Provided is a solid acid catalyst for use in oxidation of a substrate in the coexistence of oxygen and ozone (solid acid catalyst for oxygen-ozone-coexisting oxidation). The solid acid catalyst enables oxidation of the substrate with a high conversion. This solid acid catalyst for oxygen-ozone-coexisting oxidation is a solid acid catalyst for use in an oxidation reaction to oxidize a substrate (A) in the coexistence of oxygen and ozone. The solid acid catalyst includes a transition metal in the form of an elementary substance, a compound, or an ion, and a support supporting the transition metal. The support includes, at least in its surface, a strong acid or super strong acid having a Hammett acidity function (H.sub.0) of −9 or less. The support is preferably a pellet or particle made of a fluorinated sulfonic acid resin, or a support including a solid and a layer of a fluorinated sulfonic acid resin disposed on the solid.

The present application relates to compounds and methods for reducing the severity of convulsant activity or epileptic seizures, or for the treatment of chronic or acute pain.

The present application relates to compounds and methods for reducing the severity of convulsant activity or epileptic seizures, or for the treatment of chronic or acute pain.

The present invention relates to methods to use cyclohexan-1,2-dione (CHD) groups to attach labels, linkers, and other molecules to a target compound comprising a CHD-reactive group such as a guanidine, amidine, urea, thiourea and the like. Methods of the invention include milder conditions than those previously known for promoting reaction of CHD with CHD-reactive groups, which makes the methods suitable for use with base-sensitive compounds and complex biomolecules. Methods of the invention are especially useful for attaching linking and labeling groups to a peptide that comprises at least one arginine residue, and can also be used to link such peptides to other target molecules such as nucleic acids. The invention also provides CHD-containing conjugation reagents and compositions comprising CHD-containing intermediates, and precursors useful for making CHD-containing compounds that can be used in the methods of the invention.

The present invention relates to a novel synthetic pathway for alpha-tocopherol. The invention discloses different reactions yielding some new intermediates in a very high yield and stereoselectivity.

Crystalline molecular framework:small molecule compounds. The molecular framework is formed from guanidinium cations and organosulfonate anions and the guanidinium cations and organosulfonate anions are associated via one or more hydrogen bond. The small molecule(s) is/are encapsulated by the molecular framework. Methods for making crystalline molecular framework:small molecule compounds may include combining guanidinium cations, organosulfonate anions, and small molecules in a single step. The crystalline molecular framework:small molecule compounds can be used to determine the structure of the small molecule(s).

Crystalline molecular framework:small molecule compounds. The molecular framework is formed from guanidinium cations and organosulfonate anions and the guanidinium cations and organosulfonate anions are associated via one or more hydrogen bond. The small molecule(s) is/are encapsulated by the molecular framework. Methods for making crystalline molecular framework:small molecule compounds may include combining guanidinium cations, organosulfonate anions, and small molecules in a single step. The crystalline molecular framework:small molecule compounds can be used to determine the structure of the small molecule(s).

The present invention relates to methods to use cyclohexan-1,2-dione (CHD) groups to attach labels, linkers, and other molecules to a target compound comprising a CHD-reactive group such as a guanidine, amidine, urea, thiourea and the like. Methods of the invention include milder conditions than those previously known for promoting reaction of CHD with CHD-reactive groups, which makes the methods suitable for use with base-sensitive compounds and complex biomolecules. Methods of the invention are especially useful for attaching linking and labeling groups to a peptide that comprises at least one arginine residue, and can also be used to link such peptides to other target molecules such as nucleic acids. The invention also provides CHD-containing conjugation reagents and compositions comprising CHD-containing intermediates, and precursors useful for making CHD-containing compounds that can be used in the methods of the invention.

The present invention relates to methods to use cyclohexan-1,2-dione (CHD) groups to attach labels, linkers, and other molecules to a target compound comprising a CHD-reactive group such as a guanidine, amidine, urea, thiourea and the like. Methods of the invention include milder conditions than those previously known for promoting reaction of CHD with CHD-reactive groups, which makes the methods suitable for use with base-sensitive compounds and complex biomolecules. Methods of the invention are especially useful for attaching linking and labeling groups to a peptide that comprises at least one arginine residue, and can also be used to link such peptides to other target molecules such as nucleic acids. The invention also provides CHD-containing conjugation reagents and compositions comprising CHD-containing intermediates, and precursors useful for making CHD-containing compounds that can be used in the methods of the invention.

A hydrocarbon compound and carbon monoxide are reacted in the presence of either a supported chromium (VI) catalyst or a supported chromium (II) catalyst, optionally with UV-visible light irradiation and/or exposure to an oxidizing atmosphere, followed by removing a reaction product containing an alcohol compound and/or a carbonyl compound from the respective chromium catalyst. Often, the reaction product contains one or more ketone and/or aldehyde compounds.