This invention discloses 2-methylene-(22E)-25-hexanoyl-24-oxo-26,27-cyclo-22-dehydro-19-nor-vitamin D analogs, and specifically 2-methylene-(22E)-25-hexanoyl-24-oxo-26,27-cyclo-22-dehydro-19-nor-1-hydroxyvitamin D.sub.3, and pharmaceutical uses therefor. This compound exhibits relatively high transcription activity as well as pronounced activity in arresting the proliferation of undifferentiated cells and inducing their differentiation to the monocyte thus evidencing use as an anti-cancer agent and for the treatment of skin diseases such as psoriasis as well as skin conditions such as wrinkles, slack skin, dry skin and insufficient sebum secretion. This compound also shows low activity in vivo on bone calcium mobilization, and therefore may be used to treat autoimmune disorders or inflammatory diseases in humans as well as renal osteodystrophy. This compound may also be used for the treatment or prevention of obesity.

The present disclosure provides for pharmaceutical composition and methods of treating a condition using the pharmaceutical composition. The condition to be treated in a subject in need of treatment can include an infection or non-viral hyper-inflammation/immune hyperactivation condition. The infection can be a coronavirus infection, HIV infection, influenza infection, or the like, where a direct or indirect result of the infection can be respiratory distress, oxidative stress, and the like that can lead to acute respiratory distress syndrome (ARDS) and/or organ dysfunction or failure.

Disclosed is the compound vitamin D.sub.3 phosphate and pharmaceutically acceptable salts thereof, pharmaceutical compositions comprising the compound and methods for preparing the compound. Also disclosed are methods of treating vitamin D deficiency using the compound. The compound is particularly suitable for transdermal delivery.

It is an object of the present invention to provide methods for producing vitamin D that gives improved yields and reduced side product contamination. In various aspects, these methods provide for production of vitamin-D.sub.2 using ergosterol as provitamin D.sub.2 or a dihydroxy derivative thereof as a starting material, or production of vitamin-D.sub.3 using 7-dehydrocholesterol as provitamin D.sub.3 or a dihydroxy derivative thereof as the starting material. The methods described herein comprise irradiating the starting material in a solution including an organic or inorganic base with light in the wavelength range 245-360 nanometers (nm) to obtain a product containing pre-vitamin-D.sub.2 or pre-vitamin-D.sub.3, and heating the product to convert the resulting pre-vitamin-D.sub.2 or pre-vitamin-D.sub.3 to vitamin D.sub.2 or vitamin D.sub.3. In various embodiments, these methods further comprise recovering vitamin D.sub.2 or vitamin D.sub.3 from this reaction as a purified product.

It is an object of the present invention to provide methods for producing vitamin D that gives improved yields and reduced side product contamination. In various aspects, these methods provide for production of vitamin-D.sub.2 using ergosterol as provitamin D.sub.2 or a dihydroxy derivative thereof as a starting material, or production of vitamin-D.sub.3 using 7-dehydrocholesterol as provitamin D.sub.3 or a dihydroxy derivative thereof as the starting material. The methods described herein comprise irradiating the starting material in a solution including an organic or inorganic base with light in the wavelength range 245-360 nanometers (nm) to obtain a product containing pre-vitamin-D.sub.2 or pre-vitamin-D.sub.3, and heating the product to convert the resulting pre-vitamin-D.sub.2 or pre-vitamin-D.sub.3 to vitamin D.sub.2 or vitamin D.sub.3. In various embodiments, these methods further comprise recovering vitamin D.sub.2 or vitamin D.sub.3 from this reaction as a purified product.

The present invention discloses compositions that comprise compounds relating to vitamin D. These compounds are useful for assays in the determination and distinguishing of certain 3-epimeric 25 hydroxyvitamin D and non-epimeric 25 hydroxyvitamin D. The compositions of the present invention may be used for example as immunogens used to develop antibodies to certain vitamin D compounds or conjugates used in assays for certain vitamin D compounds or used as a solid phase reagent in assays. The composition comprises a compound of one or more of the generic formula (R.sup.1).sub.p-(L).sub.q-Z.

The present invention discloses compositions that comprise compounds relating to vitamin D. These compounds are useful for assays in the determination and distinguishing of certain 3-epimeric 25 hydroxyvitamin D and non-epimeric 25 hydroxyvitamin D. The compositions of the present invention may be used for example as immunogens used to develop antibodies to certain vitamin D compounds or conjugates used in assays for certain vitamin D compounds or used as a solid phase reagent in assays. The composition comprises a compound of one or more of the generic formula (R.sup.1).sub.p-(L).sub.q-Z.

An air-stable, high-melt 1a-hydroxy-vitamin D.sub.3 compound, methods for preparing an animal feed composition, methods of preparing 1a-hydroxy-vitamin D.sub.3, methods of enhancing phytate phosphorus and calcium utilization, and an animal feed regime are provided.

An air-stable, high-melt 1a-hydroxy-vitamin D.sub.3 compound, methods for preparing an animal feed composition, methods of preparing 1a-hydroxy-vitamin D.sub.3, methods of enhancing phytate phosphorus and calcium utilization, and an animal feed regime are provided.

It is an object of the present invention to provide methods for producing vitamin D that gives improved yields and reduced side product contamination. In various aspects, these methods provide for production of vitamin-D.sub.2 using ergosterol as provitamin D.sub.2 or a dihydroxy derivative thereof as a starting material, or production of vitamin-D.sub.3 using 7-dehydrocholesterol as provitamin D.sub.3 or a dihydroxy derivative thereof as the starting material. The methods described herein comprise irradiating the starting material in a solution including an organic or inorganic base with light in the wavelength range 245-360 nanometers (nm) to obtain a product containing pre-vitamin-D.sub.2 or pre-vitamin-D.sub.3, and heating the product to convert the resulting pre-vitamin-D.sub.2 or pre-vitamin-D.sub.3 to vitamin D.sub.2 or vitamin D.sub.3. In various embodiments, these methods further comprise recovering vitamin D.sub.2 or vitamin D.sub.3 from this reaction as a purified product.