Effective Immobilization of Novel Antimicrobial Peptides via Conjugation onto Activated Silicon Catheter Surfaces.
Irem SoyhanTuba PolatErkan MoziogluTugba Arzu Ozal IldenızMerve Acikel ElmasSinan CebeciNihan UnubolOzgul GokPublished in: Pharmaceutics (2024)
Antibiotic-resistant microorganisms have become a serious threat to public health, resulting in hospital infections, the majority of which are caused by commonly used urinary tract catheters. Strategies for preventing bacterial adhesion to the catheters' surfaces have been potentially shown as effective methods, such as coating thesurface with antimicrobial biomolecules. Here, novel antimicrobial peptides (AMPs) were designed as potential biomolecules to prevent antibiotic-resistant bacteria from binding to catheter surfaces. Thiolated AMPs were synthesized using solid-phase peptide synthesis (SPPS), and prep-HPLC was used to obtain AMPs with purity greater than 90%. On the other side, the silicone catheter surface was activated by UV/ozone treatment, followed by functionalization with allyl moieties for conjugation to the free thiol group of cystein in AMPs using thiol-ene click chemistry. Peptide-immobilized surfaces were found to become more resistant to bacterial adhesion while remaining biocompatible with mammalian cells. The presence and site of conjugation of peptide molecules were investigated by immobilizing them to catheter surfaces from both ends (C-Pep and Pep-C). It was clearly demonstrated that AMPs conjugated to the surface via theirN terminus have a higher antimicrobial activity. This strategy stands out for its effective conjugation of AMPs to silicone-based implant surfaces for the elimination of bacterial infections.
Keyphrases
- biofilm formation
- public health
- staphylococcus aureus
- pseudomonas aeruginosa
- escherichia coli
- candida albicans
- ultrasound guided
- urinary tract
- ms ms
- mass spectrometry
- hydrogen peroxide
- cystic fibrosis
- simultaneous determination
- risk assessment
- climate change
- adverse drug
- high performance liquid chromatography
- tandem mass spectrometry
- walled carbon nanotubes