Disclosed herein are methods for the large-scale production of a highly thermally stable acetylcholinesterase (AChE) and butyrylcholinesterase (BChE). Additionally, the expression methods disclosed herein can produce ChE preparations consisting of extract or purified forms that can be produced in high amounts and are highly thermally stable. These ChE products can be used in vitro detection, detoxification and decontamination methods.

This invention refers to a method for preparing a chemical digester characterized by using organic and inorganic elements used for multiple purposes such as an accelerator in the decomposition of organic matter, as a water flocculant, as an organic soil fertilizer and as a means to eliminate the concentration of flies and other inserts in organic matter to decompose. The method comprises heating water in a reactor at a temperature of 38 C., adding a polysaccharide, an anti-thickener and an antifoam. The method then comprises the addition of two organic acids, one of them previously mixed in a second reactor and, finally, an inorganic acid until the mixture is homogenized. Optionally the method comprises the packaging of the mixture and the treatment of organic matter.

The invention is directed toward mutant, non-wild-type organophosphorus acid anhydrolase enzymes having three site mutations, methods of production, and methods of use to effectively degrade toxic organophosphorus compounds, most preferably GP (2,2-dimethylcyclopentyl methylphosphonofluoridate).

Compositions and methods related to anucelate cells (e.g., bacterial minicells) for pesticide degradation applications including related cells, polypeptides, and vectors.

A method of using a metal organic framework (MOF) comprising a metal ion and an at least bidendate organic ligand to catalytically detoxify chemical warfare nerve agents including exposing the metal-organic-framework (MOF) to the chemical warfare nerve agent and catalytically decomposing the nerve agent with the MOF.

The present invention provides a composition and a method of using the composition to decontaminate surfaces or objects that have opioid contamination, and in particular to decontaminate fentanyls on surfaces using an opioid-active reagent and an opioid-effective solubilizing agent. Preferably, the opioid-active reagent is chlorine dioxide.

Enzyme-immobilizing MOFs and methods for their use in enzymatically catalyzed reactions are provided. The MOFs are channel-type MOFs that present a hierarchical pore structure comprising a first set of large channels sized for enzyme immobilization and a second set of smaller channels running alongside of the large channels that remain enzyme-free and allow for reactant delivery to the enzymes and product expulsion from the larger channels.

An improved formulation may include an enhanced ability relative to its predicates to destroy toxic threats in the form of sporulated bacteria, bacteria protected by biofilms, planktonic bacteria, fungus, viruses, chemical weapons, toxic chemicals including Fentanyl, its analogs, and a whole host of toxic industrial chemicals. The formulation may include a three part product composed of a buffered detergent chemical system, a hydrogen peroxide chemical system and an accelerator system designed to deliver activated peroxygen species when blended together.

The present invention is directed towards a composition for decontaminating surfaces contaminated with toxic chemicals/substances, comprising at least one type of metal oxyhydroxide such as zirconium hydroxide, Zr(OH).sub.4, optionally with added water for hydration of the solid, mixed into a carrier liquid used for application to a contaminated surface.

Disclosed herein are non-wild-type organophosphorus acid anhydrolases having two site mutations, methods of production, and methods of use to effectively degrade toxic chemicals such as ((RS)-Propan-2-yl methylphosphonofluoridate) (Sarin) and other organophosphorus compounds.