Abstract: A method for degrading coal tar, coal tar distillation fractions, and organic compounds, specially those compounds having three or more fused rings of the type often associated with coal tar, whether derived from coal tar or synthesized independently. According to the present invention degradation takes place by means of the nonspecific degradation reaction used by white rot fungi to degrade lignin. The degradation reaction occurs in part by means of a lignin degrading enzyme and hydrogen peroxide, both produced by white rot fungi.

Abstract: This invention describes a method for catalyzing sequential reductive dehalogenation reactions on aliphatic halocarbons using free radical intermediates. More specifically, this invention involves the use of biologically derived peroxidases in the generation of a variety of oxidation or reduction agents consisting of cation radicals, anion radicals, neutral radicals, or oxygen radicals. Such oxidation and reduction agents can be employed in combination to carry out sequential reductive dehalogenation reactions on aliphatic halocarbons to thereby degrade various recalcitrant organic compounds such as organic environmental pollutants.

Abstract: Composition and methods; for carrying out a variety of oxidation reactions, reduction reactions, or both utilizing a free radical generating catalyst, a mediator, and a reductant are disclosed. The free radical generating catalyst is generally a peroxidase obtained from living organisms, such as white rot fungi. Suitable peroxidases include lignin peroxidase, horse radish peroxidase, and lactoperoxidase. Suitable mediators include veratryl alcohol, iodine, methoxybenzenes, Mn II, and ABTS. Suitable reductants include EDTA, oxalate, hydroquinones, quinones plus quinone reductase, and hydrogen peroxide.

Abstract: A method for degrading coal tar, coal tar distillation fractions, and organic compounds specifically those compounds having three or more fused rings, of the type often associated with coal tar, whether derived from coal tar or synthesized independently. According to the present invention degradation takes place by means of the nonspecific degradation reaction used by Phanerochaete chrysoporium to degrade lignin. The degradation reaction occurs in part by means of a lignin degrading enzyme and hydrogen peroxide, both produced by Phanerochaete chrysoporium.

Abstract: Composition and methods for carrying out a variety of oxidation reactions, reduction reactions, or both utilizing a free radical generating catalyst, a mediator, and a reductant are disclosed, The free radical generating catalyst is generally a peroxidase obtained from living organisms, such as white rot fungi. Suitable peroxidases include lignin peroxidase, horse radish peroxidase, and lactoperoxidase. Suitable mediators include veratryl alcohol, iodine, methoxybenzenes, Mn II, and ABTS. Suitable reductants include EDTA, oxalate, hydroquinones, quinones plus quinone reductase, and hydrogen peroxide. The free radical generating catalyst is generally activated in the presence of hydrogen peroxide and reacts with the mediator to form the free radical of the mediator, which is an oxidant. The free radical of the mediator in turn reacts with the reductant to form the free radical of the reductant, which is also a reductant.

Abstract: There is provided a process for biodegradation of TNT (2,4,6-Trinitrotoluene) wherein the biodegradation is done utilizing the fungus Phanerochaete chrysosporium strain BKM F-1767, wherein waste containing TNT is treated with the fungus under predetermined conditioning and for a time period sufficient for biodegradation to occur rendering the waste ecologically acceptable to the environment.

Abstract: A process for degrading environmentally persistent organic pollutant compounds by reacting those pollutant compounds with fungal enzymes containing a lignin-degrading enzyme and hydrogen peroxide. This reaction preferably takes place under aerobic conditions such that the organic pollutant compounds are degraded. Using the present invention, degradation to carbon dioxide and water is possible. Alternatively, the reaction may be halted to leave desirable reaction intermediates.The enzyme and hydrogen peroxide system of the present invention is found to be ideal for degrading various types of orgaic pollutants. Moreover, the reaction system is nonspecific. As a result, only a single type of fungus or fungus-generated enzyme system is required in order to degrade a wide spectrum of pollutants.One embodiment of the present invention relates to a preferred process where the enzyme (peroxidase) and hydrogen peroxide are provided by a lignin-degrading fungi or fungi mixed with the pollutant organic compound.