Acute paronychia in a neonate secondary to clindamycin-resistant Staphylococcus aureus.

Paronychia is a common inflammatory condition of the nail fold that is often associated with infection. Causes can be fungal, viral, or most commonly, bacterial. Neonatal paronychia is a rare presentation with only one previously reported case in the literature of a patient younger than 1 month of age. This is a case of an 8-day-old neonate with acute bacterial paronychia caused by clindamycin-resistant Staphylococcus aureus.

Evaluation of the antibiotic properties of glutathione.

Skin and soft tissue infections (SSTIs) are growing in prevalence in both the outpatient and inpatient settings and are some of the most common diseases seen by dermatologists, who are often the first point of care for these patients. Microbial resistance to antibiotics continues to rise as more virulent strains evolve, and strains predominantly found in the hospital setting are now being seen in the community. Therefore, innovative approaches to combat this trend are needed. Glutathione (GSH) is a well-described and established antioxidant. It participates in detoxification of xenobiotics, regulation of cellular growth, modulation of immune response, and maintenance of the thiol status of proteins and cellular cysteine levels. GSH is also known to have a regulatory effect on immune cells and even inherent antibacterial properties have been reported. To this end, the value of GSH as an antibiotic was evaluated by growing methicillin resistant S. aureus, E. coli, K. pneumoniae and P. aeruginosa strains isolated from human skin and soft tissue infection in the presence of GSH. At a physiologic concentration of 10 mM, GSH had no effect on bacterial growth. At concentrations above 50 mM, which created acidic conditions (pH < 4), bacterial growth was completely inhibited. When adjusted to physiologic pH, GSH exhibited a bacteriostatic effect in a concentration-dependent manner. Additionally, the cytotoxicity of GSH was evaluated in a murine cell line. GSH was relatively non-toxic to murine macrophages, even at the highest concentration tested (160 mM). These results suggest the potential utility of GSH for the prevention and/or as adjunctive treatment of infection, most significantly in disease states associated with GSH deficiency.

Safety and efficacy of topical cantharidin for the treatment of pediatric molluscum contagiosum: a prospective, randomized, double-blind, placebo-controlled pilot trial.

Topical cantharidin is a commonly used treatment for molluscum contagiosum (MC). However, studies validating its safety and efficacy are limited. We conducted a 6-week, randomized, double-blind, placebo-controlled trial with subsequent open-label extension to assess the safety and effectiveness of cantharidin in treating pediatric MC. Ninety-four participants with MC were randomized to receive cantharidin or placebo, with or without occlusion. The primary outcome was complete lesion clearance. Secondary outcomes included post-treatment lesion count, adverse events, and side effects. No significant differences between the study arms, including baseline lesion count, were observed. The overall mean (SD) baseline lesion count was 22.2 (12.9). The number of participants achieving total clearance is as follows: 7/23 (30.4%) in the cantharidin only arm, 10/24 (41.7%) in the cantharidin with occlusion arm, 2/25 (8.0%) in the placebo with occlusion arm, and 3/22 (13.6%) in the placebo only arm. Post hoc analysis demonstrated that 17/47 (36.2%) participants in the combined cantharidin arms achieved clearance compared to 5/47 (10.6%) in the placebo arms (P = 0.0065). The mean (SD) lesion count change from baseline was -5.1 (12.2) in the placebo only arm; the mean change (SD) was -17.4 (12.8) in the cantharidin only arm (P = 0.0033) and -15.9 (11.6) in the cantharidin with occlusion arm (P = 0.0101). No serious adverse events or side effects were observed. Topical cantharidin was well-tolerated and associated with the resolution of MC.

Antimicrobial and anti-inflammatory activity of chitosan-alginate nanoparticles: a targeted therapy for cutaneous pathogens.

Advances in nanotechnology have demonstrated potential application of nanoparticles (NPs) for effective and targeted drug delivery. Here we investigated the antimicrobial and immunological properties and the feasibility of using NPs to deliver antimicrobial agents to treat a cutaneous pathogen. NPs synthesized with chitosan and alginate demonstrated a direct antimicrobial activity in vitro against Propionibacterium acnes, the bacterium linked to the pathogenesis of acne. By electron microscopy (EM) imaging, chitosan-alginate NPs were found to induce the disruption of the P. acnes cell membrane, providing a mechanism for the bactericidal effect. The chitosan-alginate NPs also exhibited anti-inflammatory properties as they inhibited P. acnes-induced inflammatory cytokine production in human monocytes and keratinocytes. Furthermore, benzoyl peroxide (BP), a commonly used antiacne drug, was effectively encapsulated in the chitosan-alginate NPs and demonstrated superior antimicrobial activity against P. acnes compared with BP alone while demonstrating less toxicity to eukaryotic cells. Together, these data suggest the potential utility of topical delivery of chitosan-alginate NP-encapsulated drug therapy for the treatment of dermatologic conditions with infectious and inflammatory components.

The potential of nitric oxide releasing therapies as antimicrobial agents.

Nitric oxide (NO) is a short-lived, diatomic, lipophilic gas that plays an integral role in defending against pathogens. Among its many functions are involvement in immune cell signaling and in the biochemical reactions by which immune cells defend against bacteria, fungi, viruses and parasites. NO signaling directs a broad spectrum of processes, including the differentiation, proliferation, and apoptosis of immune cells. When secreted by activated immune cells, NO diffuses across cellular membranes and exacts nitrosative and oxidative damage on invading pathogens. These observations led to the development of NO delivery systems that can harness the antimicrobial properties of this evanescent gas. The innate microbicidal properties of NO, as well as the antimicrobial activity of the various NO delivery systems, are reviewed.