Antimicrobial technology in orthopedic and spinal implants

Eltorai, Adam E.M.; Haglin, Jack M.; Perera, Sudheesha; Brea, Bielinsky A; Ruttiman, Roy; Garcia, Dioscaris; Born, Christopher T.; Daniels, Alan H.

doi:10.5312/wjo.v7.i6.361

Cited by 37 publications

(33 citation statements)

References 75 publications

(87 reference statements)

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“…Firstly, Ti substrates coated with continuous Ag thin films were tested as a reference for Ag‐based antimicrobial implant coatings . The Ag content of as‐prepared Ag thin film coated samples (black line, Ti−Ag 0 h) was determined by linear sweep voltammetry from −0.1 V to +0.4 V vs Ag/AgCl in 1 M HCl, using a scan rate of 25 mV/s (Figure a).…”

Section: Resultsmentioning

confidence: 99%

A Unified Interdisciplinary Approach to Design Antibacterial Coatings for Fast Silver Release

et al. 2017

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The increasing number of surgical treatments performed per year requires novel approaches to inhibit implant‐associated infections, caused by multi‐antibiotic resistant bacteria. Silver ions (Ag+) are known for their effective antimicrobial activity. Therefore, a system that efficiently and locally releases the minimum required amount of Ag+ directly after the surgical treatment is in high demand. Herein we study electrochemically, microbiologically, microscopically and spectroscopically sacrificial Ag anode coatings for antibacterial implant applications. It is found that Ag dot arrays deposited on noble metals (Pd, Ir) release Ag+ much faster than continuous Ag thin films. The Ag+ release qualitatively scales with the difference of standard potentials between Ag and the noble metal. Furthermore, with higher numbers of Ag dots, the total amount of released Ag+ increases, while the release efficiency declines. Notably, an efficient killing of Staphylococcus aureus bacteria was seen for coatings containing as little as 23 ng of Ag per mm2. Thus, the use of sacrificial Ag anodes as highly efficient antibacterial coating materials is evaluated.

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Section: Resultsmentioning

confidence: 99%

A Unified Interdisciplinary Approach to Design Antibacterial Coatings for Fast Silver Release

et al. 2017

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“…Thus, the higher infection rates associated with biomaterials when compared to common surgical site infections is explained by the increased susceptibility to infection in the presence of a biomaterial 39 . In addition to the impaired HID, certain biomaterials and/or superficial coatings can physically, chemically and biologically support and enhance microbial growth [40][41][42][43][44] . Coatings and biomaterial surfaces often incorporate superficial pores in order to encourage ingrowth of host tissue into the implant thus mediating successful integration 45,46 .…”

Section: Pathogenesis Of Infections Associated With Implantsmentioning

confidence: 99%

“…Unfortunately, these pores constitute superficial niches that physically protect microbes from phagocytic cells. Bio-resorbable biomaterials can locally dissipate nutrients over time that may be used by bacteria to support their own growth and proliferation [40][41][42][43] . Moreover, metallic ions released from certain metals, comprised within biomaterials and coatings, have been shown to chemically enhance microbial function by altering internal metabolic processes for several microbial species 44 .…”

Section: Pathogenesis Of Infections Associated With Implantsmentioning

confidence: 99%

Biofilm formation in total hip arthroplasty: prevention and treatment

et al. 2016

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“…4 Manufacturers have been trying to reduce endoprosthetic infection rates with antimicrobial implant surfaces like antibiotic-based, antiseptic, photoactive-based or silver coatings. [6][7][8] Antibiotic coatings have limited duration of drug elution and the risk of resistance, 9 while effective antiseptic coatings (chlorhexidine, chloroxylenol) also exhibit toxicity. 2,10 The nanostructured topography of the implants has also been tested in vitro for anti-bacterial properties, [11][12][13][14] whereby mesenchymal and embryonic stem cells were unable to grow on surfaces with particular TiO 2 nanotube dimen-sions 14 .…”

Section: Introductionmentioning

confidence: 99%

Infection risk analysis of 101 silver-coated endoprostheses

Mavčič¹,

Martinčič²,

Špiler³

et al. 2019

Mater. Tehnol.

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Our aim was to analyse the implant survival and infection rates of 101 consecutive silver-coated MUTARS® (= Modular Universal Tumour And Revision System) endoprostheses implanted at an independent orthopaedic tertiary hospital between April 1, 2011 and December 31, 2018 and to compare them with previous outcomes of the MUTARS® developmental hospitals. In addition, we tested the hypothesis that the infection-free survival rates of silver-coated implants depend on the patient's age, gender, pre-operative diagnoses and anatomical localization of the reconstruction. The cohort included 47 sarcoma resections, 29 revision arthroplasties, 20 metastatic resections, 3 benign bone tumours and 2 primary arthroplasties. Endoprosthesis was located in the distal femur (38 patients), proximal femur (29 patients), proximal humerus (12 patients), proximal tibia (10 patients), pelvis (6 patients), total femur (5 patients) and distal humerus (1 patient). The mean age at implantation was 49 (range 11-86) years and the mean follow-up 3.2 (range 0.1-7.7) years. Twenty-four patients required at least one subsequent revision operation and 15 endoprostheses had to be partially/totally removed. Patients' age was an independent risk factor for postoperative infection regardless of other confounding factors (hazard ratio 1.05 for each year; p = 0.02). With the overall postoperative infection rate 12 % (4 % reinfection + 8 % newly acquired) and cumulative partial/total implant removal rate 25 % after 5 years, complications were comparable to the previous series of the MUTARS® developmental hospitals with high variability between preoperative diagnoses and anatomical localizations. Silver-coated implants show a consistent trend of preventing infections in high-risk body regions and enabling more successful treatment should infection occur, but 10-15 years of clinical follow-up is required for further assessment.

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Antimicrobial technology in orthopedic and spinal implants

Cited by 37 publications

References 75 publications

A Unified Interdisciplinary Approach to Design Antibacterial Coatings for Fast Silver Release

A Unified Interdisciplinary Approach to Design Antibacterial Coatings for Fast Silver Release

Biofilm formation in total hip arthroplasty: prevention and treatment

Infection risk analysis of 101 silver-coated endoprostheses

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