Introduction. Infection of endoprostheses is a serious complication in orthopedic surgery. As
Aim. The utilization of
Orthopaedic and trauma implant related infection remains one of the major complications that negatively impact clinical outcome and significantly increase healthcare expenditure. Hydroxyapatite has been used for many years to increase implant osseointegration.
Infections are among the main complications connected to implantation of biomedical devices, having high incidence rate and severe outcome. Since their treatment is challenging, prevention must be preferred. For this reason, solutions capable of exerting suitable efficacy while not causing toxicity and/or development of resistant bacterial strains are needed. To address infection, inorganic antibacterial coatings, and in particular
Introduction. Implant associated infections are responsible for over 10 % of recorded orthopaedic revision surgeries across the UK, with higher infection rates commonly observed for other endoprostheses such as cranioplasties. To prevent colonization and biofilm formation on implant surfaces, the use of
Uncemented implants combining antimicrobial properties with osteoconductivity would be highly desirable in revision surgery due to periprosthetic joint infection (PJI).
Infected mega-endoprostheses are difficult to treat with systemic antibiotics due to encapsulation of the implant by fibrous tissue, formation of biofilms and antibiotic resistant bacteria. Modifying the implant surface by incorporating a bactericidal agent may reduce infection. Infection rates are typically in the range of 8% to 30%. This study describes a novel process method of “stitching-in” ionic
Objectives. 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. Methods. 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. Results. In total, 11 of the 12 patients completed the study. No argyria or considerable differences in laboratory parameters were detected.
INTRODUCTION. Post-operative infections following end-stage joint salvage reconstruction, tumor resection and megaprosthetic reconstruction is a major problem because of increasing infection rates in this patient cohort. The success of treatment and longevity is limited because current prosthetic composites do not decrease infection rates in these patients.
Aim.
Introduction. A modified anodisation technique where a titanium surface releases bactericidal concentrations of
Metallic implants are used frequently in the operative repair of joints and fractures in orthopaedic surgery. Metal infection is a catastrophic complication of the surgery with patients loosing their newfound mobility and independence, associated morbidity and mortality is high. Orthopaedic implant infection is chronic and biofilm based. Present treatment focuses on removing the infective substratum and implant surgically as well as prolonged anti-microbial therapy. Biofilms are 500 times more resistant than planktonic strains of bacterial flora to antibiotics, and with evolving resistant strains this form of therapy is loosing ground.
Long-term survival and favourable outcome of implant use are determined by bone-implant osseointegration and absence of infection near the implants. As with most diseases, prevention is the preferred approach.
Foreword.
Introduction. Various anti-infective agents can be added to the surface of orthopaedic implants to actively kill bacteria and prevent infection.
Metallic implants are used frequently in the operative repair of joints and fractures in orthopaedic surgery. Orthopaedic implant infection is chronic and biofilm based. Present treatment focuses on removing the infective substratum and implant surgically as well as prolonged anti-microbial therapy. Biofilms are up to 500 times more resistant than planktonic strains of bacterial flora to antibiotics.
Surgical site infection related to orthopaedic implants is one of the serious complications. In the previous works, we developed a novel thermal spraying technology combined
Aim. To investigate the effectiveness of
Introduction. Titanium (Ti) alloys are used as porous bone ingrowth materials on non-cemented knee arthroplasty tibial tray implants. Nano-surface mechanism that increase the osseointegration rate between Ti alloys, and surrounding tissue has been recognized to improve the interface to ultimately allow patients to weight bear on non-cemented arthroplasty implants sooner. Bioactive TiO. 2. nanotube arrays has been shown to accelerate osseointegration. Ideally, these surfaces would both increase the adhesion of bone to the implant and help to reduction of infection to substitute for antibiotic bone cement. This study examines a combination treatment of both TiO. 2. nanotubes combined with
Introduction: Chronic infection after total joint arthroplasty is a complication of major concern to orthopaedic surgeons, especially if patients suffer from any type of immunodeficiency. But for extensive surgical and systemic treatment recurrence rates are high.