osteotomy lines and two had partially visible osteotomy lines. The CONTROL group had three animals with absent osteotomy lines and two with partially visible osteotomy lines. The mean (±SD) stress at failure for the healing tibial osteotomies at 6 weeks was 28.8 (±23.97)MPa in the IBAN group and 37.4(±29.20) MPa in the CONTROL group (p=0.62)

Our results indicate that Ibandronate adversely affected direct fracture repair as demonstrated by the radiographic density of the fracture line. The strength of the repair was reduced but this did not reach statistical significance. Our results suggest that a sample size of 220 animals is required to detect a 15% difference (alpha 0.05, beta 0.2) which suggests the effect of bisphosphonates on direct fracture repair may be small.

The stress response to trauma is the summation of the physiological response to the injury (the ‘first hit’) and by the response to any on-going physiological disturbance or subsequent trauma surgery (the ‘second hit’).

Our animal model was developed in order to allow the study of each of these components of the stress response to major trauma. High-energy, comminuted fracture of the long bones and severe soft-tissue injuries in this model resulted in a significant tropotropic (depressor) cardiovascular response, transcardiac embolism of medullary contents and activation of the coagulation system. Subsequent stabilisation of the fractures using intramedullary nails did not significantly exacerbate any of these responses.