Abstract: A therapeutic method for catalytically forming persulfide and/or polysulfide from hydrogen sulfide in vitro and in vivo using endogenously or exogenously released hydrogen sulfide is disclosed. That method comprises contacting cells in need including those under oxidative stress, traumatic brain injury (TBI) and hypoxia, or have an excess of hydrogen sulfide or deficiency of protein persulfidation with oxidized carbon nanoparticulate material in which the particles contain a plurality of carbonyl, hydroxyl and carboxyl substituents. Oxidized carbon nanoparticulate (OCN) material can be prepared from any of a variety of sources of which activated charcoal is preferred. A water-dispersible OCN material is described that does not need added hydrophilic polymers to provide dispersibility for at least 7 days at a concentration of about 1-5 mg/mL. These OCN materials also have a UV absorbance maximum in water of about 220 nm and pass through a 0.22 µm pore PES membrane.

Abstract: Modified hydrophilic carbon clusters (HCCs), poly(ethylene glycol)-hydrophilic carbon clusters (PEG-HCCs) and similarly structured materials like graphene quantum dots (GQDs), PEGylated GQDs, small molecule antioxidants, and PEGylated small molecule antioxidants. These materials have been modified with an iron chelating moiety, deferoxamine, or a similar chelating moiety. By exploiting common binding sites, the carbon nanostructure facilitates intracellular transport including in mitochondria, reduces oxidative breakdown of the chelator moiety prior to treatment, and reduces both the cause and consequences of metal induced oxidative stress within the body thus providing a novel form of therapy for a range of oxidative and metal-related toxicities. Graphenic materials can be used for the treatment of acute and chronic mitochondrial electron transport chain dysfunction.