ON-DEMAND ACTIVATION OF A NOVEL ANTI-INFECTIVE BIOPOLYMER IMPLANT COATING WITH HIGH-ENERGY SHOCKWAVES

Puetzler J, Hasselmann J, Gosheger G, et al. ON-DEMAND ACTIVATION OF A NOVEL ANTI-INFECTIVE BIOPOLYMER IMPLANT COATING WITH HIGH-ENERGY SHOCKWAVES. Orthop Procs. 2022;104-B(SUPP_10):87-87. doi:10.1302/1358-992X.2022.10.087

Puetzler, J., et al. “ON-DEMAND ACTIVATION OF A NOVEL ANTI-INFECTIVE BIOPOLYMER IMPLANT COATING WITH HIGH-ENERGY SHOCKWAVES.” Orthopaedic Proceedings, vol. 104-B, no. SUPP_10, 2022, pp. 87-87., https://doi.org/10.1302/1358-992X.2022.10.087

Puetzler, J., Hasselmann, J., Gosheger, G., Niemann, S., Fobker, M., Hillebrand, J., Schwarze, J., Theil, C., & Schulze, M. (2022). ON-DEMAND ACTIVATION OF A NOVEL ANTI-INFECTIVE BIOPOLYMER IMPLANT COATING WITH HIGH-ENERGY SHOCKWAVES. Orthopaedic Proceedings, 104-B(SUPP_10), 87-87. https://doi.org/10.1302/1358-992X.2022.10.087

Puetzler, J., Hasselmann, J., Gosheger, G., Niemann, S., Fobker, M., Hillebrand, J. et al. (2022) “ON-DEMAND ACTIVATION OF A NOVEL ANTI-INFECTIVE BIOPOLYMER IMPLANT COATING WITH HIGH-ENERGY SHOCKWAVES.” Orthopaedic Proceedings, 104-B(SUPP_10), pp. 87-87. Available at: https://doi.org/10.1302/1358-992X.2022.10.087

Puetzler, J., J. Hasselmann, G. Gosheger, S. Niemann, M. Fobker, J. Hillebrand, J. Schwarze, C. Theil, and M. Schulze. “ON-DEMAND ACTIVATION OF A NOVEL ANTI-INFECTIVE BIOPOLYMER IMPLANT COATING WITH HIGH-ENERGY SHOCKWAVES.” Orthopaedic Proceedings 104-B, no. SUPP_10 (2022): 87-87. https://doi.org/10.1302/1358-992X.2022.10.087

Puetzler J, Hasselmann J, Gosheger G, Niemann S, Fobker M, Hillebrand J, et al. ON-DEMAND ACTIVATION OF A NOVEL ANTI-INFECTIVE BIOPOLYMER IMPLANT COATING WITH HIGH-ENERGY SHOCKWAVES. Orthop Procs. 2022 Oct 1;104-B(SUPP_10):87-87. https://doi.org/10.1302/1358-992X.2022.10.087

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Abstract

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/mm², 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.

E-mail: jan.puetzler@ukmuenster.de