The present invention describes novel methods for using Treprostinil or its derivative, or a pharmaceutically acceptable salt thereof, for the treatment and/or prevention of ischemic lesions, such as digital ulcers, in subjects with scleroderma (including systemic sclerosis), Buerger's disease, Raynaud's disease, Raynaud's phenomenon and/or other conditions that cause such lesions. The invention also relates to kits for treatment and/or prevention of ischemic lesions, comprising an effective amount of Treprostinil or its derivative, or a pharmaceutically acceptable salt thereof.

The present invention describes novel methods for using Treprostinil or its derivative, or a pharmaceutically acceptable salt thereof, for the treatment and/or prevention of ischemic lesions, such as digital ulcers, in subjects with scleroderma (including systemic sclerosis), Buerger's disease, Raynaud's disease, Raynaud's phenomenon and/or other conditions that cause such lesions. The invention also relates to kits for treatment and/or prevention of ischemic lesions, comprising an effective amount of Treprostinil or its derivative, or a pharmaceutically acceptable salt thereof.

Provided herein is a method of using threonate to alter cellular physiology, such as neuronal physiology. A method of the present disclosure may include providing to a medium comprising a cell, a threonate-containing compound, or a precursor thereof, to increase the concentration of threonate in the medium, where the increased concentration of threonate is sufficient to increase the concentration of magnesium in the cell. Also provided is a method that includes administering a threonate-containing compound, or a precursor thereof, to an individual, to increase synaptic density in the brain and/or to treat a neurological disorder, e.g., cognitive impairment. The threonate-containing compound of the present disclosure does not include magnesium threonate.

Provided herein is a method of using threonate to alter cellular physiology, such as neuronal physiology. A method of the present disclosure may include providing to a medium comprising a cell, a threonate-containing compound, or a precursor thereof, to increase the concentration of threonate in the medium, where the increased concentration of threonate is sufficient to increase the concentration of magnesium in the cell. Also provided is a method that includes administering a threonate-containing compound, or a precursor thereof, to an individual, to increase synaptic density in the brain and/or to treat a neurological disorder, e.g., cognitive impairment. The threonate-containing compound of the present disclosure does not include magnesium threonate.

Provided herein is a method of using threonate to alter cellular physiology, such as neuronal physiology. A method of the present disclosure may include providing to a medium comprising a cell, a threonate-containing compound, or a precursor thereof, to increase the concentration of threonate in the medium, where the increased concentration of threonate is sufficient to increase the concentration of magnesium in the cell. Also provided is a method that includes administering a threonate-containing compound, or a precursor thereof, to an individual, to increase synaptic density in the brain and/or to treat a neurological disorder, e.g., cognitive impairment. The threonate-containing compound of the present disclosure does not include magnesium threonate.

A natural water soluble protocatechuic acid and L-theanine cocrystal composition is described. The cocrystal composition may be created by a method including solvent-assisted mechanical grinding. The natural water soluble cocrystal composition is suitable for sublingual administration, preferably to humans.

Disclosed herein are prenatal dosage forms formulated for different stages of the pregnancy cycle. Also disclosed are methods of administering prenatal dosage forms to a prenatal, pregnant or lactating woman. Further disclosed are kits including prenatal dosage forms.

The present composition provides for mitigating adverse effects of alcohol consumption. The composition includes a fructose source comprising between 5% and 75% of a total weight of the composition, a niacinamide source comprising between 0.1% and 1% of the total weight, and a glycoprotein source comprising between 0.1% and 2% of the total weight, wherein the total weight is a weight prior to inclusion with a hydrating source. The composition can be disposed in a powder or dissolved form, as part of a concentrate, and/or part of a beverage. The composition can include mixability for diluting or mixing with the liquid or beverage for user consumption and absorprtion.

The present composition provides for mitigating adverse effects of alcohol consumption. The composition includes a fructose source comprising between 5% and 75% of a total weight of the composition, a niacinamide source comprising between 0.1% and 1% of the total weight, and a glycoprotein source comprising between 0.1% and 2% of the total weight, wherein the total weight is a weight prior to inclusion with a hydrating source. The composition can be disposed in a powder or dissolved form, as part of a concentrate, and/or part of a beverage. The composition can include mixability for diluting or mixing with the liquid or beverage for user consumption and absorprtion.

The invention provides pharmaceutical compositions of berberine ursodeoxycholate (BUDCA) and methods of use thereof for the treatment fatty liver disease, diabetes, hyperlipidemia, and liver fibrosis, and related diseases and conditions.