Provided herein, in part, is a method of treating a neurological or movement disorder in a patient in need thereof, comprising subcutaneously administering to said patient a pharmaceutically acceptable composition comprising levodopa and optionally carbidopa and optionally entacapone or tolcapone, or pharmaceutically acceptable salts thereof, wherein said composition is administered substantially continuously, and compositions that can be used in the disclosed methods.

Provided herein, in part, is a method of treating a neurological or movement disorder in a patient in need thereof, comprising subcutaneously administering to said patient a pharmaceutically acceptable composition comprising levodopa and optionally carbidopa and optionally entacapone or tolcapone, or pharmaceutically acceptable salts thereof, wherein said composition is administered substantially continuously, and compositions that can be used in the disclosed methods.

An oral cannabis composition comprising molecularly separated cannabinoids, MCT oil and a terpene blend. A method of producing the oral cannabis composition comprising the steps of a) producing cannabis extract by supercritical carbon dioxide extraction; b) after step a), winterizing the cannabis extract; c) after step b), distilling the winterized cannabis extract to produce molecularly separated cannabinoids; d) after step c), mixing the molecularly separated cannabinoids with MCT oil; and e) after step d), mixing the mixture of MCT oil and molecularly separated cannabinoids with a terpene blend. A second method comprises the steps of a) selecting a desired mixture of molecularly separate cannabinoids; b) after step a), mixing the molecularly separated cannabinoids with MCT oil; and c) after step b), mixing the mixture of MCT oil and molecularly separated cannabinoids with a terpene blend.

An oral cannabis composition comprising molecularly separated cannabinoids, MCT oil and a terpene blend. A method of producing the oral cannabis composition comprising the steps of a) producing cannabis extract by supercritical carbon dioxide extraction; b) after step a), winterizing the cannabis extract; c) after step b), distilling the winterized cannabis extract to produce molecularly separated cannabinoids; d) after step c), mixing the molecularly separated cannabinoids with MCT oil; and e) after step d), mixing the mixture of MCT oil and molecularly separated cannabinoids with a terpene blend. A second method comprises the steps of a) selecting a desired mixture of molecularly separate cannabinoids; b) after step a), mixing the molecularly separated cannabinoids with MCT oil; and c) after step b), mixing the mixture of MCT oil and molecularly separated cannabinoids with a terpene blend.

The present application relates to compositions corn-sing a bioactive lipophilic compound, an oil and at least one solubilizing agent that is a compound of Formula (I), to emulsions comprising such compositions and to uses thereof. The present application also relates to methods of preparing such emulsions. The methods comprise heating such compositions to form a homogeneous melt and combining the homogeneous melt with water to obtain the emulsion.

The present application relates to compositions corn-sing a bioactive lipophilic compound, an oil and at least one solubilizing agent that is a compound of Formula (I), to emulsions comprising such compositions and to uses thereof. The present application also relates to methods of preparing such emulsions. The methods comprise heating such compositions to form a homogeneous melt and combining the homogeneous melt with water to obtain the emulsion.

In an embodiment of the invention, a composition for treating a cell population comprises an Affinity Medicant Conjugate (AMC). The medicant moiety can be a toxin including an acylfulvene or a drug moiety. The affinity moiety can be an antibody, a binding protein, a steroid, a lipid, a growth factor, a protein, a peptide or non peptidic. The affinity moiety can be covalently bound to the medicant via a linker. Novel linkers that can be directed to cysteine, arginine or lysine residues based on solution pH allow greater flexibility in preserving and/or generating specific epitopes in the AMC.

In an embodiment of the invention, a composition for treating a cell population comprises an Affinity Medicant Conjugate (AMC). The medicant moiety can be a toxin including an acylfulvene or a drug moiety. The affinity moiety can be an antibody, a binding protein, a steroid, a lipid, a growth factor, a protein, a peptide or non peptidic. The affinity moiety can be covalently bound to the medicant via a linker. Novel linkers that can be directed to cysteine, arginine or lysine residues based on solution pH allow greater flexibility in preserving and/or generating specific epitopes in the AMC.

The present invention provides nutritional compositions that are employed as oral supplementation to the human diet and methods for using such nutritional compositions. The compositions of the present invention provide for supplementation to the diet of the cancer patient, as well as preventative dietary supplementation aimed at supporting the human immune system for those not currently suffering from cancer. Methods are provided that utilize specific combinations of selected forms selenium. chromium, and molybdenum in combination with fish oil.

The present invention provides nutritional compositions that are employed as oral supplementation to the human diet and methods for using such nutritional compositions. The compositions of the present invention provide for supplementation to the diet of the cancer patient, as well as preventative dietary supplementation aimed at supporting the human immune system for those not currently suffering from cancer. Methods are provided that utilize specific combinations of selected forms selenium. chromium, and molybdenum in combination with fish oil.