Provided are: a method for producing a mycrosporine-like amino acid (MAA) that includes a step in which microbes are cultivated that produce MAA on the outside of bacterial cells, a step in which the bacterial cells and extracellular culture fluid are separated, and a step in which the MAA is recovered from the extracellular culture fluid; an MAA indicated by formula (1), an MAA produced using this method, or an ultraviolet-absorbing composition including the MAA indicated by formula (1); and a composition including the MAA produced using this method or the MAA indicated by formula (1), for preventing at least one symptom or disease selected from a group comprising acute skin reactions, aging of the skin, and skin cancer. ##STR00001##

Provided are: a method for producing a mycrosporine-like amino acid (MAA) that includes a step in which microbes are cultivated that produce MAA on the outside of bacterial cells, a step in which the bacterial cells and extracellular culture fluid are separated, and a step in which the MAA is recovered from the extracellular culture fluid; an MAA indicated by formula (1), an MAA produced using this method, or an ultraviolet-absorbing composition including the MAA indicated by formula (1); and a composition including the MAA produced using this method or the MAA indicated by formula (1), for preventing at least one symptom or disease selected from a group comprising acute skin reactions, aging of the skin, and skin cancer. ##STR00001##

A compound:

##STR00001##

and double bond regioisomers thereof.

A compound:

##STR00001##

and double bond regioisomers thereof.

The present invention discloses a catalytic system for preparing highly branched alkane from olefin, which contains novel nickel or palladium complexes. In the presence of the catalytic system, highly branched oily alkane mixture can be efficiently obtained from olefins (such as ethylene) under mild conditions. The alkane mixture has a low bromine number, and can be used as a processing aid(s) and lubricant base oil with high-performance. Provides also was a method for preparing the catalyst and a method for preparing an oily olefin polymer.

The present invention discloses a catalytic system for preparing highly branched alkane from olefin, which contains novel nickel or palladium complexes. In the presence of the catalytic system, highly branched oily alkane mixture can be efficiently obtained from olefins (such as ethylene) under mild conditions. The alkane mixture has a low bromine number, and can be used as a processing aid(s) and lubricant base oil with high-performance. Provides also was a method for preparing the catalyst and a method for preparing an oily olefin polymer.

The present technology relates to UV radiation-absorbing and/or visible radiation-absorbing compounds, and use of same in the preparation of compositions for protecting biological and nonbiological material against UV and/or visible radiation. Specifically, the compounds of the present technology may be used in the preparation of compositions for protecting biological or non-biological material against UV radiation, in particular UVA, UVB, UVC or visible radiation, or any combinations thereof. The biological material can be skin and the composition and/or the formulation can be a cosmetic or personal care composition, such as a sunscreen composition. The non-biological material can be an article of manufacture such as a textile or fabric.

The present technology relates to UV radiation-absorbing and/or visible radiation-absorbing compounds, and use of same in the preparation of compositions for protecting biological and nonbiological material against UV and/or visible radiation. Specifically, the compounds of the present technology may be used in the preparation of compositions for protecting biological or non-biological material against UV radiation, in particular UVA, UVB, UVC or visible radiation, or any combinations thereof. The biological material can be skin and the composition and/or the formulation can be a cosmetic or personal care composition, such as a sunscreen composition. The non-biological material can be an article of manufacture such as a textile or fabric.

An azasteroid mimic or an intermediate for the preparation of an azasteroid and azasteroid mimic is formed via an oxocycloalkenyl isoxazolium anhydrobase and its dimer. The dimer can be used to form mono- and dihydrazones, which can be an azasteroid mimic or an intermediate for the preparation of an azasteroid and azasteroid mimic. A method of preparation of the dimer and the azasteroid mimic or an intermediate for the preparation of an azasteroid and azasteroid mimic occurs with hydrazonation and, optionally, a subsequent dehydrazonation. The dimer can be converted by inserting a nitrogen atom into the six membered ring of to a C-17 position cyclohexenone moiety of the dimer to yield a reduced tetrazolo[1,5-a]azepin-8-yl group. A subsequent hydrozone formation at a benzylic ketone can be carried out to generate an azasteroid mimic with a (triazol-4-yl)imino substituent. Monohydrazones can be converted to their thione equivalents.

An azasteroid mimic or an intermediate for the preparation of an azasteroid and azasteroid mimic is formed via an oxocycloalkenyl isoxazolium anhydrobase and its dimer. The dimer can be used to form mono- and dihydrazones, which can be an azasteroid mimic or an intermediate for the preparation of an azasteroid and azasteroid mimic. A method of preparation of the dimer and the azasteroid mimic or an intermediate for the preparation of an azasteroid and azasteroid mimic occurs with hydrazonation and, optionally, a subsequent dehydrazonation. The dimer can be converted by inserting a nitrogen atom into the six membered ring of to a C-17 position cyclohexenone moiety of the dimer to yield a reduced tetrazolo[1,5-a]azepin-8-yl group. A subsequent hydrozone formation at a benzylic ketone can be carried out to generate an azasteroid mimic with a (triazol-4-yl)imino substituent. Monohydrazones can be converted to their thione equivalents.