Borane, reduction acids

This is one of the few methods available for the direct and efficient conversion of an acid, via the acid chloride, to an ortho ester. The preparation of the oxetane is straightforward, and a large number of oxetanes have been prepared [triol, (EtO)2CO, KOH]." In addition, the -butyl analogue has been used for the protection of acids. During the course of a borane reduction, the ortho ester was reduced to form a ketal. This was attributed to an intramolecular delivery of the hydride. ... 

Investigations in our laboratory by Rebecca Stimson have demonstrated that it is possible to combine the borane reduction of a metal acyl with the Lewis acid promoted CO insertion reaction which has been discussed earlier in this paper (29). In this reaction, which is presumed to proceed by equation 17, the... 

This observation has led to the preparation of more effective bicyclic oxaza-borolidines such as 1, prepared from (S)-(-)-2-(diphenylhydroxymethyl)pyrrolidine and BH3 (la) or methylboronic acid (lb). Both reagents catalyze borane reduction of alkyl aryl ketones to furnish (R)-alcohols in > 95% ee, by face-selective hydride transfer within a complex such as B. Catalyst lb is somewhat more effective than... 

Related to this reaction is the acid treatment of the (l-hydFoxymethylcyclohexadiene)tricarbonyliron (45), prepared via DIBAL-H reduction of ester (26) or borane reduction of the corresponding carboxylic acid, which leads to the 1-methylcyclohexadienyliron complex (46 equation 18).11 Using these methods, it is therefore possible to prepare a range of alkyl-substituted dienyl complexes having a defined substitution pattern. 

Scheme 11.1 also summarizes other impressive examples of the performance of the CBS method [1-8]. Several excellent reviews on the CBS method have appeared recently [1, 2], and no detailed discussion of the development of the process or substrate scope shall be presented in this review. Please note, however, that the oxazaborolidine-catalyzed borane reduction of ketones is a prime example of bi-functional catalysis [2, 9] - as shown in Scheme 11.2, the current mechanistic picture involves simultaneous binding of both the ketone and the borane to the Lewis-acidic (boron) and Lewis-basic (nitrogen) sites of the catalyst A. In the resulting ternary complex B, the reaction partners are synergistically activated toward hydride transfer. 

Conversion to benzazepine was achieved under acidic conditions via hydrogenation in alcoholic solvents to form 25, which did not require isolation. Intermediate 25 was directly cyclized under basic conditions to give crystalline lactam 26. The base-mediated ring closure proceeded from the cis/trans mixture of 25 by epimerization of the benzylic methine permitting formation of the cyclic amide from the cis isomer. Finally, conversion of 26 to the desired benzazepine (8) was accomplished by in situ borane reduction and 8 was isolated as the tosylate salt in 81% yield. 

There is a second effect. In the transition state in which the stronger Lewis acid complexes the carbonyl oxygen, the carbonyl group is a better electrophile. Therefore, it becomes a better hydride acceptor for Brown s chloroborane than in the hydride transfer from Alpine-Borane. Reductions with Alpine-Borane can actually be so slow that decomposition of this reagent into a-pincnc and 9-BBN takes place as a competing side reaction. The presence of this 9-BBN is problematic because it reduces the carbonyl compound competitively and of course without enantiocontrol. 

Macrocyclic diamine 14 and triglycolic acid dichloride 15 were condensed under high-dilution conditions to form 16 in 45 % yield. Subsequent reduction of 16 using diborane yielded the [2.2.2]cryptand as the bis-borane adduct. Acidic work-up with 6 N hydrochloric acid afforded 7 in 90% yield. 

Hemiacetals are formed from hydroxy aldehydes " or ketones which are usually first in a protected form and are deblocked prior to cyclization. Ozonolysis of cyclohexene derivative 5 and reductive workup, followed by hydrolysis of the acid chloride formed in situ and borane reduction of the carboxylic acid, leads to the six-membered hemiacetal 6. a precursor for fluo-rinated sugars that are potentially versatile as molecular probes in the elucidation of biochemical processes. ... 

The in situ generated catalyst from ATBH and trimethyl borate has also been used in the stereoselective reduction of a-oxoketoxime ethers to prepare the corresponding chiral 1,2-amino alcohols. Thus the asymmetric borane reduction of buta-2,3-dione monoxime ether followed by acidic work-up and subsequent reaction with benzyloxycarbonyl chloride affords a 90% yield of 7V-(Z)-3-aminobutan-2-ol with excellent enantioselectivities (eq 5). A trityl group in the oxime ether is required for high enantioselectivity. This method has been successively applied to both cyclic and acyclic a-oxoketoxime ethers. 

Oxazaborolidines have been found to be a unique catalyst for asymmetric borane reduction of ketones and imines [35,36]. Coordination of BH3 to the nitrogen atom of 24 serves to activate BH3 as a hydride donor and to increase the Lewis acidity of the boron atom (Eq. 9). The Lewis acidity of the boron atom in the oxazaborolidine plays an important role in the reduction. Several types of polymer-supported oxazaborolidine have been reported and are considered to be polymer-supported boron-based Lewis acids. 

Zagorevskii et al. have observed the same stereoselective trans reduction with several tetrahydro-T-carbolines by generating the diborane from NaBIlt in situ (equation 79).As expected, treatment of these carbolines with pyridine-borane and acid gives the cw-fused isomers (equation 80).Bosch and coworkers have also utilized an in situ generation of diborane to effect the chemoselective reduction of the indole double bond during the synthesis of a new indolomorphan. 

The C-4 acids (183 and 184) have also been subjected to borane reduction conditions to afford alcohol 195 in 23-50% yield or 64% yield as the C-8 epimeric mixture (195 and 196, Scheme 29) [34, 49, 64]. The C-8 alcohol epimers 195 and 196 have been treated separately as a common intermediate for a number of C-4 derivatives including esters, ethers, and amines [34, 49, 64], Alcohols 195 and 196 was subjected to DCC, DMAP, and desired acid chloride or carboxylic acid in CH2CI2 affording ester analogs in 50-92% yield [64], Esters prepared include alkyl, aryl, and fluorenylmethyloxycarbonyl (Fmoc) protected amino acid derivatives (197 and 198) [64]. Ethers were prepared with various alkyl halides and Ag20 in CH3CN at 40 °C. Alkyl, allyl, and benzyl ethers were prepared in 45-80% yield (199 and 200) [34,64]. Alcohols 195 and 196 were then activated to the triflates and displaced by a variety of amines by treatment with trifluoromethanesulfonic anhydride and desired amine in 22% - quantitative yield over two steps (201 and 202)... 

As in other electroless processes, chemical reduction of ions such as Fe2+, Cu2+, Ag+, Au+, Pd2+, and Pt4+ from their aqueous solutions is carried out using various reducing agents to produce different shapes of nanoparticles. Depending on metal, typical reducing agents involve borohydride, dimethyl amino borane, ascorbic acid, hydrazine, formaldehyde, etc. 

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