Preclinical data showed poly(methyl methacrylate) (PMMA) loaded with microsilver to be effective against a variety of bacteria. The purpose of this study was to assess patient safety of PMMA spacers with microsilver in prosthetic hip infections in a prospective cohort study. A total of 12 patients with prosthetic hip infections were included for a three-stage revision procedure. All patients received either a gentamicin-PMMA spacer (80 g to 160 g PMMA depending on hip joint dimension) with additional loading of 1% (w/w) of microsilver (0.8 g to 1.6 g per spacer) at surgery 1 followed by a gentamicin-PMMA spacer without microsilver at surgery 2 or vice versa. Implantation of the revision prosthesis was carried out at surgery 3.Objectives
Methods
Osteoporosis and osteomalacia lead to increased fracture risk. Previous studies documented dysregulated osteoblast and osteoclast activity, leading to a high-turnover phenotype, reduced bone mass and low bone mineral content. Osteocytes, the most abundant bone cell type, are involved in bone metabolism by enabling cell to cell interaction. Osteocytes presence and viability are crucial for bone tissue homeostasis and mechanical integrity. Osseo-integration and implant degradation are the main problems in developing biomaterials for systemically diseased bone. This study examines osteocyte localisation, morphology and on the implant surface and at the implant bone interface. Furthermore, the study investigates ECM proteins regulation correlated to osteocytes and mechanical competence in an ovariectomised rat model with a critical size metaphyseal defect. After induction of osteoporosis, 60 female Sprague-Dawley rats were randomised into five groups: SrCPC (n=15), CPC (n=15), ScB30 (n=15), ScB30Sr20 (n=15) and empty defect (n=15). The left femur of all animals underwent a 4mm wedge-shaped metaphyseal osteotomy that was internally fixed with a T-shaped plate. The defect was then either filled with the above mentioned implants or left empty. After six weeks, histomorphometric analysis showed a statistically significant increase in bone formation at the tissue-implant interface in the SrCPC group compared to the other groups (p<0.01). Osteocyte morphology and networks were detected using silver and staining. ECM proteins were investigated through immunohistochemistry. Cellular populations were tested using enzyme histochemistry. Mineralisation was assessed using time of flight secondary ion mass spectrometry (TOF-SIMS). Statistical analysis was performed using Mann Whitney U test with Bonferroni correction.Objectives
Methodology
Multiple Myeloma is a hematological malignancy of terminally differentiated plasma cells associated with increased osteoclast activity and decreased osteoblast functions. Systemic antiproliferative treatment includes proteasome inhibitors such as bortezomib, a clinical potent antimyeloma agent. Local delivery of biological active molecules via biomaterial composite implants to the site of the lesion has been shown to be beneficial for bone and implant-associated infections. In anticancer treatment local delivery of anticancer agents to the neoplasia via biomaterial carriers has never been reported before. The purpose of the current is to present the concepts and the first in vivo results for proteasome inhibitor composite biomaterials for local delivery of bortezomib to proliferative multiple myeloma bone lesions including concentration measurements at different anatomical regions in a rat model. 80 female Sprague-Dawley rats were randomised into five different treatment groups (n=16/group): 1) Empty (2) Xerogel-granulat: XG (3) Xerogel-granulat+100mgbortezomib [b]: XG100b (4) Xerogel-granulat+500mgb:XG500b (5) Xerogel-granulat+2500mgb:XG2500b. A 2.5 mm drill hole was then created in the metaphysis of the left femur. The defect was then either filled with the previously mentioned substitutes or left empty to serve as a control. After 4 weeks femora were harvested followed by histological, histomorphometrical and immunohistochemical (BMP2; bone-morphogenic protein 2, OPG; osteoprotegerin, RANKL; Receptor activator of nuclear factor kappa-B ligand, ASMA; alpha smooth muscle actin, ED1;CD68 antibody). TOF-SIMS was used to assess the distribution of released strontium ions. Statistical analysis was done using SPSS software. Data was not found normally distributed and hence Mann-Whitney U with bonferroni correction was used. To avoid type I errors due to unequal variances and group sizes Games-Howell test was also performed.Background
Methods
Magnesium has a number of qualities suitable for bioresorbable metallic implants. However, high corrosion rate and formation of hydrogen gas can compromise its performance. Combining magnesium with calcium phosphate improves magnesium's biocompatibility by decreasing gas formation and increasing bone remodeling. Clinical problems like risk of postoperative infection and increased incidence of pediatric trauma requiring surgical intervention raised the need for temporary orthopedic implants that would resorb after the bone healing is complete. This would decrease high costs associated with repeated surgeries, minimise recovery times, decrease the risk of postoperative infections, and thus promote higher quality of life to the patients. The specific requirement for orthopedic implants, aside from being bioresorbable, is the ability to bear high loads. Magnesium was suggested as a suitable material for these purposes because it is biocompatible; has excellent mechanical properties; is natural for human body, and seems to stimulate new bone formation. However, an important problem with magnesium is high corrosion rate with consistent hydrogen gas formation on contact with fluids. This Summary Statement
Introduction
The introduction of new treatments needs to be both clinically effective and cost effective. Clinicians tend to be unaware of the importance of the latter, and how health economic assessments are undertaken, especially in a public health system where the inclusion of funded treatments is made on a national basis. The purpose of this study was to determine the cost savings from a societal perspective in the use of recombinant human Bone Morphogenetic Protein -2 (rhBMP-2) in grade III A and B open tibia fractures treated with a locked intramedullary nail and soft-tissue management in the UK, Germany, and France. Healthcare system (direct healthcare costs) and costs for productivity losses (indirect health-care costs) were calculated using the raw data from the Bone Morphogenetic Protein Evaluation Group in Surgery for Tibial Trauma “BESTT study”. Return-to-work time for estimation of productivity losses was assumed to correspond with the time of fracture healing. For calculation of secondary interventions costs and productivity losses the respective 2007/08 national tariffs for surgical procedures and average national wages for the UK, Germany, and France were used. From a societal perspective, overall savings per case of €7911 for the UK, €9270 for Germany, and €9291 were calculated. Those savings largely offset the upfront price of rhBMP-2 of €2266(£1,790) in the UK, €2970 in Germany, and €2950 in France. Total net savings can be estimated to be €9.6 million for the UK, €14.5 million for Germany, and €11.4 million for France. For all three countries reduced productivity losses are the key driver for the overall savings. In summary, despite the apparent high direct cost of rhBMP-2 in grade III A and B open tibia fractures, at a national level there are net cost-savings from a societal perspective for all three countries.
Gentamicin was described with negative effects on bone formation. Arginin-Glycin-Aspartat (RGD) sequences play a key role in the adhesion of osteoblasts and have proven to improve implant integration. We have already shown a significant reduction in infection rates by a combined gentamicin-hydroxyapatite (HA) and gentamicin-RGD-hydroxyapatite coating in a rabbit infection model for cementless joint prostheses. The purpose of the study was to assess whether the gentamicin-HA coating had a negative effect on the implant integration and new bone formation, compared to pure HA coating, and whether this could be enhanced by additional gentamicin-RGD-HA coating. There were 5 study groups (8 animals per group) with 5 different stainless steel K-wires: uncoated, HA coated, gentamicin-HA, RGD-coated, gentamicin-RGD-HA coated. A 2.0 mm K-wire with one type of coating was introduced into the intramedullary canal of the tibia. The tibiae were harvested after 12 weeks and standardised longitudinal and transverse sections were performed to study new bone formation around the implant and implant bone contact. New bone formation and osseointegration of the implant surface was assessed using histomorphometrical methods by computerised semi-quantitative analysis and histological methods. There were no significant differences between the HA and the gentamicin-HA group although new bone formation and implant bone contact were always higher for the pure HA coating. Additional RGD coating on the gentamicin-RGD-HA coating did not show significant improvement of bone formation and implant integration compared to gentamicin-HA. There was a very similar histological appearance of new bone formation between all groups with very low frequency of giant cells, indicating good biocompatibility. Gentamicin-HA coating did not have significant negative effects on bone formation and bone implant contact, compared to pure HA coating. In combination with the excellent ability to reduce infection rates, gentamicin-HA coating may have a high interest in cement-less arthroplasty.
These studies are indicative of the potential utility of resorbable and nonresorbable inorganic materials as bone graft substitutes. Bone transplants and bone substitute materials are necessary in +/−10% of all skeletal reconstructive operations. The higher osteogenic potential of autografts compared to allogenic transplants is undisputed, but restricted by limited availability and necessity of secondary operations. Commercial bone graft materials show variety of compositions and properties, many very different from those of autologous bone. Physicochemical properties of these materials were compared using x-ray diffraction, scanning and transmission electron microscopy. Biological reactivity of different materials was also compared in histological evaluations in animal models. Experimental and clinical studies have been encouraging, especially in metaphyseal defects. Bone substituting the artificial material should be able to bear weight and, if possible, be lamellar bone. Since fundamental examinations of osteoinduction and affiliated isolation of growth factors (Urist 1965), extensive scientific research on growth factors contained in bone matrix has been performed. Proteins of the TGF-β family play a key role in regulation of bone regeneration. In past years, alkaline fibroblast growth factor has raised increased interest among researchers. Its presence implies that it plays an important role in the development of bone substance. One best known effect is significant augmentation of microangiogenesis, which could be demonstrated among others in experimental wound healing investigations. Further experimental examinations showed significant increase of callus formation in rats and miniature pigs, in which FGF had been injected into the fracture site. Current bone substitute materials are only to be used in clearly defined indications, as they do not currently meet the biological or mechanical properties of autogenous bone. Our knowledge is grounded on various experimental models, which are not always comparable. Therefore many aspects have to be considered as a working understanding.
Infections in total joint arthroplasty, particularly with multiresistant bacteria, are a serious problem. A new nanoparticulate silver cement had previously shown good biocompatibility combined with good in vitro antimicrobial activity against multiresistant bacteria. The purpose of the current study was to evaluate the antibacterial activity of nanoparticulate silver cement against biofilm-building methicillin-resistant S. aureus (MRSA) in a rabbit model and to compare it to that of gentamicin-loaded cement. Gentamicin cement or nanoparticulate silver bone cement was injected into the proximal half of one femur in 10 animals, respectively. Before hardening of the cement 107 or 108 colony forming units of MRSA with high gentamicin resistance were inoculated at the cement bone interface in 5 rabbits of each group. The animals were euthanized after 14 days and both the cement adjacent bone and the cement itself were studied using microbiological and histological methods. Infection was defined as positive culture growth from the bone and/or cement samples. Infections rates were 100% for the gentamicin group (10 of 10 animals had infection) and 30% for the NanoSilver group (3 of 10 animals). Thus, nanoparticulate silver bone cement significantly reduced infection rates by 70%. Nanoparticulate silver cement exhibited good antimicrobial activity in the prophylaxis of cement-related infections with MRSA and is therefore a promising alternative in total joint arthroplasty.