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A chlorhexidine-releasing epoxy-based coating on titanium implants prevents Staphylococcus aureus experimental biomaterial-associated infection. / Riool, M.; Dirks, A. J.; Jaspers, V. et al.

In: European cells & materials, Vol. 33, 2017, p. 143-157.

Research output: Contribution to journalArticleAcademicpeer-review

Harvard

Riool, M, Dirks, AJ, Jaspers, V, de Boer, L, Loontjens, TJ, van der Loos, CM, Florquin, S, Apachitei, I, Rijk, LN, Keul, HA & Zaat, SA 2017, 'A chlorhexidine-releasing epoxy-based coating on titanium implants prevents Staphylococcus aureus experimental biomaterial-associated infection', European cells & materials, vol. 33, pp. 143-157. https://doi.org/10.22203/eCM.v0033a11

APA

Riool, M., Dirks, A. J., Jaspers, V., de Boer, L., Loontjens, T. J., van der Loos, C. M., Florquin, S., Apachitei, I., Rijk, L. N., Keul, H. A., & Zaat, S. A. (2017). A chlorhexidine-releasing epoxy-based coating on titanium implants prevents Staphylococcus aureus experimental biomaterial-associated infection. European cells & materials, 33, 143-157. https://doi.org/10.22203/eCM.v0033a11

Vancouver

Riool M, Dirks AJ, Jaspers V, de Boer L, Loontjens TJ, van der Loos CM et al. A chlorhexidine-releasing epoxy-based coating on titanium implants prevents Staphylococcus aureus experimental biomaterial-associated infection. European cells & materials. 2017;33:143-157. doi: 10.22203/eCM.v0033a11

Author

Riool, M. ; Dirks, A. J. ; Jaspers, V. et al. / A chlorhexidine-releasing epoxy-based coating on titanium implants prevents Staphylococcus aureus experimental biomaterial-associated infection. In: European cells & materials. 2017 ; Vol. 33. pp. 143-157.

BibTeX

@article{b102add0bfef45ed8eecbd831095735a,
title = "A chlorhexidine-releasing epoxy-based coating on titanium implants prevents Staphylococcus aureus experimental biomaterial-associated infection",
abstract = "Prevention of biomaterial-associated infections (BAI) remains a challenging problem, in particular due to the increased risk of resistance development with the current antibiotic-based strategies. Metallic orthopaedic devices, such as non-cemented implants, are often inserted under high mechanical stress. These non-cemented implants cannot be protected by e.g. antibioticreleasing bone cement or other antimicrobial approaches, such as the use of bioactive glass. Therefore, in order to avoid abrasion during implantation procedures, we developed an antimicrobial coating with great mechanical stability for orthopaedic implants, to prevent Staphylococcus aureus BAI. We incorporated 5 and 10 wt % chlorhexidine in a novel mechanically stable epoxy-based coating, designated CHX5 and CHX10, respectively. The coatings displayed potent bactericidal activity in vitro against S. aureus, with over 80 % of the release (19 µg/cm2 for CHX5 and 41 µg/cm2 for CHX10) occurring within the first 24 h. In mice, the CHX10 coating significantly reduced the number of CFU (colony forming units), both on the implants and in the peri-implant tissues, 1 d after S. aureus challenge. The CHX10-coated implants were well-tolerated by the animals, with no signs of toxicity observed by histological analysis. Moreover, the coating significantly reduced the frequency of culture-positive tissues 1 d, and of culture-positive implants 1 and 4 d after challenge. In summary, the chlorhexidine-releasing mechanically stable epoxy-based CHX10 coating prevented implant colonisation and S. aureus BAI in mice and has good prospects for clinical development",
author = "M. Riool and Dirks, {A. J.} and V. Jaspers and {de Boer}, L. and Loontjens, {T. J.} and {van der Loos}, {C. M.} and S. Florquin and I. Apachitei and Rijk, {L. N.} and Keul, {H. A.} and Zaat, {S. A.}",
year = "2017",
doi = "10.22203/eCM.v0033a11",
language = "English",
volume = "33",
pages = "143--157",
journal = "European cells & materials",
issn = "1473-2262",
publisher = "Swiss Society for Biomaterials",

}

RIS

TY - JOUR

T1 - A chlorhexidine-releasing epoxy-based coating on titanium implants prevents Staphylococcus aureus experimental biomaterial-associated infection

AU - Riool, M.

AU - Dirks, A. J.

AU - Jaspers, V.

AU - de Boer, L.

AU - Loontjens, T. J.

AU - van der Loos, C. M.

AU - Florquin, S.

AU - Apachitei, I.

AU - Rijk, L. N.

AU - Keul, H. A.

AU - Zaat, S. A.

PY - 2017

Y1 - 2017

N2 - Prevention of biomaterial-associated infections (BAI) remains a challenging problem, in particular due to the increased risk of resistance development with the current antibiotic-based strategies. Metallic orthopaedic devices, such as non-cemented implants, are often inserted under high mechanical stress. These non-cemented implants cannot be protected by e.g. antibioticreleasing bone cement or other antimicrobial approaches, such as the use of bioactive glass. Therefore, in order to avoid abrasion during implantation procedures, we developed an antimicrobial coating with great mechanical stability for orthopaedic implants, to prevent Staphylococcus aureus BAI. We incorporated 5 and 10 wt % chlorhexidine in a novel mechanically stable epoxy-based coating, designated CHX5 and CHX10, respectively. The coatings displayed potent bactericidal activity in vitro against S. aureus, with over 80 % of the release (19 µg/cm2 for CHX5 and 41 µg/cm2 for CHX10) occurring within the first 24 h. In mice, the CHX10 coating significantly reduced the number of CFU (colony forming units), both on the implants and in the peri-implant tissues, 1 d after S. aureus challenge. The CHX10-coated implants were well-tolerated by the animals, with no signs of toxicity observed by histological analysis. Moreover, the coating significantly reduced the frequency of culture-positive tissues 1 d, and of culture-positive implants 1 and 4 d after challenge. In summary, the chlorhexidine-releasing mechanically stable epoxy-based CHX10 coating prevented implant colonisation and S. aureus BAI in mice and has good prospects for clinical development

AB - Prevention of biomaterial-associated infections (BAI) remains a challenging problem, in particular due to the increased risk of resistance development with the current antibiotic-based strategies. Metallic orthopaedic devices, such as non-cemented implants, are often inserted under high mechanical stress. These non-cemented implants cannot be protected by e.g. antibioticreleasing bone cement or other antimicrobial approaches, such as the use of bioactive glass. Therefore, in order to avoid abrasion during implantation procedures, we developed an antimicrobial coating with great mechanical stability for orthopaedic implants, to prevent Staphylococcus aureus BAI. We incorporated 5 and 10 wt % chlorhexidine in a novel mechanically stable epoxy-based coating, designated CHX5 and CHX10, respectively. The coatings displayed potent bactericidal activity in vitro against S. aureus, with over 80 % of the release (19 µg/cm2 for CHX5 and 41 µg/cm2 for CHX10) occurring within the first 24 h. In mice, the CHX10 coating significantly reduced the number of CFU (colony forming units), both on the implants and in the peri-implant tissues, 1 d after S. aureus challenge. The CHX10-coated implants were well-tolerated by the animals, with no signs of toxicity observed by histological analysis. Moreover, the coating significantly reduced the frequency of culture-positive tissues 1 d, and of culture-positive implants 1 and 4 d after challenge. In summary, the chlorhexidine-releasing mechanically stable epoxy-based CHX10 coating prevented implant colonisation and S. aureus BAI in mice and has good prospects for clinical development

U2 - 10.22203/eCM.v0033a11

DO - 10.22203/eCM.v0033a11

M3 - Article

C2 - 28197990

VL - 33

SP - 143

EP - 157

JO - European cells & materials

JF - European cells & materials

SN - 1473-2262

ER -

ID: 3383991