N-acetylcysteine S-nitrosothiol Nanoparticles Prevent Wound Expansion and Accelerate Wound Closure in a Murine Burn Model.

BACKGROUND: The treatment of cutaneous wounds in the clinical setting continues to be a clinical challenge and economic burden, with burn wounds being especially formidable. Direct mechanical injury coupled with the transfer of thermal energy leads to tissue necrosis, pro-inflammatory cytokine release and the eventual expansion of an initial wound. Our current therapeutic armamentarium falls short of options to help prevent wound expansion, and therefore new modalities are required. Nitrosating substances such as RSNOs have been proven to be effective in promoting wound closure due to their ability to modulate inflammation, cytokine production and vascular function. OBJECTIVE: We aim to evaluate the efficacy of n-actetylcysteine s-nitrosothiol nanoparticles (NAC-SNO-np) on thermal burn wounds and associated expansion. METHODS: A multi-burn model was utilized to induce three burn wounds on the dorsal surface of BALB/c mice, allowing for evaluation of the burn itself and peripheral tissue. Wounds were excised and processed for histology and immunohistochemistry on day 7 following wounding. RESULTS: Following treatment with NAC-SNO-np, burn wound expansion was attenuated and wound healing was accelerated. Histological analysis revealed increased collagen deposition as well as increased macrophage and decreased neutrophil infiltration into the wound bed. CONCLUSION: NAC-SNO-np represents a platform that harnesses the nitrosative properties of NAC-SNO in order to accelerate the transition from inflammatory to proliferative wound healing. Further studies are needed in order to translate to the clinical setting.

Characterization and assessment of nanoencapsulated sanguinarine chloride as a potential treatment for melanoma.

Sanguinarine has a history of use in both folk medicine and early dermatology for the treatment of cutaneous neoplasms. Applied indiscriminately, bloodroot is an escharotic agent with potential to cause extensive tissue necrosis. However, when used in a controlled fashion, sanguinarine imparts selective cytotoxic/anti-proliferative activity through multiple mechanisms against human/ murine melanoma. To exploit sanguinarine's observed activity against melanoma, a targeted delivery system is required. We present a sol-gel based nanoparticulate platform for encapsulating sanguinarine chloride(sang-np)-a targeted therapeutic capable of steady, reliable delivery of predictable quantities of drug over a sustained time period with minimal undesirable effects. Size and release kinetics of sang-np were characterized using dynamic light scattering and ultraviolet-visible spectroscopy respectively. In vitro efficacy of sang-np was assessed. At both 2 and 24 hours, free sanguinarine killed > 90% of B16 melanoma cells, assessed via MTT assay. At 2 hours, sang-np killed a portion of melanoma cells, increasing to percentages comparable to free sanguinarine by 24 hours. Control(empty) nanoparticles exerted minimal toxicity to melanoma cells at both time points. TUNEL assay revealed that treatment with both sanguinarine and sang-np induces apoptosis in B16 melanoma cells, suggesting that both treatments act via the same mechanism of action. These data confirm controlled release of sanguinarine from sang-np, as well as comparable efficacy and mechanism of action to sanguinarine alone. This suggests that nanoparticle delivery of sanguinarine may be a unique approach to capitalize on this potent agent's inherent anti-tumor activity and overcome many of the limitations with its current formulation.