Hydrogen peroxide-activatable polymeric prodrug of curcumin for ultrasound imaging and therapy of acute liver failure.

Curcumin is a major active phenolic component of turmeric and has gained great attention in pharmaceutics due to its potent antioxidant, anti-inflammatory and anticancer activity. Here, we developed poly(oxalate-co-curcumin) (POC) as a hydrogen peroxide (H2O2)-activatable polymeric prodrug of curcumin by incorporating curcumin in the backbone of H2O2-responsive polyoxalate. POC particles effectively scavenged H2O2 and released curcumin in a H2O2-triggered manner. POC particles exhibited excellent antioxidant and anti-inflammatory activity in activated cells. POC particles intravenously administrated into acetaminophen-intoxicated mice remarkably suppressed the level of alanine transaminase and inhibited apoptotic cell death in liver. Interestingly, POC particles could also enhance the ultrasound contrast in the intoxicated liver due to CO2 bubble generation through H2O2-triggered oxidation of peroxalate esters. Given their H2O2-responsiveness and highly potent antioxidant activity, POC particles hold great translational potential as theranostic agents for H2O2-associated diseases.

Fabrication of nanofiber coated with l-arginine via electrospinning technique: a novel nanomatrix to counter oxidative stress under crosstalk of co-cultured fibroblasts and satellite cells.

The objective of this study was to synthesize and characterize novel polyurethane (PU)-nanofiber coated with l-arginine by electrospinning technique. This study determined whether l-arginine conjugated with PU-nanofiber could stimulate cell proliferation and prevent H2O2-induced cell death in satellite cells co-cultured with fibroblasts isolated from Hanwoo (Korean native cattle). Our results showed that l-arginine conjugated with PU nanofiber could reduce cytotoxicity of co-cultured satellite cells. Protein expression levels of bcl-2 were significantly upregulated whereas those of caspase-3 and caspase-7 were significantly downregulated in co-culture of satellite cells compared to those of monoculture cells after treatment with PU-nanofiber coated with l-arginine and which confirmed by Confocal microscope. These results suggest that co-culture of satellite cells with fibroblasts might be able to counter oxidative stress through translocation/penetration of antioxidant, collagen, and molecules secreted to satellite cells. Therefore, this nanofiber might be useful as a wound dressing in animals to counter oxidative stresses.