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Orthopaedic Proceedings
Vol. 100-B, Issue SUPP_14 | Pages 122 - 122
1 Nov 2018
McFadden R Chan C Carson L Buchanan F
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With an ever-increasing aging population, total hip and knee arthroplasty is projected to increase by 137% and 601%, respectively, between the period; 2005–2030. Prosthetic Join Infection (PJI) occurs in approximately 2% of total joint replacements (TJRs) in the U.S. PJI is primarily caused by adherence of bacteria to the surface of the prosthesis, ultimately forming an irreversibly attached community of sessile bacteria, known as a biofilm, highly tolerant to antibiotic treatment. Often the only resolution if the ensuing chronic infection is surgical removal of the implant – at high cost for the patient (increased morbidity), and for healthcare resources. Strategies to prevent bacterial adherence have significant potential for medical impact. Laser surface treatment using an automated continuous wave (CW) fiber laser system has shown promise in producing anti-adherent and bactericidal surfaces. Work presented here aims to investigate the effect of this approach on orthopaedic metals as a proof of concept, specifically Ti-6Al-4V (kindly supplied by Stryker Orthopaedics, Limerick). A coupon was surface treated using a laser (MLS-4030; Micro Lasersystems BV, Driel). Samples were incubated in Müller Hinton Broth (MHB) inoculated with methicillin resistant Staphylococcus aureus (MRSA; ATCC 43300) for 24h before Live/Dead staining (BacLight™ solution; Molecular Probes) and inspection by fluorescence microscopy (GXM-L3201 LED; GX Optical). Images were analysed using ImageJ software (NIH) and a significant reduction (p > 0.05, n=24) in total biofilm coverage and Live/Dead ratio was observed between the laser treated and as received surfaces. This data demonstrates the anti-adherent, and indeed bactericidal, effect of Laser-surface treatment.


Orthopaedic Proceedings
Vol. 100-B, Issue SUPP_14 | Pages 62 - 62
1 Nov 2018
Geddes L Carson L Themistou E Buchanan F
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Research in orthopaedics is now moving away from permanent metallic implants, and looking towards the use of bioresorbable polymers (e.g. PLLA, PGA and related co-polymers) that, when implanted into the injured site, bioresorb as the tissue heals. However, reports of a delayed inflammatory reponse occurring in the late stages of polymer degradation has limited the wide scale use of these polymers. Few studies assess the long-term biocompatibility of these polymers and with an increasing market for bioresorbable materials it is anticipated that this will be a future issue. This work aims to develop a predictive tool that can be used to assess the delayed inflammatory response of poly(D,L-lactide-co-glycolide) (PDLGA) using in vitro tests. An elevated temperature accelerated test (47oC) was developed and utilitised to induce predetermined amounts of degradation in PDLGA. This was used to mimic a range of clinically relevant in vivo implantation times up to 5–6 months. All pre-degradion work was performed under sterile conditions, in PBS solution. At predetermined time intervals, indicators of late stage inflammation will be assessed using an MTT cytotoxicity assay, an inflammation antibody array and an ELISA analysis for inflammatory factors, with mouse L929 fibroblasts, RAW264.7 and primary BMDM macrophages. It is hypothosised that at the later degradation time intervals signs of inflammatory factors will be observed. The methodologies developed in this work can be applied to the optimisation of polymer degradation profiles to minimise late-stage inflammatory repsonse and identification of beneficial additives in this regard.