The present disclosure is directed to fatty-acid glycerol ester derivative compounds containing a targeting bisphosphonate group. The disclosure further includes pharmaceutical or biomedical compositions comprising these compounds, and methods of using these compounds and compositions forming microbubbles. The microbubbles have affinity for metal-containing, especially calcium-containing, bodies and/or biological targets. In certain embodiments, these compositions are useful for providing targeted placement of microbubbles capable of cavitation on application of high frequency energy.

The present disclosure is directed to fatty-acid glycerol ester derivative compounds containing a targeting bisphosphonate group. The disclosure further includes pharmaceutical or biomedical compositions comprising these compounds, and methods of using these compounds and compositions forming microbubbles. The microbubbles have affinity for metal-containing, especially calcium-containing, bodies and/or biological targets. In certain embodiments, these compositions are useful for providing targeted placement of microbubbles capable of cavitation on application of high frequency energy.

Methods of carbohydrate acetylation are disclosed. A method may include adding a carbohydrate to a reaction vessel, adding poly-4-vinylpyriding (P4VP) to the reaction vessel, adding a bio-derived solvent to the reaction vessel, adding acetic anhydride (Ac20) to the reaction vessel, and adding a catalyst to the reaction vessel. The bio-derived solvent may be 2-methyltetrahydrofuran (2-MeTHF). A catalyst may also be added to the reaction vessel.

Methods of carbohydrate acetylation are disclosed. A method may include adding a carbohydrate to a reaction vessel, adding poly-4-vinylpyriding (P4VP) to the reaction vessel, adding a bio-derived solvent to the reaction vessel, adding acetic anhydride (Ac20) to the reaction vessel, and adding a catalyst to the reaction vessel. The bio-derived solvent may be 2-methyltetrahydrofuran (2-MeTHF). A catalyst may also be added to the reaction vessel.

The present disclosure pertains to a new synthetic method for the preparation of 3,6-dimethylhexahydrobenzofuran-2-one, a derivative of mint lactone, and an important organoleptic compound which finds use in the flavor and fragrance industries. Applicants' novel synthetic route is also applicable to other alkene compounds.

Provided is a catalyst for transesterification reactions, which contains an iron salen complex. Also provided is a method for producing an ester compound, which is characterized by carrying out a transesterification reaction between a starting material ester and a starting material alcohol with use of the catalyst.

Provided is a catalyst for transesterification reactions, which contains an iron salen complex. Also provided is a method for producing an ester compound, which is characterized by carrying out a transesterification reaction between a starting material ester and a starting material alcohol with use of the catalyst.

The invention relates to a method for (I) producing a carboxylic ester of formula (I). Said method comprises the steps of: a) bringing an organosilane/borane of formula Si or B into contact with CO.sub.2, in the presence of a catalyst and an electrophilic compound of formula (III), the groups R.sup.1, R.sup.2, R.sup.3, R.sup.4, R.sup.5, Y, and M′ being as defined in claim 1; and optionally b) recovering the compound of formula (I) produced.

##STR00001##

The invention relates to a method for (I) producing a carboxylic ester of formula (I). Said method comprises the steps of: a) bringing an organosilane/borane of formula Si or B into contact with CO.sub.2, in the presence of a catalyst and an electrophilic compound of formula (III), the groups R.sup.1, R.sup.2, R.sup.3, R.sup.4, R.sup.5, Y, and M′ being as defined in claim 1; and optionally b) recovering the compound of formula (I) produced.

##STR00001##

The present invention relates to novel manganese complexes and their use, inter alia, for homogeneous catalysis in (1) the preparation of imine by dehydrogenative coupling of an alcohol and amine; (2) C—C coupling in Michael addition reaction using nitriles as Michael donors; (3) dehydrogenative coupling of alcohols to give esters and hydrogen gas (4) hydrogenation of esters to form alcohols (including hydrogenation of cyclic esters (lactones) or cyclic di-esters (di-lactones), or polyesters); (5) hydrogenation of amides (including cyclic dipeptides, lactams, diamide, polypeptides and polyamides) to alcohols and amines (or diamine); (6) hydrogenation of organic carbonates (including polycarbonates) to alcohols or hydrogenation of carbamates (including polycarbamates) or urea derivatives to alcohols and amines; (7) dehydrogenation of secondary alcohols to ketones; (8) amidation of esters (i.e., synthesis of amides from esters and amines); (9) acylation of alcohols using esters; (10) coupling of alcohols with water and a base to form carboxylic acids; and (11) preparation of amino acids or their salts by coupling of amino alcohols with water and a hydrogenative coupling of alcohols and amines; (13) preparation of imides from diols. ##STR00001## ##STR00002##