Staphylococcus aureus (SA) is a leading cause of both superficial and invasive infections in community and hospital settings, frequently resulting in chronic refractory disease. It is imperative that innovative therapeutics to which the bacteria are unlikely to evolve resistance be developed to curtail associated morbidity and mortality and ultimately improve our capacity to treat these infections. In this study, a previously unreported nitric oxide (NO)-releasing nanoparticle technology is applied to the treatment of methicillin-resistant SA (MRSA) wound infections. The results show that the nanoparticles exert antimicrobial activity against MRSA in a murine wound model. Acceleration of infected wound closure in NO-treated groups was clinically shown compared with controls. The histology of wounds revealed that NO nanoparticle treatment decreased suppurative inflammation, minimal bacterial burden, and less collagen degradation, providing potential mechanisms for biological activity. Together, these data suggest that these NO-releasing nanoparticles have the potential to serve as a novel class of topically applied antimicrobials for the treatment of cutaneous infections and wounds.
The effect of methamphetamine on the host response to an opportunistic pathogen has not been extensively described. Methamphetamine is a major public health and safety problem in the United States. Chronic methamphetamine abuse is associated with a 2-fold higher risk of human immunodeficiency virus infection and, possibly, additional infections. Histoplasma capsulatum is a dimorphic fungus that is endemic in the Midwest of the United States and that causes respiratory and systemic disease, particularly in individuals with impaired immunity. We showed that methamphetamine abrogates normal macrophage function, resulting in an inability to control histoplasmosis. Methamphetamine decreased phagocytosis and killing of yeast by primary macrophages by alkalization of the phagosome. Furthermore, mice that received methamphetamine prior to H. capsulatum infection were immunologically impaired, with increased fungal burden, increased pulmonary inflammation, and decreased survival. Immunosuppression by methamphetamine may be associated with deregulation of cytokines in the lungs of infected mice, aberrant processing of H. capsulatum within macrophages, and immobilization of MAC-1 receptors on the surface of macrophages that are involved in phagocytosis. Additionally, methamphetamine inhibits T cell proliferation and alters antibody production, which are important components of adaptive immunity. With use of a murine model of histoplasmosis, this study establishes that methamphetamine may alter the immune system of the host and enhance fungal pathogenesis.
Candida species are a major cause of catheter infections. Using a central venous catheter Candida albicans biofilm model, we demonstrated that chitosan, a polymer isolated from crustacean exoskeletons, inhibits candidal biofilm formation in vivo. Furthermore, chitosan statistically significantly decreased both the metabolic activity of the biofilms and the cell viability of C. albicans and Candida parapsilosis biofilms in vitro. In addition, confocal and scanning electron microscopic examination demonstrated that chitosan penetrates candidal biofilms and damages fungal cells. Importantly, the concentrations of chitosan that were used to evaluate fungal biofilm susceptibility were not toxic to human endothelial cells. Chitosan should be considered for the prevention or treatment of fungal biofilms on central venous catheters and perhaps other medical devices.
The use of indwelling medical devices (e.g. pacemakers, prosthetic joints, catheters, etc) continues to increase, yet these devices are all too often complicated by infections with biofilm-forming microbes with increased resistance to antimicrobial agents and host defense mechanisms. We investigated the ability of chitosan, a polymer isolated from crustacean exoskeletons, to damage biofilms formed by the pathogenic fungus Cryptococcus neoformans. Using 2,3-bis(2-methoxy-4-nitro-5-sulfophenyl)-5-[(phenylamino) carbonyl]-2H-tetrazolium-hydroxide (XTT) reduction assay and CFU determinations, we showed that chitosan significantly reduced both the metabolic activity of the biofilms and cell viability, respectively. We further demonstrated that chitosan penetrated biofilms and damaged fungal cells using confocal and scanning electron microscopy. Notably, melanization, an important virulence determinant of C. neoformans, did not protect cryptococcal biofilms against chitosan. The chitosan concentrations used in this study to evaluate fungal biofilm susceptibility were not toxic to human endothelial cells. Our results indicate that cryptococcal biofilms are susceptible to treatment with chitosan, suggesting an option for the prevention or treatment of fungal biofilms on indwelling medical devices.
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