Design and Synthesis of Ceragenins–Cationic Steroid Antimicrobial Compounds, Structural Improvement and Synthesis of Cyclopentenone Prostaglandins and Modification and Synthesis of Derivatives of Ribityllumazines: Potential Antigens for Activation of MAIT Cells

Li, Yubo

01 April 2019

Antimicrobial peptides (AMPs) are ubiquitous and display broad-spectrum antimicrobial activity that can control bacterial colonization of surfaces. Ceragenins are small-molecule mimics of AMPs and have several advantages over AMPs, including cost of manufacture and stability. A ceragenin, CSA-120, modified with an acrylamide group was directly incorporated into fluoropolymer coatings as a means of inhibiting bacterial biofilm formation. The ceragenin-containing coatings displayed improved performance. By conjugating a copper chelating group to the ceragenin, chelation of 64Cu by the conjugate was effective and provided a stable complex that allowed in vivo imaging. This conjugate may provide a means of identifying infection sites in patients presenting general signs of infection without localized symptoms. A combination nanoparticle comprised of a maghemite core for enhanced T2 MRI contrast diagnostics, a colloidal silver shell acting as an antimicrobial and therapeutic vehicle, and a ceragenin (CSA- 124) surfactant providing microbial adhesion was synthesized and characterized by multiple methods. Silver nanoparticles conjugated with ceragenin, CSA-124, as a potential Gram-positiveselective antimicrobial were synthesized and termed as CSA-SNPs. Herein, CSA-SNPs are characterized using multiple methods and the antimicrobial properties are determined through minimum inhibitory concentration/minimum bactericidal concentration (MIC/MBC) and time-kill study. Prostanoids are a natural subclass of eicosanoids generated mainly from metabolic oxidation of arachidonic acid. Cyclopentenone prostaglandins (cyPGs) contain a highly reactive α,β-unsaturated carbonyl group in their cyclopentenone ring and possess three main potentially therapeutic properties: anti-inflammatory, antiproliferative and antiviral. We designed and synthesized EC and its derivatives in reducing secretion of pro-inflammatory cytokines IL-6 and IL-12. Mucosal-Associated Invariant T (MAIT) Cells are unique innate-like T cells and play a key role in host defense against bacterial and fungal infection as well as in human autoimmune diseases. The MAIT cells are activated through T-cell receptor αβ chain (TCR-αβ) binding with the MR1-ligand, which is vitamin B metabolites presented on MR1. Rribityllumazines, one of important MR1-ligand was synthesized in my study.

Antimicrobial peptides

Ceragenin

Cationic Steroid Antimicrobial

Nanoparticle

Cyclopentenone prostaglandins

Mucosal-Associated Invariant T

Rribityllumazines

Biochemistry

Physical Sciences and Mathematics

Application and Development of Ceragenins in Medical Device Coatings for Clinical Settings

Sherren, Elliot E.

21 June 2024

Hospital-acquired infections (HAIs) pose a significant and increasing threat to global health. One primary cause of this threat is increasing antibiotic resistance. As traditional antibiotics continue to grow less effective, there is an urgent need for novel antimicrobial strategies. This work explores the potential of ceragenins, also known as cationic steroid antimicrobials (CSAs), as a promising alternative to combat HAIs. Specifically, we investigated potential roles that CSAs can play in the context of multiple medical device coatings in healthcare settings. Ceragenins are synthetic mimic of antimicrobial peptides (AMPs) which exhibit broad-spectrum antimicrobial activity against many common pathogens that have been cited as high priority by global health organizations. Unlike traditional antibiotics, which rely on specificity to bacterial enzymes or processes, ceragenins disrupt microbial membranes generally. This mechanism of action allows ceragenins to bypass many of the related antibiotic resistance mutations of bacteria and fungi. As microbial membranes are a highly conserved and fundamental structure of these pathogens, it is much more difficult for microbes to develop mutations that prevent CSA binding. Additionally, ceragenins are resistant to both host and pathogenic proteolytic degradation and are cost-effective to produce, which place CSAs as an attractive alternative to traditional antibiotics. This research investigates the integration of ceragenins into various medical devices to prevent HAIs. Specifically, we investigated silicone tissue expanders, peripherally inserted central catheter (PICC) lines, and adhesive devices which include both polyacrylate and silicone scar tape. These studies include the development of coating techniques to maximize appropriate antimicrobial activity while maintaining stability and biocompatibility across these different base materials. Our experimental results demonstrate that ceragenin-coated devices significantly reduce microbial colonization and biofilm formation. We considered the length of antimicrobial activity needed and developed coatings that would be appropriate for those use cases. This reduction in harmful pathogenic colonization demonstrates their potential to improve patient outcomes and reduce healthcare costs associated with HAIs. Further research and development could facilitate the continued adoption of ceragenin-based coatings in medical devices, which can reduce the incidence of HAIs while contributing to the broader fight against antibiotic-resistant infections worldwide.

ceragenin

cationic steroid antimicrobials

antimicrobial peptides

silicone tissue expander

adhesives

antibiotic resistance

Physical Sciences and Mathematics