Aim. To evaluate bacterial adhesion and biofilm formation to metallic cerclage wire versus polymer cerclage system (SuperCable®). Methods. Experimental in vitro study to evaluate quantitative bacterial adherence to different cerclage wire materials. Two types of cerclage wires were compared: a metallic versus a polymer based wire (SuperCable®). A two-centimeter cerclage wire piece of each material was included in 2 mL of tryptic soy broth (TSB) culture media, inoculated with 10 microliters of a 0.5 McFarland of a Staphylococcus epidermidis strain and cultivated at 37°C during 2h for adhesion and 48h for biofilm formation. After this time, the cerclages were washed using a 1% phosphate buffered saline (PBS) and sonicated in new culture medium. After sonication, dilutions of each culture were spread in TSB agar and incubated 37°C during 24h. The number of colonies were counted and the cfu/cm2 was calculated. Results. There were no differences in the number of colonies counted at 2 hours. At 48 hours, the polymer cerclage system showed a clinically and statistically reduction of 95.2% in the biofilm formation of S. epidermidis. The highest bacterial counts were observed in metallic cerclages after 48h. Conclusion. In in vitro conditions, the polymer cerclage system may offer decreased biofilm formation compared with metallic cerclage wires. However, there are many other factors in in vivo conditions that could play a role in bacterial adhesion to cerclage wires. Further research is needed in order to recommend the use of polymer cerclage systems for septic revision surgery

Introduction. Support of appositional bone ingrowth and resistance to bacterial adhesion and biofilm formation are preferred properties for biomaterials used in spinal fusion surgery. Although polyetheretherketone (PEEK) is a widely used interbody spacer material, it exhibits poor osteoconductive and bacteriostatic properties. In contrast, monolithic silicon nitride (Si. 3. N. 4. ) has shown enhanced osteogenic and antimicrobial behavior. Therefore, it was hypothesized that incorporation of Si. 3. N. 4. into a PEEK matrix might improve upon PEEK's inherently poor ability to bond with bone and also impart resistance to biofilm formation. Methods. A PEEK polymer was melted and compounded with three different silicon nitride powders at 15% (by volume, vol.%), including: (i) α-Si. 3. N. 4. ; (ii) a liquid phase sintered (LPS) ß-Si. 3. N. 4. ; and (iii) a melt-derived SiYAlON mixture. These three ceramic powders exhibited different solubilities, polymorphic structures, and/or chemical compositions. Osteoconductivity was assessed by seeding specimens with 5 × 10. 5. /ml of SaOS-2 osteosarcoma cells within an osteogenic media for 7 days. Antibacterial behavior was determined by inoculating samples with 1 × 10. 7. CFU/ml of Staphylococcus epidermidis (S. epi.) in a 1 × 10. 8. /ml brain heart infusion (BHI) agar culture for 24 h. After staining with PureBlu™ Hoechst 33342 or with DAPI and CFDA for SaOS-2 cell adhesion or bacterial presence, respectively, samples were examined with a confocal fluorescence microscope using a 488 nm Krypton/Argon laser source. Images were also acquired using a FEG-SEM in secondary and backscattered modes on gold sputter-coated specimens (∼20–30Å). Hydroxyapatite (HAp) deposition was measured using a laser microscope. Raman spectra were collected for samples in backscattering mode using a triple monochromator using a 532 nm excitation source (Nd:YVO. 4. diode-pumped solid-state laser). Results. PEEK composites with 15 vol.% α-Si. 3. N. 4. , LPS ß-Si. 3. N. 4. , or the SiYAlON mixture showed significantly greater SaOS-2 cell proliferation (>600%, p<0.003, cf., Fig. 1(a)) and HAp deposition (>100%, p<0.003, cf., Fig. 1(b)) relative to monolithic PEEK. The largest increase in cell proliferation was observed with the SiYAlON composite, while the greatest amount of HAp was found on the LPS ß-Si. 3. N. 4. composite. Following exposure to S. epidermidis, the composite containing the LPS β-Si. 3. N. 4. powder showed one order of magnitude reduction in adherent live bacteria (p<0.003, cf., Fig. 1(c)) as compared to the PEEK monolith. It is interesting to note that the composite containing α-Si. 3. N. 4. exhibited the worst bacterial resistance (i.e., ∼100% higher than monolithic PEEK), suggesting that the bacteriostatic effectiveness of Si. 3. N. 4. bioceramics is apparently dependent upon the presence of selective sintering additives, viz. yttria and alumina. Conclusions. The addition of 15 wt.% of specific Si. 3. N. 4. powders to PEEK showed enhanced SaOS-2 cell adhesion, proliferation, and HAp deposition when compared to monolithic PEEK. These same composites also showed resistance to S. epi. adhesion and biofilm formation.. Although improvements in osteoconductivity have been previously observed by compounding or coating PEEK with HAp, titanium, or tantalum, these approaches did not provide anti-microbial properties. Compounding PEEK with Si. 3. N. 4. represents a significant advancement due to its ability to provide both improved bone apposition and resistance to biofilm formation. For any figures or tables, please contact the authors directly

Bacterial infection related to prosthetic replacement is one of the serious types of complications. Recently, there has been a greater interest in antibacterial biomaterials. In order to reduce the incidence of replacement-associated infections, we developed a novel coating technology of Hydroxyapatite (HA) containing silver (Ag). We reported the Ag-HA coating showed high antibacterial activity against E. coli, S. aureus and methicillin-resistant S. aureus (MRSA) under static condition. However, human bodies have a circulating body fluid, which is not a static condition. And the growth and the maturation of biofilm, which is said that a common course of persistent infections at a surgical site, are enhanced by the flow of broth in culture environment. Therefore, we evaluated whether the Ag-HA coating inhibits the biofilm formation on its surface or not by a biofilm-forming test under flow condition in this study. Ag-HA or HA powder was sprayed onto the commercial pure titanium disks using a flame spraying system. The HA coating disks were used as negative control. The biofilm-forming methicillin sensitive S. aureus (BF-MSSA; Seattle 1945) strain and the BF-MRSA (UOEH6) strain were used. The pre-culture bacterial suspension (about 10. 5. colony forming units; CFU) was inoculated onto the Ag-HA and HA coating disks. After cultivation at 37 °C for 1 h, the disks were rinsed twice with 500 μL sterile PBS (-) to eliminate the non-adherent bacteria. The number of the adherent bacteria on these disks was counted using culture method. After rinsing, the disks were transferred into petri-dish containing Trypto–Soy Broth (TSB) + 0.25% glucose with a stirring bar on the magnetic stirrer and they were cultured at 37°C for 7 days. In the meantime, the stirring bar was spun at 60 rounds per minute. Then, the disks were immersed in a fluorescent reagent to stain the biofilm. Finally, the biofilm on each disk was observed by a fluorescence microscope and the biofilm-covered rate on the surfaces of them was calculated using the NIH image software. The number of the bacteria on these disks was not so different between Ag-HA and HA coating after rinsing. After biofilm-forming test, the coverage of the biofilm of BF-MSSA was 2.1% and 81.0% on the Ag-HA and HA coatings, respectively. Similarly, in the case of BF-MRSA, it was 7.7% and 72.0% on the Ag-HA and HA coatings, respectively. Though bacteria slightly adhered, biofilm was hardly observed on the Ag-HA coating. The biofilm on the HA coating was extensive and mature. The inhibition effect of biofilm formation on the Ag-HA coating might be ascribed to the antibacterial effect by Ag ions released from the coating. Because Ag ions have a broad spectrum of antibacterial activity against pathogens, including biofilm forming bacteria, they inhibited the biofilm formation on the Ag-HA coating by killing adherent bacteria. Even in a flow condition, it was suggested that the AgHA shows the antibacterial activity, though the conditions in this work are different from those in living body

Problems. Biofilm infections are increasingly associated with orthopedic implants. Bacteria form biofilms on the surfaces of orthopedic devices. The biofilm is considered to be a common cause of persistent infections at a surgical site. The growth and the maturation of biofilm are enhanced by the flow of broth in culture environment. In order to reduce the incidence of implant-associated infections, we developed a novel coating technology of hydroxyapatite (HA) containing silver (Ag). We previously reported that the Ag-HA coating inhibits biofilm formation under flow condition of Trypto Soy Broth + 0.25% glucose for 7 days. In this study, we evaluated whether the Ag-HA coating continuously inhibits the biofilm formation on its surface under flow condition of fetal bovine serum, which contains many in vivo substrates such as proteins. Materials and Method. The commercial pure titanium disks were used as substrates. Ag-HA or HA powder was sprayed onto the substrates using a flame spraying system. The HA coating disks were used as negative control. The biofilm-forming methicillin resistant Staphylococcus aureus (BF-MRSA; UOEH6) strain was used. The bacterial suspension (about 10. 5. colony forming units) was inoculated into 24-well sterile polystyrene tissue culture plates. The Ag-HA and HA coating disks were aseptically placed in the wells. After cultivation at 37°C for 1 hour, the disks were rinsed twice with 500 μL sterile PBS (−) to eliminate the non-adherent bacteria. After rinsing, the disks were transferred into petri-dish containing heat-inactivated FBS with a stirring bar on the magnetic stirrer and they were cultured at 37 °C for 24 hours, 7 and 14 days. In the meantime, the stirring bar was spun at 60 rounds per minute. Then, the disks were immersed in a fluorescent reagent to stain the biofilm. Finally, the biofilm on each disk was observed by a fluorescence microscope and the biofilm-covered rate (BCR) on the surfaces of them was calculated using the NIH image software. Results. Biofilm was hardly observed on the Ag-HA coating. However, the biofilm on the HA coating was extensive and mature (Fig. 1). At 24h after cultivation, BCRs of BF-MRSA were 2.1% and 19.8% on the Ag-HA and HA coatings, respectively. Similarly, they were 6.3% and 12.4% on the Ag-HA and HA coatings at 7 days. At 14 days they were 20.6% and 39.4% on the Ag-HA and HA coatings, respectively. These results demonstrate that BCRs on the Ag-HA coating were significantly lower than those on the HA coating (Fig. 2). Discussion. The Ag-HA coating continuously showed the inhibiting ability for biofilm formation under flow condition for 14 days. Ag ions inhibited the biofilm formation on the Ag-HA coating by killing adherent bacteria in the vicinity of the surface, although the release rate of Ag ions was high until 24h after immersion and decreased thereafter. The Ag-HA coating would be expected to contribute to reduction of implant-related biofilm infection

Introduction. The use of antibiotic-loaded polymethylmethacrylate bone-cement spacers during two-stage exchange procedures is the standard in the treatment of patients with delayed prosthetic joint infection. The real antimicrobial activity of these spacers is unclear because the adherence of bacteria to cement might result in clinical recurrence of infection. The purpose of the study is to evaluate the in vitro formation of Pseudomonas Aeruginosa (PA) and Staphylococcus spp. biofilm on antibiotic-loaded bone cement. Materials and methods. Cement disks (diameter = 6 mm) impregnated with gentamicin and colistin were submerged in bacterial suspensions of Methicillin-resistant Staphylococcus Aureus(MRSA), Staphylococcus epidermidis (SE), and PA. Negative controls (specimen disks without antibiotic) were similarly prepared. Biofilm formation was visualized by confocal scanning laser microscopy (CSLM), after staining the discs with the live/dead BacLight viability stain containing SYTO 9 dye and propidium iodide. Images from five randomly selected areas were acquired for each disc. Sequential optical sections of 2 µm were collected in sequence along the z-axis over the complete thickness of the sample. The resulting stacks of images were analyzed, quantified and rendered into three-dimensional (3D). The biofilm thickness on antibiotic bone cement compared with the controls was automatically evaluated. Results. CSLM showed living bacteria and bacterial biofilm on the surface of all cement disks, either antibiotic-loaded or controls. Mean biofilm thickness on the controls was 29.6 µm for MRSA, 32.3 µm for SE, and 59.7 µm for PA. The 3D rendering showed decrease in the biofilm thickness for all bacterial strains on gentamicin- and colistin-impragnated cement disks as compared with the controls. The incorporation of gentamicin into cement resulted in a 54%, 74%, and 45% reduction in the bacterial biofilm thickness for MRSA, PA and SE, respectively. The use of colistin leaded to a 51 % reduction in the PA biofilm thickness. Conclusion. The bacterial viability and biofilm formation are reduced by adding antibiotics to bone cement but antibiotic-loaded bone cement does not completely inhibit the formation of an infectious biofilm in vitro

Aim. To investigate the local intra-operative concentration of gentamicin needed to prevent biofilm formation in a porcine model of implant-associated osteomyelitis. Method. In total 24 pigs were allocated to six groups. Group A (n=6) was inoculated with saline. Groups B (n=6), C (n=3), D (n=3), E (n=3) and F (n=4) were inoculated with 10 μL saline containing 10. 4. CFU of Staphylococcus aureus, however, different minimal inhibitory concentrations (MIC) of gentamicin were added to the inoculum of Groups C(160xMIC), D(1600xMIC), E(16000xMIC) and F(160000xMIC). The inoculums were injected into a pre-drilled implant cavity proximally in the right tibial bone. Following inoculation, a steel implant (2 × 15 mm) was placed in the cavity. The pigs were euthanized after five days. The implants were sonicated and swabs were taken from the implant cavity for microbiological evaluation. The peri-implant tissue was analyzed by histopathology including estimation of neutrophil infiltration. Results. The microbiological samples from Group A pigs were sterile. All implants and implant cavities of pigs inoculated with bacteria and bacteria + 160 or 1.600xMIC were positive for S. aureus. In each of the Groups E (16000xMIC) and F (160000xMIC) only one animal was found positive and 1/3 and 3/4 of the implants were sterile after sonication, respectively. All positive swabs were confirmed to be same spa-type as used for inoculation. By adding Groups C + D (<10000xMIC) and Groups E + F (>10000xMIC) a strong significant decrease (one-way ANOVA, P value = 0.001) of implant attached bacteria was only seen between the high MIC values and Group B (bacteria only). The histological examination demonstrated that 1600, 16000 and 160000 × MIC resulted in a peri-implant tissue reaction, including neutrophil estimation, comparable to saline inoculated animals. Patho-morphologically, it was not possible to distinguish between pigs inoculated with bacteria and bacteria + 160xMIC as both groups had a strong inflammatory response and an equal estimation of neutrophils. Discussion. The antibiotic susceptibility for prevention of an in vivo biofilm infection is influenced by body fluids, host immune response, extracellular host proteins like fibrin, tissue necrosis and development of an anaerobic environment. With the present in-vivo setup, we have demonstrated that local intra-operative gentamicin might be given in concentrations of more than 10000 times the MIC value in order to prevent biofilm formation by planktonic bacteria. Our study supports that biofilm susceptibility testing performed in-vitro is yet still unreliable for prediction of prophylactic and therapeutic success

Introduction:. Periprosthetic infections that accompany the use of total joint replacement devices cause unwanted and catastrophic outcomes for patients and clinicians. These infections become particularly problematic in the event that bacterial biofilms form on an implant surface. Previous reports have suggested that the addition of Vitamin E to ultra-high-molecular-weight polyethylene (UHMWPE) may prevent the adhesion of bacteria to its surface and thus reduce the risk of biofilm formation and subsequent infection. 1–3. In this study, Vitamin E was blended with two types of UHMWPE material. It was hypothesized that the Vitamin E blended UHMWPE would resist the adhesion and formation of clinically relevant methicillin-resistant Staphylococcus aureus (MRSA) biofilms. Methods and Materials:. Five sample types were manufactured, machined and sterilized (Table 1). To determine if MRSA biofilms would be reduced or prevented on the surface of the Vitamin E (VE) loaded samples (HXL VE 150 kGy and HXL VE 75 kGy) in comparison to the other three clinically relevant material types, each was tested for biofilm formation using a flow cell system. 4. Direct Bacterial Quantification – An n = 7 samples of each material type were placed individually into a chamber of the flow cell. A solution of 10% modified brain heart infusion (BHI) broth containing 10. 5. MRSA cells/mL was flowed through each chamber. Using previously established protocols,. 4–7. after 48 hours of growth, each sample was removed, and the number of colony forming units (CFU) determined using a 10-fold dilution series. SEM Imaging – Using the same protocol as above, after the 48-hour incubation period, an n = 7 of each material type were fixed in 2.5% glutaraldehyde, dehydrated in ascending concentrations of ethanol, coated with carbon and imaged using scanning electron microscopy (SEM). Results:. Results indicated that the Vitamin E blended materials did not resist the attachment/formation of MRSA biofilms to any greater degree than the other three material types. All materials had greater than 10. 7. CFU/cm. 2. (Figure 1). SEM images corroborated with the quantification data (Figure 2). Discussion:. In contrast to previously published results,. 1–3. these data indicated that Vitamin E blended UHMWPE may not have the ability to prevent biofilm formation of a clinical MRSA isolate from occurring

Introduction. According to the Australian registry 2014, periprosthetic joint infection (PJI) is the fourth important reason for revision of a primary total hip arthroplasty (THA). PJI is frequently caused by commensal strains of the skin such as Staphylococcus aureus or Staphylococcus epidermis. Deep infection is depending on many factors, such as implant surface chemical and physical behaviour, device design, host site, surgery and host response. Nevertheless, a lack of knowledge is seen concerning the specific effects of different surfaces on the biological response of different biomaterials. In addition, it is difficult to discriminate the material chemico-physical properties by the topological features, such as surface roughness. Indeed, it has been widely demonstrated that surface composition, electric charge, wettability and roughness of implant surfaces have a strong influence on their interactions with biological fluids and tissues. Therefore, also bearing surface properties can influence the incidence of PJI, just shown recently. Objectives. To verify the capability of ceramic bearings to reduce bacteria biofilm adhesion by means of their surface chemico-physical properties. Methods. The surface chemico-physical properties of the most common materials in THA as monolithic alumina, zirconia platelet toughened alumina (ZPTA), zirconia (TZP), titanium alloy (Ti6Al4V), stainless-steel and cobalt alloy (Co28Cr6Mo) were compared. All materials were characterized using x-ray photoelectron spectroscopy (XPS), fourier transform spectroscopy (FTIR), x-ray diffraction (XRD) and zeta-potential. Additionaly wettability by contact angle measurement with various media as simulated body fluid (SBF), bacterial broth, cell culture media and fetal bovine serum (FBS) was determined. Furthermore, the surface protein adsorption amount was evaluated by bicinchoninic acid (BCA) assay analysis using FBS as protein source. Selective protein adsorption was also evaluated by electroforetic technique. The specimens' surface anti-bacterial adhesion activity was evaluated by Staphylococcus aureus biofilm formation after 24h by colonies forming units count. Cytocompatibility was assessed using human primary osteoblasts cell culture and MTT assay. Results. The surface of all tested materials was found to be electronegative at physiological pH by means of zeta-potential measurement. Nevertheless, monolithic alumina and ZPTA have the isolectric point at lower pHs and adsorbed a larger amount of proteins (albumin and fibronectin) in comparison with metal surfaces. Such feature might be correlated with bacteria biofilm growth, since the ceramic surfaces were also less colonized by Staphylococcus aureus in comparison to metal surfaces (p<0.005) while they maintained the ability to promote osteoblasts adhesion and proliferation. The above results were confirmed by XPS technique where the ceramic surfaces had less hydroxyl groups and consequently were less prone to adhere with biological species as the bacteria. No correlation was observed using the FTIR and XRD surface characterization techniques. Conclusions. The ceramic bearing surfaces were found to reduce the bacteria biofilm adhesion, because of their surface chemico-physical properties

Background. The main reasons for hip prosthesis failure are aseptic loosening and periprosthetic joint infection (PJI). The real frequency of PJI is probably largely underestimated because of non-standardized definition criteria, diagnostic procedure, treatment algorithm and other confounders. Therefore, data from joint registries are not reflecting the frequency of PJI and can be misleading; particularly low-grade PJI can be frequently misdiagnosed as aseptic failure. Therefore, prospective clinical studies with standardized protocol, comprehensive diagnostic procedure and sufficient follow-up should be performed. Sonication of explanted prosthesis is highly sensitive for detection of biofilms on prosthetic surface and allows quantitative analysis of biofilm formation. We hypothesize that by using sonication, ceramic components (BIOLOX®delta, BIOLOX®forte) will show higher resistance against biofilm adhesion compared to polyethylene (PE) and metal (CoCrMo). Methods. In this prospective multicentre study (level of evidence: Ia), we included all consecutive adults ≥18 years of age, who underwent explantation of the hip prosthesis for infection or aseptic reason. Excluded were patients in whom part of the prosthetic components were retained. A standardized and comprehensive diagnostic algorithm was applied, including sonication of all removed prosthetic components for qualitative and quantitative microbiological analysis (ultrasound bath 40 kHz, 1 W/cm2, 1 min). Individual components (metal, PE, ceramic) were separately placed in sterile boxes for investigation. All patients were simultaneously included in the European Prosthetic joint infection cohort (EPJIC, . www.epjic.org. ) to ensure long-term follow-up. Results. Up to date, 79 patients were included, of whom 47 (60%) were diagnosed with aseptic failure and 32 (40%) with PJI. Mean age was 73 years (27–87 years), 32 (41%) were males. Table 1 summarizes the demographic characteristics. In 32 patients with PJI, most frequently isolated organisms were coagulase-negative staphylococci (n=12, 38%), Staphylococcus aureus (n=7, 22%) and Propionibacterium acnes (n=4, 13%), followed by enterococci (n=2; 6%) and gram-negative bacilli (n=2; 6%); 2 infections (6%) were polymicrobial and 3 were culture-negative (9%). Table 2 summarizes the microbiological results from sonication of removed components. Causative microorganism could be detected in sonication fluid from polyethylene in 100%, from metal in 92% and from ceramic in 69%. Significantly lower bacterial counts expressed as colony-forming units (CFU) were detected in sonication fluid from ceramic components (230 CFU/ml) than from PE (6’250 CFU/ml) and metal components (5’870 CFU / ml) (p < 0.01). Conclusions. These first results support the hypothesis that significantly less biofilm biomass is formed on ceramic surface, compared to PE and metal surfaces, potentially indicating higher ceramic “resistance” against bacterial adhesion. These findings should be confirmed with non-microbiological investigation such as imaging (fluorescent in situ hybridization, confocal laser scanning or electron microscopy). Furthermore, in 6 of 32 patients (19%) with PJI, an aseptic loosening was preoperatively suspected. Infection was found only by systematic application of an optimized diagnostic method, particularly sonication of the removed implant. Final study results are expected to be available by the end of 2016

Aim. Quadrupled hamstring anterior cruciate ligament plasties (4xHp) have been described as having a higher risk of infection than bone patellar tendon bone plasties (BPTBp). There are 2 theories that might explain this phenomenon. One is the presence of sutures in a 4xHp that could act as a foreign body, The other is the more complex preparation of a 4xHp that might lead to higher contamination rates during the process. The objective of the present study was to evaluate the formation of biofilm in these plasties and to compare it between a 4xHp and a BPTBp. The hypothesis was that the presence of sutures in 4xHp would increase the amount of biofilm present in them in comparison to BPTBp. Method. A descriptive in vitro study was conducted. One 4xHp and one BPTBp were prepared. They were subsequently divided into 8 fragments. Three of them were reserved for negative control, and the rest were contaminated with a strain of S. Epidermidis (ATCC 35984) 10–5. Finally, a quantitative analysis was carried out by means of microcalorimetry and sonication with plating. Additionally, a qualitative analysis was carried out by means of electron microscopy. Results. In isothermal microcalorimetry, both contaminated plasties showed the same growth dynamics with a population peak (200uW) at 8h. No significant differences were found between the bacterial growth profiles of 4xHp and BPTBp. The product of sonication was plated and the number of colony forming units per milliliter (CFU/ml) was counted at 24 hours. No significant differences were detected between the 4×Hp (mean +/− sem = 3,5×107 +/− 3450000) and the BPTBp (4,6 ×107 +/− 1,455e+7). With a p value of 0.6667, there were no differences of significance (Mann-Whitney test). In the samples analyzed with electron microscopy, no specific biofilm growth pattern was identified upon comparing BPTBp with 4xHp. Conclusions. There were no significant differences at either the quantitative or qualitative level when comparing bacterial growth in BPTBp and 4xHp. Therefore, the presence of sutures in 4xHp cannot be established as a predisposing factor to higher infection rates. These findings may be justified in the sense that the plasties themselves already behave like foreign bodies. Therefore, the presence of sutures does not increase the possibility of biofilm forming on their surface

Gram-negative prosthetic joint infections (GN-PJI) present unique challenges in management due to their distinct pathogenesis of biofilm formation on implant surfaces. To date, there are no animal models that can fully recapitulate how a biofilm is challenged in vivo in the setting of GN-PJI. The purpose of this study is to establish a clinically representative GN-PJI in vivo model that can reliably depict biofilm formation on titanium implant surface. We hypothesized that the biofilm formation on the implant surface would affect the ability of the implant to be osseointegrated. The model was developed using a 3D-printed, medical-grade titanium (Ti-6Al-4V), monoblock, cementless hemiarthroplasty hip implant. This implant was used to replace the femoral head of a Sprague-Dawley rat using a posterior surgical approach. To induce PJI, two bioluminescent Pseudomonas aeruginosa (PA) strains were utilized: a reference strain (PA14-lux) and a mutant strain that is defective in biofilm formation (DflgK-lux). PJI development and biofilm formation was quantitatively assessed in vivo using the in vivo imaging system (IVIS), and in vitro using the viable colony count of the bacterial load on implant surface. Magnetic Resonance Imaging (MRI) was acquired to assess the involvement of periprosthetic tissue in vivo, and the field emission scanning electron microscopy (FE-SEM) of the explanted implants was used to visualize the biofilm formation at the bone-implant interface. The implant stability, as an outcome, was directly assessed by quantifying the osseointegration using microCT scans of the extracted femurs with retained implants in vitro, and indirectly assessed by identifying the gait pattern changes using DigiGaitTM system in vivo. A localized prosthetic infection was reliably established within the hip joint and was followed by IVIS in real-time. There was a quantitative and qualitative difference in the bacterial load and biofilm formation between PA14 and DflgK. This difference in the ability to persist in the model between the two strains was reflected on the gait pattern and implant osseointegration. We developed a novel uncemented hip hemiarthroplasty GN-PJI rat model. This model is clinically representative since animals can bear weight on the implant. PJI was detected by various modalities. In addition, biofilm formation correlated with implant function and stability. In conclusion, the proposed in vivo GN-PJI model will allow for more reliable testing of novel biofilm-targeting therapetics

Introduction. Gram-negative prosthetic joint infections (GN-PJI) present unique challenges in management due to their distinct pathogenesis of biofilm formation on implant surfaces. The purpose of this study is to establish a clinically representative GN-PJI model that can reliably recapitulate biofilm formation on titanium implant surface in vivo. We hypothesized that biofilm formation on an implant surface will affect its ability to osseointegrate. Methods. The model was developed using 3D-printed titanium hip implants, to replace the femoral head of male Sprague-Dawley rats. GN-PJI was induced using two bioluminescent Pseudomonas aeruginosa strains: a reference strain (PA14-lux) and a mutant biofilm-defective strain (ΔflgK-lux). Infection was monitored in real-time using the in vivo imaging system (IVIS) and Magnetic Resonance Imaging (MRI). Bacterial loads on implant surface and in periprosthetic tissues were quantified utilizing viable-colony-count. Field-emission scanning-electron-microscopy of the explanted implants was used to visualize the biofilm formation at the bone-implant-interface. The implant stability, as an outcome, was directly assessed by quantifying the osseointegration in vitro using microCT scan, and indirectly assessed by identifying the gait pattern changes using DigiGait. TM. system in vivo. Results. Localized infection was established within the hip joint and was followed by IVIS in real-time. There was a quantitative and qualitative difference in the bacterial load and biofilm formation between PA14-lux and ΔflgK-lux. This difference in the ability to persist in the model between the two strains was reflected in the gait pattern and implant osseointegration. Conclusions. We developed a novel uncemented hip hemiarthroplasty, GN-PJI rat model. To date, the proposed in vivo biofilm-based model is the most clinically representative for GN-PJI since animals can bear weight on the implant and poor osseointegration correlates with biofilm formation. In addition, localized PJI was detected by various modalities. Clinical Relevance. The proposed in vivo GN-PJI model will allow for more reliable testing of novel biofilm-targeting therapeutics

Aim. A novel anti-infective biopolymer implant coating was developed to prevent bacterial biofilm formation and allow on-demand burst release of anti-infective silver (Ag) into the surrounding of the implant at any time after surgery via focused high-energy extracorporeal shock waves (fhESW). Method. A semi-crystalline Poly-L-lactic acid (PLLA) was loaded with homogeneously dissolved silver (Ag) applied onto Ti6Al4V discs. A fibroblast WST-1 assay was performed to ensure adequate biocompatibility of the Ag concentration at 6%. The prevention of early biofilm formation was investigated in a biofilm model with Staphylococcus epidermidis RP62A after incubation for 24 hours via quantitative bacteriology. In addition, the effect of released Ag after fhESW (Storz DUOLITH SD1: 4000 impulses, 1,24 mJ/mm. 2. , 3Hz, 162J) was assessed via optical density of bacterial cultures (Escherichia coli TG1, Staphylococcus epidermidis RP62A, Staphylococcus aureus 6850) and compared to an established electroplated silver coating. The amount of released Ag after the application of different intensities of fhESW was measured and compared to a control group without fhESW via graphite furnace atomic absorption spectrometry (GF-AAS), scanning electron microscopy (SEM) and energy dispersive X-ray spectroscopy (EDS). Results. The coating with 6% Ag reduced Staphylococcus epidermidis biofilm formation by 99.7% (mean±SD: 2.1×10^5 ± 3,9×10^5 CFU/µL) compared to uncoated controls (6.8×10^7 ± 4.9×10^7 CFU/µL); (p=0.0001). After applying fhESW the commercially available electroplated silver coating did not prevent the growth of all tested bacterial strains. Bacterial growth is delayed with 4% Ag and completely inhibited with 6% Ag in the novel coating, except for a small increase of S. aureus after 17 hours. SEM and EDS confirmed a local disruption of the coating after fhESW. Conclusions. This novel anti-infective implant coating has the potential to prevent bacterial biofilm formation. The on-demand burst release of silver via fhESW could be an adjunctive in the treatment of implant related infection and is of particular interest in the concept of single stage revision surgery

Aim. Prosthetic joint infections pose a major clinical challenge. Developing novel material surface technologies for orthopedic implants that prevent bacterial adhesion and biofilm formation is essential. Antimicrobial coatings applicable to articulating implant surfaces are limited, due to the articulation mechanics inducing wear, coating degradation, and toxic particle release. Noble metals are known for their antimicrobial activity and high mechanical strength and could be a viable coating alternative for orthopaedic implants [1]. In this study, the potential of thin platinum-based metal alloy coatings was developed, characterized, and tested on cytotoxicity and antibacterial properties. Method. Three platinum-based metal alloy coatings were sputter-coated on medical-grade polished titanium discs. The coatings were characterized using optical topography and scanning electron microscopy with energy dispersive spectroscopy (SEM/EDS). Ion release was measured using inductively coupled plasma optical emission spectrometry (ICP-OES). Cytotoxicity was tested according to ISO10993-5 using mouse fibroblasts (cell lines L929 and 3T3). Antibacterial surface activity, bacterial adhesion, bacterial proliferation, and biofilm formation were tested with gram-positive Staphylococcus aureus ATCC 25923 and gram-negative Escherichia coli ATCC 25922. Colony forming unit (CFU) counts, live-dead fluorescence staining, and SEM-EDS images were used to assess antibacterial activity. Results. Three different platinum-based metal alloys consisting of platinum-iridium, platinum-copper, and platinum-zirconium. The coatings were found 80 nm thick, smooth (roughness average < 60 nm), and non-toxic. The platinum-copper coating showed a CFU reduction larger than one logarithm in adherent bacteria compared to uncoated titanium. The other coatings showed a smaller reduction. This data was confirmed by SEM and live-dead fluorescence images, and accordingly, ICP-OES measurements showed low levels of metal ion release from the coatings. Conclusions. The platinum-copper coating showed low anti-adhesion properties, even with extremely low metal ions released. These platinum-based metal alloy coatings cannot be classified as antimicrobial yet. Further optimization of the coating composition to induce a higher ion release based on the galvanic principle is required and copper looks most promising as the antimicrobial compound of choice. Acknowledgments. This publication is supported by the DARTBAC project (with project number NWA.1292.19.354) of the research program NWA-ORC which is (partly) financed by the Dutch Research Council (NWO); and the AMBITION project (with project number NSP20–1-302), co-funded by the PPP Allowance made available by Health-Holland, Top Sector Life Sciences & Health to ReumaNederland

Aim. Galleria mellonella larvae is a well-known insect infection model that has been used to test the virulence of bacterial and fungal strains as well as for the high throughput screening of antimicrobial compounds against infections. Recently, we have developed insect infection model G. mellonella larvae to study implant associated biofilm infections using small K-wire as implant material. Here, we aimed to further expand the use of G. mellonella to test other materials such as bone cement with combination of gentamicin to treat implant-associated infections. Method. The poly methyl methacrylate (PMMA) with and without gentamicin and liquid methyl methacrylate (MMA) were kindly provided by Heraeus Medical GmbH, Wehrheim. To make the bone cement implants as cubes, Teflon plate (Karl Lettenbauer, Erlangen) with specified well size was used. The Radiopaque polymer and monomer were mixed well in a bowl, applied over on to the Teflon plate and pressed with spatula to form fine and uniform cubes. After polymerization, the bone cement implants were taken out of the Teflon well plate with the help of pin. For the infection process, bone cement cubes were pre-incubated with S. aureus EDCC 5055 culture at 5×10. 6. CFU/ml for 30 min at 150 rpm shaking conditions. Later, these implants were washed with 10ml PBS and implanted in the larvae as mentioned. Survival of the larvae were observed at 37°C in an incubator. To analyze the susceptibility of the bacterial infections towards gentamicin, survival of the larvae compared with control group implanted only with bone cement. The effect of gentamicin was also measured in terms of S. aureus load in larvae on 2. nd. day. SEM analysis was performed to see the effect of gentamicin on biofilm formation on bone cement. Results. Our experiments established the G. mellonella as an excellent model to screen bone cement with antimicrobial compounds against bacterial infections. The gentamicin bone cement samples showed excellent S. aureus bacterial load reduction after the implantation in G. mellonella model. The bone cement with gentamicin showed better survival of larvae infected with S. aureus compared to control. Finally, the gentamicin also affected the biofilm formation on the bone cement surface with S. aureus. Conclusions. Thus, our work showed G. mellonella is a rapid, cheap economical pre-clinical model to study the bone cement associate bacterial infections as well as screening of the various antimicrobial compounds

Aim. Biofilm-related infections represent a recurrent problem in the orthopaedic setting. In recent years, great interest was directed towards the identification of novel molecules capable to interfere with pathogens adhesion and biofilm formation on implant surfaces. In this study, two stable forms of α-tocopherol, the hydrophobic acetate ester and the water-soluble phosphate ester, were tested in vitro as coating for titanium prostheses. Method. Antimicrobial activity against microorganisms responsible of prosthetic and joints infections was assessed by broth microdilution method. In addition, α-tocopherol esters were evaluated for both their ability to hamper bacterial adhesion and biofilm formation on sandblasted titanium surfaces. Results. Only α-tocopheryl phosphate displayed antimicrobial activity against the tested strains. Both esters were able to significantly interfere with bacterial adhesion and to prevent biofilm formation, especially by Staphylococcus aureus and Staphylococcus epidermidis. The activity of α-tocopheryl phosphate was greater than that of α-tocopheryl acetate. Alterations at membrane levels have been reported in literature1 and may be likely responsible for the interference on bacterial adhesion and biofilm formation shown by α-tocopherol esters. Conclusions. Although further studies are needed to better investigate the mechanisms of action and the spectrum of activity of α-tocopherol esters, these characteristics, together with the positive effect on wound healing and immune response, make these molecules promising candidate for coating in order to prevent implant-associated infections

Aim. To evaluate the ability of different combinations of antibiotic loaded cement to inhibit bacteria growth and biofilm formation. Method. Cement beads were aseptically prepared using Palacos R (plain 40g PMMA cement) or Palacos R+G (40g PMMA cement containing industrially added 0.5g of gentamicin), with or without supplementary antibiotics as follows: Palacos R; Palacos R+G; Palacos R plus 1g / 2g daptomycin; Palacos R+G plus 1g / 2g of daptomycin; Palacos R plus 1g / 2g vancomcyin; and Palacos R+G plus 1g / 2g vancomycin. After production, each antibiotic loaded acrylic cement (ALAC) combination was allocated into two groups (group 1 and 2). The group 2 cement beads were initially eluted in broth at 37. o. C for 72hours then transferred to fresh broth containing a known concentration of bacteria. The group 1 samples were not eluted but directly immerse in culture broth containing bacteria. All samples were thereafter incubated at 37. o. C for 24 hours. After incubation, group 1 samples were visually assessed for bacterial growth, while for the group 2 samples, biofilm formation were quantified using ultrasonication and viable bacteria counting technique. Three proficient biofilm forming Staphylococcus epidermidis bacterial strains (1457, 1585-RA and 5179-R1) were used for all experiments and the bacteria counts were expressed as colony forming units / ml (CFU/ml). Results. In the group 1 samples, all the ALAC combinations were able to inhibit growth of all the three biofilm bacteria strains assessed except the gentamicin only samples in which biofilm growth were observed within 24hours. Meanwhile, in group 2, bacterial growth and biofilm formation by all three bacterial strains were observed on all the ALAC combinations, with the least biofilm formation being on the Palacos R+G plus 2g daptomycin combinations (mean CFU/ml: 1.04E +06) and the greatest on the gentamicin only cement (mean CFU/ml: 2.3E +07). Conclusions. Our study demonstrates that the highest antimicrobial activity of ALAC is seen in the first 24 hours. However, after 72 hours of antibiotic release, fresh bacterial exposure in fresh broth resulted in varying degrees of biofilm colonisation of all ALAC surfaces. Nonetheless, the overall biofilm formation was least on the gentamicin / daptomycin combinations and the results were statistically significant when compared to plain cement (p < 0.05, two tail t-test)

Aim. Bacterial biofilms play a key role in prosthetic infection (PI) pathogenesis. Establishment of the biofilm phenotype confers the bacteria with significant tolerance to systemic antibiotics and the host immune system meaning thorough debridement and prosthesis removal often remain the only possible course of treatment. Protection of the prosthesis and dead-space management may be achieved through the use of antibiotic loaded cements and beads to release high concentrations of antibiotics at the surgical site. The antibacterial and antibiofilm efficacy of these materials is poorly understood in the context of mixed species models, such as are often encountered clinically. Methods. A P. aeruginosa and S. aureus in vitro co-culture biofilm model was grown using 1/5th BHI supplemented with 20 µM hemin. The ability of beads made from a synthetic calcium sulfate (CaSO4) loaded with vancomycin, tobramycin and vancomycin & tobramycin in combination to prevent biofilm formation and kill established co-culture biofilms were assessed using viable cell counts and confocal scanning laser microscopy (CSLM) over a 7 day time course. To assay for genetic changes to the individual species as a result of their presence together within a biofilm, mutation rates were measured using fluctuation analysis following growth as planktonic and biofilm cultures, alone or in co-culture. Mutants were determined based on their ability to grow on agar plates containing an inhibitory concentration of rifampicin. Mutation rates were calculated using the Ma-Sandri-Sarkar Maximum Likelihood Estimator and 94% confidence intervals compared for significance. Results. Mixed species biofilms displayed differential sensitivity to vancomycin alone and tobramycin alone CaSO4-loaded beads relative to single species biofilms. Preliminary data suggests 10- and 100-fold increase in mutation rates of P. aeruginosa and S. aureus, respectively, when in a co-culture relative to monospecies biofilm which, while further work is needed, may directly or indirectly contribute to the differing antibiotic sensitivities observed. A broad-spectrum intervention of CaSO4-loaded vancomycin & tobramycin beads was able to prevent bacterial colonisation and attenuate P. aeruginosa and S. aureus mixed species biofilm formation for multiple days. Conclusions. Synthetic antibiotic-loaded CS beads, with a broad-spectrum antibiotic combination, have potential to reduce or eliminate mixed species biofilm formation on implant material by providing locally high concentrations over sufficient time periods to aid in the management of PIs. * Stimulan, Biocomposites Ltd

Aim. Implant infections caused by Staphylococcus aureus are difficult to treat due to biofilm formation, which complicates surgical and antibiotic treatment. Herewith we introduce an alternative approach using monoclonal antibodies (mAbs) targeting S. aureus and provide the biodistribution and specificity in a mouse implant infection model. Methods. 4497-IgG1targeting S. aureus Wall Teichoic Acid was labeled to Indium-111 using “CHXA” as a chelator. SPECT-CT scans were performed at 24, 72 and 120 hours after administration in Balb/cAnNCrl mice with a subcutaneous implant pre-colonized with biofilm of S. aureus. Biodistribution over the various organs of this labelled antibody was visualized and quantified using SPECT-CT imaging and compared to uptake at the target tissue with implant infection. Results. Uptake of the . 111. In-4497 mAbs (half-life 59 hours) at the infected implant gradually increased from 8.34%ID/g at 24 hours to 9.22%ID/g at 120 hours. Uptake at the heart/blood pool decreased over time from 11.60 to 7.58%ID/g whereas the uptake in other organs decreased from 7.26 to less than 4.66%ID/g at 120 hours. Conclusion. 111. In-4497 mAbs was found to specifically detect S. aureus and its biofilm with excellent and prolonged accumulation at the colonized implant site. Therefore, it holds great promise as a drug delivery system for diagnostic and bactericidal treatment of biofilm. However, high activity in the blood pool must be considered as it could pose a risk to healthy tissue

Periprosthetic joint infection (PJI) in geriatric and/or multimorbid patients is an enormous challenge for orthopaedic surgeons. Revision procedures have also been demonstrated to expose patients to higher infection risks. Prior patient stratification according to presumed infection risks, followed by a more potent local antibiotic prophylaxis protocol with selective use of DALBC, is an interesting strategy to decrease the burden of PJI in high risk patients. The PubMed & EMBASE databases were screened for publications pertaining to the utilization of DALBC in cement for infection prophylaxis & prosthesis fixation. 6 preclinical & 7 clinical studies were identified which met the inclusion criteria and were stratified by level of clinical evidence. Only those studies were considered which compared the PJI outcome in the DALBC vs the SALBC group. (1). DALBC have been shown to exert a much stronger and longer lasting inhibition of biofilm formation on many PJI relevant bacteria (gram-positive and gram-negative pathogens) than single gentamicin-only containing cements. (2). DALBC use (COPAL G+C) in the intervention arm of 7 clinical studies has led to a significant reduction of PJI cases in a) cemented hemiarthroplasty procedures (3 studies, evidence level I and III), in b) cemented septic revision surgeries (2 studies, evidence level III), in c) cemented aseptic knee revisions (1 study, evidence level III) and in d) cemented primary arthroplasties in multi-morbid patients (1 study, evidence level III-IV). These benefits were not associated with more systemic side effects or a higher prevalence of broad antimicrobial resistancies. Use of DALBC is likely to be more effective in preventing PJI in high risk patients. The preliminar findings so far may encourage clinicians to consolidate this hypothesis on a wider clinical range