In-Vitro Biofilm Removal Efficacy Using Water Jet in Combination with Cold Plasma Technology on Dental Titanium Implants.
Rutger MatthesLukasz JablonowskiLea MiebachVinay PitchikaBirte HoltfreterChristian EberhardLeo SeifertTorsten GerlingRabea SchlüterThomas KocherSander BekeschusPublished in: International journal of molecular sciences (2023)
Peri-implantitis-associated inflammation can lead to bone loss and implant failure. Current decontamination measures are ineffective due to the implants' complex geometry and rough surfaces providing niches for microbial biofilms. A modified water jet system (WaterJet) was combined with cold plasma technology (CAP) to achieve superior antimicrobial efficacy compared to cotton gauze treatment. Seven-day-old multi-species-contaminated titanium discs and implants were investigated as model systems. The efficacy of decontamination on implants was determined by rolling the implants over agar and determining colony-forming units supported by scanning electron microscopy image quantification of implant surface features. The inflammatory consequences of mono and combination treatments were investigated with peripheral blood mononuclear cell surface marker expression and chemokine and cytokine release profiles on titanium discs. In addition, titanium discs were assayed using fluorescence microscopy. Cotton gauze was inferior to WaterJet treatment according to all types of analysis. In combination with the antimicrobial effect of CAP, decontamination was improved accordingly. Mono and CAP-combined treatment on titanium surfaces alone did not unleash inflammation. Simultaneously, chemokine and cytokine release was dramatically reduced in samples that had benefited from additional antimicrobial effects through CAP. The combined treatment with WaterJet and CAP potently removed biofilm and disinfected rough titanium implant surfaces. At the same time, non-favorable rendering of the surface structure or its pro-inflammatory potential through CAP was not observed.
Keyphrases
- staphylococcus aureus
- soft tissue
- peripheral blood
- oxidative stress
- biofilm formation
- pseudomonas aeruginosa
- electron microscopy
- high frequency
- poor prognosis
- bone loss
- high resolution
- candida albicans
- combination therapy
- machine learning
- cystic fibrosis
- long non coding rna
- replacement therapy
- cell surface
- atomic force microscopy
- high speed