To identify the incidence of sequential slip of the unaffected hips in patients presenting with unilateral SCFE managed with prophylactic fixation or observation.

A retrospective review of all unilateral SCFE treated during 1998 to 2012 was undertaken. The study compares the incidence of sequential slip of the initially unaffected hip in patients managed with prophylactic fixation or observation. The study also reports the incidence avascular necrosis, chondrolysis, and metal-work related problem in this group of patients. All patients included in this current work have at least 12 months of follow-up from the index slip.

A total of 44 cases had prophylactic fixation of the unaffected hip (mean age 12.6 years,) and 36 patients managed with regular observation (mean age 13.4 years). Sequential slip of the unaffected hip was noted in a total of 10 patients (28 %) managed with regular observation and only in 1 patient (2%) managed with prophylactic fixation. A Fishers exact test showed significantly high incidence of sequential slip in unaffected hips when managed by regular observation (p-value-0.002). There is no evidence of avascular necrosis or chondrolysis in the unaffected hip in both groups, 3 patients had metalwork related problem and one had superficial wound infection in prophylactic fixation group.

Simultaneous prophylactic fixation of the unaffected hips significantly reduces the incidence of sequential slip. This is a relatively safe procedure and should be advocated in all cases of unilateral SCFE to avoid potential complications and preserve function of the unaffected hip.

Introduction:

Plantar Fasciitis is an extremely common and challenging problem that presents itself to foot and ankle practitioners. Many different treatment modalities are available for this condition, with little proven benefit. ECSWT was approved for use by the FDA for the treatment of chronic proximal plantar fasciitis in 2002 and NICE published guidance in 2009 recommending its use in refractory cases.

Impaction allografting is a bone reconstruction technique currently used in lower limb revision arthroplasty. Demineralisation and addition of osteogenic protein-1 (OP-1) can improve the osteoinductivity of the allograft however recent reports indicate significant allograft resorption when it is combined with OP-1 during impaction. Our hypothesis was that hydroxyapatite (HA) and OP-1 could effectively replace demineralised allograft. The objective was to evaluate human mesenchymal stem cell (h-MSC) proliferation (tritiated thymidine incorporation, total DNA Hoechst 33258 and scanning electron microscopy) and osteogenic differentiation (alkaline phosphatase activity) in human demineralised bone matrix (h-DBM) and HA, with or without OP-1. Cell proliferation on HA+OP-1 was significantly higher compared to HA at all time points (p< 0.05) and to DBM alone (day 1, p=0.042; day 14, p< 0.001). Cell proliferation was higher in DBM+OP-1, at all time points compared to HA+OP-1 but only in absolute values. Cell differentiation was significantly higher in HA+OP-1 compared to HA (p< 0.05) but comparable to DBM alone. Differentiation was significantly higher on DBM+OP-1 at all time points compared to HA (p< 0.05) and to HA+OP-1 (p< 0.05). HA is a potential graft expander in impaction allografting. When combined with OP-1 is comparable to DBM alone and being non absorbable may support the impacted graft in the early stages after the administration of OP-1.

Impaction allografting is a bone tissue engineering technique currently used in lower limb reconstruction orthopaedic surgery. Our hypothesis was that biological optimisation can be achieved by demineralisation and addition of osteogenic protein-1(OP-1) to the allograft. The objective of our in vitro study was to evaluate human mesenchymal stem cell (MSC) proliferation (Alamar Blue assay, titrated thymidine assay, total DNA Hoechst 33258 and scanning electron microscopy) and osteogenic differentiation (alkaline phosphatase assay) in two types of impacted carrier, namely demineralised bone matrix (DBM) and insoluble collagenous bone matrix (ICBM), with or without OP-1. The objective in vivo was to compare the osteogenic potential of impacted DBM with or without OP-1, with that of impacted fresh frozen allograft (FFA), again with or without OP-1. DBM+OP-1 optimized osteoinduction and significantly improved (p< 0.05) proliferation and differentiation in comparison to the majority of all other graft preparation in vitro. In addition DBM+OP-1 was significantly superior, with regard to osteogenesis, compared to the impacted FFA alone (p< 0.001), FFA+OP-1 (p=0.01) and DBM alone (p=0.02) in vivo. We propose that partial demineralisation and addition of OP-1 provides a good method for improving the osteoinductive properties of fresh allograft currently used in the impaction grafting technique.

Limitations of allografts and autografts for bone repair have increased the demand for a synthetic bone graft substitute for load-bearing and non-load bearing osseous defects. Tissue engineering of bone has thus been implicated to circumvent and eliminate the limitations of existing therapies, with living cell-scaffold constructs ultimately “integrating” with the patients own tissue. Bone engineering requires cells, growth inducing factors and a scaffold for delivery of cells to the anatomic site, creation of 3-D space for tissue formation and mechanical support. In this study, we investigated whether addition of osteogenic Protein-1 (OP-1) enhanced the osseoinductive properties of hydroxyapatite (HA) loaded with mesenchymal stem cells (MSCs). The study was conducted over a fourteen day period and the two groups HA/MSC and HA/MSC loaded with OP-1 were analysed qualitatively by SEM and quantitatively by assessment of proliferation (Alamar blue assay and total cellular DNA) and differentiation marker alkaline phosphatase activity (ALP). HA/MS/OP-1 showed a statistically significant (p< 0.05) increase in cell proliferation (286.52 ± 58.2) compared to the unloaded samples (175.62 ± 23.51). ALP activity (release) was also significantly enhanced (p < 0.05) in the loaded samples at day 14 (12.63 ± 1.58) compared to the control (2.73 ± 1.07).

Conclusion: the osseoinductive potential of HA was markedly improved by the incorporation of MSC’s and OP-1. This type of graft could provide improved mechanical stability at an earlier time point, and may influence future clinical application of HA for load bearing sites.

Introduction: The survival of massive endoprosthesis replacements is not as successful as conventional joint replacements. The main cause of failure of these implants is aseptic loosening. Bone in-growth onto the implant collar on the shaft of the prosthesis adjacent to the transaction site has been correlated with a decrease in radiolucent lines adjacent to the intramedullary stem and reduced implant loosening. We propose that bone contact and in-growth to the collar may be further enhanced with tissue engineering techniques. The hypothesis of this study was that autologous mesenchymal stem cells (MSCs) suspended within fibrin glue and sprayed onto hydroxyapatite (HA)-coated collars of massive prosthesis will augment bone growth and contact to the implant in an ovine model.

Materials and Methods: MSCs were isolated and expanded in vitro from the iliac crest of six adult sheep. Pre-implantation, 2 x 106 autologous MSCS were suspended in thrombin. During surgery, this mixture was combined with fibrinogen and sprayed onto the proximal and distal HA-coated collars of tibial midshaft prostheses using pressurized air. The implants were cemented into the right hind limb of twelve sheep, six of which received MSCs. Radiographs were taken at 2, 4 and 6 months and bone area within defined regions quantified using image analysis software. After six months, specimens were retrieved and processed for undecalcified histology. Transverse thin sections were prepared through the centre of each collar. Image analysis was used to quantify bone area and contact. Mann Whitney U tests were used for comparative statistical analysis, where p< 0.05 was classified as significant.

Results: Anterior-posterior (AP) radiographs taken at 2, 4, and 6 months showed that animals treated with MSCs produced more bone adjacent to the shaft of the implant. Analysis of bone area on both AP and medio-lateral (ML) radiographs taken after sacrifice showed that stem cell-treated implants encouraged significantly more total bone around the implants at 6 months than the control group (171.94 ± 29.04 mm2, and 87.51 ± 9.81 mm2 bone area, respectively, p = 0.016). Analysis of histological sections shows a significant increase in bone area around midshafts treated with MSCs, compared to the implant controls (53.99 ± 10.64 mm2, and 21.07 ± 7.34 mm2, respectively; p = 0.020). The average surface area contact between the midshaft and bone was almost doubled in the MSC-implant group (19.83 ± 8.73 % contact) than in the control group (8.667 ± 8.667 %, p = 0.196). In the MSC group bone was seen deep within the grooves of the HA coated collar whilst a fibrous soft tissue layer separated the newly formed bone in the control group.

Conclusion: Bone contact and in-growth to massive endoprostheses was significantly improved by spraying the implant with autologous MSCs suspended in fibrin glue. Enhanced fixation using stem cells may help prevent aseptic loosening in these massive implants.

Aim: The biological activity of demineralised bone matrix (DBM) led to the discovery of bone morphogenetic proteins (BMP). OP-1 (BMP 7) is an osteoinductive protein and has been demonstrated to be capable of inducing new bone formation in rat subcutaneous tissue and in both orthotopic and heterotopic sites in primates. In this study we have investigated whether demineralisation and addition of osteogenic. protein 1 (OP-1) improves osteoinductive properties of allograft. Methods: A randomised controlled blind trial was performed in 16 rats. One group received two pellets of fresh frozen allograft; the other received two pellets of demineralised bone (DBM) intramuscularly. In each rat one pellet was treated with OP-1 (2mg/25mg of graft). The rats were sacriþced at 28 days and tissue þxed and processed for sectioning with haematoxylin and eosin for morphology and Alcian blue and Sirrus red for collagen types I, II. Qualitative observations were made and each specimen graded 0–5 on the degree of new bone formation and integration by two blind observers. Results & Conclusions: DBM with OP-1 yielded optimal results, being signiþcantly superior to allograft alone and allograft with OP-1. DBM alone was shown to be more effective compared to the allograft preparations. Hence we have shown that demineralization and OP-1 signiþcantly improve the osteoinductive properties of allograft

Aim: Mesenchymal stem cells (MSCñs) attach to hydroxyapaptite surfaces (HA) surfaces and given appropriate stimuli from human Bone Morphogenetic Protein 7 (OP -1), will differentiate into osteogenic cells. Our hypothesis is that combining HA/MSC/BMP-7 will provide a superior osseoinductive property compared to HA alone. Methods: Porous hydroxyapatite (74.6% porosity, and 0.65% closed porosity) loaded with MSCñs (2 x 105) were compared to samples loaded with rhBMP-7 (400 ng/0.1g HA,) of the same MSC concentration over a fourteen day period. Quantitative analysis (Cell proliferation, measured by total DNA and the Alamar blue assay and Cell differentiation- alkaline phosphatase activity) and qualitative (Light and Scanning Electron Microscopy) were performed. The Students T-test was performed. Ethical approval for the use of human tissue was obtained prior to experimentation Results: Cell proliferation as indicated by total DNA, and Alamar blue was signiþcantly enhanced (P< 0.05) in the BMP-7 loaded composite at all time points. ALP production and release was enhanced in loaded samples. ALP production per unit DNA was also enhanced in the loaded samples and was signiþ-cant at day fourteen. Conclusion: Results indicate that the loaded composites showed enhanced cell proliferation, and ALP production and release. SEM analysis also demonstrated enhanced cell attachment and an increase number of proliferative cells. Thus the HA/MSC/BMP-7 composite displayed superior osseo-inductive properties in comparison to the HA/MSC composite.