Nitric oxide-releasing nanoparticles accelerate wound healing in NOD-SCID mice.

Wound healing is a complex process, coordinated by various biological factors. In immunocompromised states wound healing can be interrupted as a result of decreased numbers of immune cells, impairing the production of effector molecules such as nitric oxide (NO). Therefore, topical NO-releasing platforms, such as diethylenetriamine (DETA NONOate), have been investigated to enhance wound healing. Recently, we demonstrated a nanoparticle platform that releases NO (NO-NPs) in a sustained manner, accelerating wound healing in both uninfected and infected murine wound models. Here, NO-NPs were investigated and compared to DETA NONOate in an immunocompromised wound model using non-obese, diabetic, severe combined immunodeficiency mice. NO-NP treatment accelerated wound closure as compared to controls and DETA NONOate treatment. In addition, histological assessment revealed that wounds treated with NO-NPs had less inflammation, more collagen deposition, and more blood vessel formation as compared to other groups, consistent with our previous data in immunocompetent animals. These data suggest that NO-NPs may serve as a novel wound-healing therapy in the setting of immunocompromised states associated with impaired wound healing. FROM THE CLINICAL EDITOR: Wound healing in an immunocompromised host is often incomplete and is a source of major concern in such conditions. This work demonstrates in a murine model that in these settings NO releasing nanoparticles significantly enhance wound healing.

Improved antimicrobial efficacy with nitric oxide releasing nanoparticle generated S-nitrosoglutathione.

Nitric oxide (NO) plays a vital role in mammalian host defense through a variety of mechanisms. In particular, NO can oxidize to form reactive nitrogen species or interact with protein thiols and metal centers, blocking essential microbial processes. S-nitrosoglutathione (GSNO), a potent NO donor formed by the interaction of NO with intracellular glutathione (GSH), is a major factor in this pathway and is considered one of the strongest naturally occurring nitrosating agent. We previously described the broad-spectrum antimicrobial activity of a nanoparticulate platform capable of controlled and sustained release of NO (NO-np). Interestingly, in vivo efficacy of the NO-np surpassed in vitro data generated. We hypothesized that the enhanced activity was in part achieved via the interaction between the generated NO and available GSH, forming GSNO. In the current study, we investigated the efficiency of NO-np to form GSNO in the presence of GSH was evaluated, and assessed the antimicrobial activity of the formed GSNO against methicillin resistant Staphylococcus aureus (MRSA), Escherichia coli, Klebsiella pneumoniae, and Pseudomonas aeruginosa. When GSH was combined with NO-np, GSNO was rapidly produced and significant concentrations of GSNO were maintained for >24h. The GSNO generated was more effective compared to NO-np alone against all bacterial strains examined, with P. aeruginosa being the most sensitive and K. pneumoniae the most resistant. We conclude that the combination of NO-np with GSH is an effective means of generating GSNO, and presents a novel approach to potent antimicrobial therapy.

A biopsy diagnosis? clinical clues and patterns to help distinguish cutaneous metastases: part II of II.

News, Views and Reviews provides focused updates, topic reviews and editorials concerning the latest developments in dermatologic therapy.

Nitric oxide nanoparticles: pre-clinical utility as a therapeutic for intramuscular abscesses.

Nitric oxide (NO) is a critical component of host defense against invading pathogens; however, its therapeutic utility is limited due to a lack of practical delivery systems. Recently, a NO-releasing nanoparticulate platform (NO-np) was shown to have in vitro broad-spectrum antimicrobial activity and in vivo pre-clinical efficacy in a dermal abscess model. To extend these findings, both topical (TP) and intralesional (IL) NO-np administration was evaluated in a MRSA intramuscular murine abscess model and compared with vancomycin. All treatment arms accelerated abscess clearance clinically, histologically, and by microbiological assays on both days 4 and 7 following infection. However, abscesses treated with NO-np via either route demonstrated a more substantial, statistically significant decrease in bacterial survival based on colony forming unit assays and histologically revealed less inflammatory cell infiltration and preserved muscular architecture. These data suggest that the NO-np may be an effective addition to our armament for deep soft tissue infections.

The growing role of nanotechnology in combating infectious disease.

The treatment and prevention of infectious diseases is a major part of both clinical and investigative medicine. As the use of conventional antibiotics rises, antimicrobial resistance patterns develop, necessitating the continuous need for newer and more effective therapies. Nanotechnology, defined as the production and application of materials in the nanoscale range (1-100 nm), has been the focus of several investigations as a result of unique physical and chemical properties of nanomaterials. . Specifically, nanomaterials provide added benefits due to their small size; allowing for an increased ability to surpass most physiologic barriers and reach their intended targets, and high surface area-to-volume ratio, allowing for increased potential to interact with pathogen membranes and cell walls. This review focuses of the potential therapeutic and preventative applications of nanotechnology-based drug delivery systems in infectious disease.

Susceptibility of Gram-positive and -negative bacteria to novel nitric oxide-releasing nanoparticle technology.

The rapidly evolving crisis of antibiotic resistance among microorganisms has contributed to the rise of patient morbidity and mortality from nosocomial and community-acquired infections. Therefore, innovative antimicrobial technology targeting mechanisms to which the bacteria are unlikely to evolve resistance is urgently needed. We have previously described a nitric oxide-releasing nanoparticle (NO-np) with efficacy against methicillin-resistant Staphylococcus aureus (MRSA) and Acinetobacter baumannii in vitro and in murine wound and abscess models. Although the prior findings suggest that the NO-np can be a useful therapeutic for skin and soft tissue infections, the antimicrobial spectrum of NO-np has yet to be fully elucidated. In the current study, we investigated the efficacy of a NO-np against several Gram-positive and -negative clinical isolates. We found that the NO-np were uniformly active against all of the Streptococcus pyogenes, Enterococcus faecalis, Klebsiella pneumoniae, Escherichia coli, and Pseudomonas aeruginosa clinical isolates examined, including strains that were both sensitive and resistant to commonly used antibiotics. We concluded that the NO-np have the potential to serve as a novel broad spectrum antimicrobial agent.