Introduction

Post-traumatic arthritis is the commonest cause of arthritis of the ankle. Development of arthritis is dependent on the restoration of pre-injury anatomy. To assess the effect of grade of lead surgeon on the accuracy of surgical reduction, we performed a retrospective radiographic analysis of all ankle fractures undergoing open reduction and internal fixation, in a single institution.

The steric and electrostatic complementarity of natural proteins and other macromolecules are a result of evolutionary processes. The role of such complementarity is well established in protein-protein interactions, accounting for the known protein complexes. To our knowledge, non-biological systems have not been a part of such evolutionary processes. Therefore, it is desirable to design and develop nonbiological surfaces, such as implant devices (e.g. bone growth for non-cemented fixation), that exhibit such complementarity effects with the natural proteins.

Cell attachment and spreading in vitro is generally mediated by adhesive proteins such as fibronectin and vitronectin [1]. The primary interaction between cells and adhesive proteins occurs through integrin and an RGD amino acid sequence. The adsorption of adhesive proteins plays an important role in cell adhesion and bone formation to an implant surface [1]. The ability of the implant surface to adsorb these proteins determines its aptitude to support cell adhesion and spreading and its biocompatibility. For example, the enhancement of osteoblast precursor attachment on hydroxyapatite (HA) as compared to titanium and stainless steel was related to increased fibronectin and vitronectin absorption [2].

The role of surface characteristics, such as topography, has been studied in recent years without the emergence of a comprehensive and consistent model [1]. For example, while no statistically significant influence of surface roughness on osteoblast proliferation and cell viability was detected in the study of metallic titanium surfaces [3], the TiO2 film enhances osteoblast adhesion, proliferation and differentiation upon an increase in roughness [4].

We designed and produced ceramic [5] and metallic coatings via an ion beam assisted deposition process with spatial dispersion (roughness) comparable to the size of proteins (3–20nm). Our ceramic and cobaltchrome (CoCr) coatings exhibit high hardness and contact angles with serum of 0° and 40° to 50°, respectively. Furthermore, our theoretical calculations and quantum-mechanical modeling clearly indicate that the spatial electric potential variation across our designed ceramic surfaces is comparable to the electrostatic potential variation of proteins such as fibronectin, promoting increased absorption on these surfaces. Therefore, an increase in the concentration of adhesive proteins on the designed surfaces results in the enhancement of the focal adhesion of cells. Our experimental results of the adhesion and proliferation of osteoblast-like stromal cells from mouse bone marrow indicate that our nanostructured coatings are three to five times better than growing on HA and orthopaedic grades of titanium and CoCr. Our results are consistent with the steric and electrostatic complementarity of nanostructured surfaces and adhesive proteins. This paper presents the adhesion and proliferation of osteoblast-like cells on micro-and nanostructured surfaces and provides new models describing the mechanism responsible for the enhancement of cell adhesion on nanostructured ceramic and metallic surfaces compared with orthopaedic materials.

Purpose: This study investigates the synergistic use of fusidic acid with vancomycin, and linezolid in poly-methylmethacrylate (PMMA) cement for the treatment of orthopedic MRSA and MRSE infections. Alone, Vancomycin is typically eluted in limited quantities from cement. The purpose of this study was to

combine FA and Vancomycin, and Linezolid alone in PMMA cement and characterize antibiotic elution, and

Method: Standardized 1g pellets of Palacos cement were manufactured containing Vancomycin and FA or Linezolid at increasing concentrations in three batches: without additive, with increasing concentrations of PEG, and with increasing concentrations of NaCl. The pellets were incubated in phosphate buffered saline and sampled at regular intervals. Drug analysis was performed with high pressure liquid chromatograpy.

Results: Total drug release at 2.5% loading of Vancomycin alone was 0.84% and of FA was 2.35%. Linezolid showed comparable release profiles. Vancomycin and FA combined yeilded Vancomycin release of 6.2% and FA of 8.4%. The addition of 30% PEG increased release of Vancomycin and Fusidic Acid by six-fold. The addition of 18% NaCl increased total Vancomycin release by 11-fold but had no effect on FA release.

Conclusion: Linezolid, Vancomycin and FA can be combined in PMMA and have favorable release profiles. The addition of PEG and NaCl dramatically increases the release of antibiotics, with the exception of FA and NaCl. These strategies may be useful in the management of MRSA/MRSE infections.

We present a system for treatment by controlled motion after repair of flexor tendons in the hand. This Washington regimen incorporates both controlled active extension against passive flexion by rubber band and the use of controlled passive extension and flexion. We utilise the Brooke Army Hospital modification of the rubber band passive flexion splint; this provides for maximal excursion of the tendon with full passive flexion of the finger. The 66 patients (78 fingers) who form the basis of this study all sustained complete laceration of the flexor profundus and superficialis tendons in "no man's land". Results were evaluated by the Strickland formula of total active motion (TAM) of the proximal and distal interphalangeal joints. Sixty-two fingers (80%) were rated "excellent", 14 fingers (18%) were "good", two fingers (2%) were "fair", none was rated "poor". Our regimen of controlled motion rehabilitation has also been applied with equal success to cases of flexor tendon grafting.