Infections of Orthopaedic Implants and Devices

The Effect of Platelet-Rich Plasma on Type I Collagen Production, VEGF Expression, and Neovascularization after Femoral Bone Implants: A Study on Rat Models

Introduction

Platelet-rich plasma (PRP) contains many growth factors, such as FGF, which induces the production of type I collagen, and VEGF, which induces neovascularization, all of which are important in bone healing. This study aimed to evaluate the effect of PRP administration on type I collagen production, VEGF expression, and neovascularization in rat models following femoral bone implants using K-wire.

Methods

An experimental randomized control study was conducted on 24 white male rats (Rattus norvegicus) in the Wistar strain that underwent K-wire implantation, where PRP was administered to the treatment groups. The amount of type I collagen was measured by immunohistochemistry VEGF expression using sandwich ELISA, and neovascularization by histopathological examination.

Results

The amount of type I collagen in the treatment group (50–>150/field of view) was significantly higher than the control group (0–99/field of view; p=0.003). VEGF expression in the treatment groups was significantly higher than controls: 10.90±4.47 and 2.29±0.92, respectively (p=0.006). Mean number of new vessels formed on fibrotic capsules in the treatment groups was significantly (p=0.007) higher than the control groups (2.69±1.03 vs 0.67±0.52).

Conclusion

The use of PRP significantly increased type I collagen production, VEGF expression, and neovascularization in rat models, elucidating the potential of PRP to be used in clinical settings to enhance the bone-healing process.

Hydroxyapatite Pellets as Versatile Model Surfaces for Systematic Adhesion Studies on Enamel: A Force Spectroscopy Case Study

Research into materials for medical application draws inspiration from naturally occurring or synthesized surfaces, just like many other research directions. For medical application of materials, particular attention has to be paid to biocompatibility, osseointegration, and bacterial adhesion behavior. To understand their properties and behavior, experimental studies with natural materials such as teeth are strongly required. The results, however, may be highly case-dependent because natural surfaces have the disadvantage of being subject to wide variations, for instance in their chemical composition, structure, morphology, roughness, and porosity. A synthetic surface which mimics enamel in its performance with respect to bacterial adhesion and biocompatibility would, therefore, facilitate systematic studies much better. In this study, we discuss the possibility of using hydroxyapatite (HAp) pellets to simulate the surfaces of teeth and show the possibility and limitations of using a model surface. We performed single-cell force spectroscopy with single Staphylococcus aureus cells to measure adhesion-related parameters such as adhesion force and rupture length of cell wall proteins binding to HAp and enamel. We also examine the influence of blood plasma and saliva on the adhesion properties of S. aureus. The results of these measurements are matched to water wettability, elemental composition of the samples, and the change in the macromolecules adsorbed over time on the surface. We found that the adhesion properties of S. aureus were similar on HAp and enamel samples under all conditions: Significant decreases in adhesion strength were found equally in the presence of saliva or blood plasma on both surfaces. We therefore conclude that HAp pellets are a good alternative for natural dental material. This is especially true when slight variations in the physicochemical properties of the natural materials may affect the experimental series.

[PCR research as an auxiliary method for diagnostics of periphresitical infection after endostreditision of joints (clinical case).]

Periprosthetic infection (PPI) after arthroplasty of large joints is the third (among the main causes of unsatisfactory results of surgical treatment) a serious threat to the health of patients. The «gold standard» for the diagnosis of PPI is the bacteriological examination of samples of periprosthetic tissues and synovial fluid. In 10-30% of cases, it is impossible to isolate microorganisms, which is explained by the difficulty of cultivation and taking antibiotics before sampling. The purpose of study is to demonstrate the diagnostic value of PCR diagnostics for identifying the genetic material of an infectious pathogen of a culture-negative periprosthetic infection. Material of the study is a description of a clinical case of a culture-negative periprosthetic infection that caused a second two-stage revision of the hip joint prosthesis In the first episode of PPI that occurred 3 years after hip replacement, a microbiological examination of the puncture of the trochanteric zone of the operated joint revealed a massive increase in methicillin-resistant Staphylococcus epidermidis (MRSE). A two-stage revision joint replacement was performed. 5 years after the revision, the patient was hospitalized with clinical and radiological signs of PPI, while examining the puncture of the joint revealed characteristic PPI cytosis. Microbiological examination of punctate and intraoperative aspirate at the first stage of the repeated two-stage revision endoprosthesis replacement did not reveal aerobic and anaerobic microorganisms. In PCR studies, the DNA of methicillin-sensitive Staphylococcus aureus (MSSA) was detected in washouts from the removed components of the endoprosthesis; no resistance marker (mecA gene) was found. Given the concomitant oncological disease, this result determined the appointment of pathogenetic antibiotic therapy, the effectiveness of which was confirmed after 8 weeks at the II stage of revision. The PCR study of joint and trochanteric punctures (before surgery), flushing from the removed spacer components (after ultrasound treatment) and intraoperative aspirate from the joint did not reveal Staphylococcus aureus DNA and resistance marker (mecA gene). In some cases of periprosthetic infection, traumatologists and orthopedists deal with culturally negative results of a microbiological study of the patient's biomaterial and swabs from the components of endoprostheses in the presence of clinical manifestations of PPI, confirmed by laboratory diagnostics and X-ray examination. According to the literature, such clinical situations are observed in 10-30% of cases and are caused by previous antibiotic therapy in the early stages of an infectious complication. After surgical treatment of PPI for the selection of adequate antibiotic therapy, such patients need to at least indirectly determine the type of infection pathogen, which is achieved by the use of additional diagnostic methods, such as a PRC study. In the case described by us, after a course of antibiotic therapy, prescribed according to the results of the first PCR study, the patient's body does not contain DNA traces of the desired infectious agent. Thus, the repeated PCR not only confirmed the accuracy of the initial diagnosis of the source of infection, but also further illustrated the success of the rehabilitation of the periprosthetic infection using a correctly selected antibacterial drug at the previous stage of the study. The use of the PCR method made it possible to diagnose the pathogen and prescribe adequate antibiotic therapy for culture-negative periprosthetic infection.

Titanium Kirschner Wires Resist Biofilms Better Than Stainless Steel and Hydroxyapatite-coated Wires: An In Vitro Study

Aim

External fixation surgery is frequently complicated by percutaneous pin site infection focused on the surface of the fixator pin. The primary aim of this study was to compare biofilm growth of clinically isolated pin site bacteria on Kirschner wires of different materials.

Materials and methods

Two commonly infecting species, Staphylococcus epidermidis and Proteus mirabilis, were isolated from patients’ pin sites. A stirred batch bioreactor was used to grow these bacteria as single culture and co-cultured biofilms on Kirschner wires made of three different materials: stainless steel, hydroxyapatite-coated steel and titanium alloy.

Results

We found that the surface density of viable cells within these biofilms was 3x higher on stainless steel and 4.5x higher on hydroxyapatite-coated wires than on the titanium wires.

Conclusion

Our results suggest that the lower rates of clinical pin site infection seen with titanium Kirschner wires are due to, at least in part, titanium’s better bacterial biofilm resistance.

Clinical significance

Our results are consistent with clinical studies which have found that pin site infection rates are reduced by the use of titanium relative to stainless steel or hydroxyapatite-coated pins.

How to cite this article

McEvoy JP, Martin P, Khaleel A, et al. Titanium Kirschner Wires Resist Biofilms Better Than Stainless Steel and Hydroxyapatite-coated Wires: An In Vitro Study. Strategies Trauma Limb Reconstr 2019;14(2):57–64.

Silver nanoparticles-modified films versus biomedical device-associated infections

A serious issue related to biomedical devices (BDs) is that of bacterial infections. BDs colonized by bacteria may cause infection or mortality. To prevent such infections, an effective strategy is to develop novel BDs with antibacterial abilities via various surface modification processes. Thus, plenty of silver nanoparticles (Ag NPs)-modified films were brought forward to because of their potential applications in improving the antibacterial properties of BDs. This article reviews the difficulties in diagnosing and treating biomedical device-associated infections as well as the state of arts in fabricating the Ag NPs-modified films for antibacterial applications. In addition, the nanoeffect of silver particles and the cytotoxicity of Ag NPs are also discussed. It is clear that safe and durable Ag NPs-modified films are more desirable for the BDs prone to bacteria. To further extend the investigations on controlling the toxicity path of Ag NPs to both bacteria and mammalian cells, developing novel green fabrication processes with more 'cleaner' (without accompaniment of ligands or reduction agents) Ag NPs should be the first mission for the material scientists to complete.