The potential for substance abuse involving residual amounts of abusable substances remaining in used skin-worn patches is reduced by the provision of a system and method for combining the abusable substance with a separate anti-abuse substance agent as part of a removal or disposal procedure.

The potential for substance abuse involving residual amounts of abusable substances remaining in used skin-worn patches is reduced by the provision of a system and method for combining the abusable substance with a separate anti-abuse substance agent as part of a removal or disposal procedure.

The potential for substance abuse involving residual amounts of abusable substances remaining in used skin-worn patches is reduced by the provision of a system and method for combining the abusable substance with a separate anti-abuse substance agent as part of a removal or disposal procedure.

The potential for substance abuse involving residual amounts of abusable substances remaining in used skin-worn patches is reduced by the provision of a system and method for combining the abusable substance with a separate anti-abuse substance agent as part of a removal or disposal procedure.

A polymer-based material includes a polymeric binder and one or more porous active materials that adsorb, chemisorb, decompose, or a combination thereof, a hazardous chemical. The polymeric binder and the one or more porous active materials are combined to form a composite bead. The polymeric binder may include a polyurethane or a styrene-based block copolymer. The porous active materials may comprise metal-organic frameworks, metal oxides, metal hydroxides, and metal hydrates. The one or more porous active materials may be between 1 and 99 wt % of a total composite mass of the composite bead. Alternatively, the one or more porous active materials may be between 80 and 95 wt % of a total composite mass of the composite bead. The hazardous chemical may include a chemical warfare agent, a simulant of chemical warfare agents, and toxic industrial chemicals.

A polymer-based material includes a polymeric binder and one or more porous active materials that adsorb, chemisorb, decompose, or a combination thereof, a hazardous chemical. The polymeric binder and the one or more porous active materials are combined to form a composite bead. The polymeric binder may include a polyurethane or a styrene-based block copolymer. The porous active materials may comprise metal-organic frameworks, metal oxides, metal hydroxides, and metal hydrates. The one or more porous active materials may be between 1 and 99 wt % of a total composite mass of the composite bead. Alternatively, the one or more porous active materials may be between 80 and 95 wt % of a total composite mass of the composite bead. The hazardous chemical may include a chemical warfare agent, a simulant of chemical warfare agents, and toxic industrial chemicals.

Disposal means for large scale efficient disposal of medication and controlled substances comprising a homogeneous mixture of one or more surfactants, aerobic enzymes, anaerobic enzymes, soluble bitterants, insoluble bitterants, colorants, excipients, thickener agents, and humectant. Unwanted medication and controlled substances, such as opioids, are introduced to the solution and rendered inert and/or useless.

Disposal means for large scale efficient disposal of medication and controlled substances comprising a homogeneous mixture of one or more surfactants, aerobic enzymes, anaerobic enzymes, soluble bitterants, insoluble bitterants, colorants, excipients, thickener agents, and humectant. Unwanted medication and controlled substances, such as opioids, are introduced to the solution and rendered inert and/or useless.

A continuous bubbling fluid bed process converts biomass feedstocks into energy/heat, engineered biochar particles (including nanoparticles) and a vapor stream of organic compounds. The products have a multitude of applications determined by the specific conditions at which the process was operated, specifically controlling: temperature, catalysts, residence time, element and compound concentrations, and withdraw of products from various points in the system. The introduction of air, steam, and various gases into the vessel at selected locations and at controlled rates enables the economic, dependable and consistent production of these products.

A continuous bubbling fluid bed process converts biomass feedstocks into energy/heat, engineered biochar particles (including nanoparticles) and a vapor stream of organic compounds. The products have a multitude of applications determined by the specific conditions at which the process was operated, specifically controlling: temperature, catalysts, residence time, element and compound concentrations, and withdraw of products from various points in the system. The introduction of air, steam, and various gases into the vessel at selected locations and at controlled rates enables the economic, dependable and consistent production of these products.