Diazoketones, reduction

The reaction of ADC compounds with carbenes and their precursors has already been discussed in Section IV,A- In general, the heterocyclic products are not the result of 1,2-addition but of 1,4-addition of the carbene to the —N=N—C=0 system.1 Thus the ADC compound reacts as a 4n unit in a cheletropic reaction leading to the formation of 1,3,4-oxadiazolines. Recent applications include the preparation of spiro-1,3,4-oxadiazolines from cyclic diazoketones and DEAZD as shown in Eq. (14),133 and the synthesis of the acyl derivatives 85 from the pyridinium salts 86.134 The acyl derivatives 85 are readily converted into a-hydroxyketones by a sequence of hydrolysis and reduction reactions. 

Acid chlorides, reduction to aldehydes, 53, 55 Acid chlorides, aromatic, diazoketones from, 53, 37... 

Diiron enneacarbonyl, 50, 2J Diketones, from diazoketones and organoboranes, 53/ 82 3-DIKETONES FROM METHYL ALKYL KETONES 3-n-BUTYL-2,4-PENTANEDIONE, 51, 90 2,6-Dimethoxybenzaldehyde, by reduction of 2,6-dime thoxy-benzonitrile with Raney nickel alloy in formic acid,... 

Diazomethane is generated by the reaction of aqueous NaOH with N-methyl-N-nitroso-p-toluenesulfonamide (Diazald ) in DMSO. The diazomethane is generated quantitatively and is removed by a stream of N2 into a packed column containing a stream of mixed anhydride formed from an N-protected (BOC or CBZ) amino acid and ethyl chloroformate. The diazoketone is converted to the chloroketone using HCI, as shown in Scheme 11.10. The chiral epoxide can then be formed via diastereoselective reduction with NaBH4 and treatment with base. 

Rhodium(II) acetate catalyzes C—H insertion, olefin addition, heteroatom-H insertion, and ylide formation of a-diazocarbonyls via a rhodium carbenoid species (144—147). Intramolecular cyclopentane formation via C—H insertion occurs with retention of stereochemistry (143). Chiral rhodium (TT) carboxamides catalyze enantioselective cyclopropanation and intramolecular C—N insertions of CC-diazoketones (148). Other reactions catalyzed by rhodium complexes include double-bond migration (140), hydrogenation of aromatic aldehydes and ketones to hydrocarbons (150), homologation of esters (151), carbonylation of formaldehyde (152) and amines (140), reductive carbonylation of dimethyl ether or methyl acetate to 1,1-diacetoxy ethane (153), decarbonylation of aldehydes (140), water gas shift reaction (69,154), C—C skeletal rearrangements (132,140), oxidation of olefins to ketones (155) and aldehydes (156), and oxidation of substituted anthracenes to anthraquinones (157). Rhodium-catalyzed hydrosilation of olefins, alkynes, carbonyls, alcohols, and imines is facile and may also be accomplished enantioselectively (140). Rhodium complexes are moderately active alkene and alkyne polymerization catalysts (140). In some cases polymer-supported versions of homogeneous rhodium catalysts have improved activity, compared to their homogenous counterparts. This is the case for the conversion of alkenes direcdy to alcohols under oxo conditions by rhodium—amine polymer catalysts... 

The intramolecular cyclopropanation of appropriate y,(5-unsaturated a-diazoketones following a stereoselective catalytic reduction of the cyclopropyl ketone group provides a useful approach in diterpenoid synthesis. Some examples of the use of the cyclopropanation-reductive cleavage approach in synthesis are shown in equations 67 and 68l0f103. 

One method for the synthesis of hydroxyalkyl-substituted P-lactams is by the Staudinger reaction, the most frequently used method for the synthesis of P-lactams.86 This method for the preparation of 4-acetoxy- and 4-formyl-substituted P-lactams involves the use of diazoketones prepared from amino acids. These diazoketones are precursors for ketenes, in a diastereoselective, photochemically induced reaction to produce exclusively tram-substituted P-lactams. The use of cinnamaldimines 96, considered as vinylogous benzaldimines, resulted in the formation of styryl-substituted P-lactams. Ozonolysis, followed by reductive workup with dimethyl sulfide, led to the formation of the aldehyde 97, whereas addition of trimethyl orthoformate permitted the production of the dimethyl acetal 98 (Scheme 11.26). 

A convenient synthesis of epoxide 38 was developed using commercially available Boc-protected phenylalanine.38 As shown in Scheme 11, protected phenylalanine 44 was converted to alcohol 45 in a three-step sequence, involving (1) reaction of 44 with isobutyl chloroformate followed by diazomethane to give the corresponding diazoketone, (2) treatment of the diazoketone with HCI to provide the corresponding chloroketone, and (3) reduction of the resulting ketone with NaBH4 to provide 45 in 52% overall yield. Treatment of 45 with alcoholic KOH furnished epoxide 38 in 99% yield. 

A wide variety of methods have been described for the synthesis of variously substituted phenethylamines. Some frequently used procedures are presented in Scheme 1. Most of these have been discussed in previous reviews (305, 306). Condensation of an appropriately substituted benzaldehyde with nitromethane followed by reduction of the nitrostyrene (Method A) has proved to be a versatile method which has been employed by numerous workers (cf. 306, 358). Another common method (Method B) affords the amines by reduction of substituted phenylacetonitriles obtained via benzylchlorides (cf.. 306) or benzylamines (307). Reduction of phenylacetamides with lithium aluminum hydride (Method C) has also been applied successfully (308, 309). The substituted phenylacetamides were obtained either via diazoketones by an Amdt-Eistert synthesis (308) or by transformation of the corresponding acetophenones (310). 

Dehydroalanine 116 desmosine 48, 49 diazo compounds 157 aryl diazonium salts, reactive properties 157 synthesis 160 diazoacetates, analysis of products 165 reactive properties 162 synthesis 164 diazoketones, analysis of products 162 conversion to haloketones 139 reactive properties 165 synthesis 140 diazomethane preparation 141 reactive properties 162 diazonium salts 89 diazonium-IH-tetrazole 90, 95 3,4-dihydroxyproline 52, 53 diimidoesters 69 diisopropylfluorophosphate 130 2,3-dimethylmaleic anhydride 83 dinitrophenylation 79 disulfide bond reduction 103... 

West and Naidu found that the diazoketone 358, prepared by alkylating the benzyl ester of L-proline with 5-bromo-l-diazopentan-2-one, cyclized to give a transient spirobicyclic ammonium ylide 359 when heated with coppeifll) acetylacetonate in toluene (Scheme 44) (355,356). This unstable ylide underwent a diastereoselective [1,2]-Stevens rearrangement to give the quinolizidinone 360 and its bridgehead epimer in a ratio of 95 5. However, some racemization (possibly through an achiral diradical intermediate) must have occurred, since 360 had an ee of only 75%. Reduction of the ester and defimctionalization of thioketal 361 with the unusual combination of sodium and hydrazine in hot ethylene glycol completed a synthesis of the unnatural (- )-enantiomer of epilupinine (ent-331). 

Two short syntheses of racemic ipalbidine ( )-(842) are shown in Scheme 109. The synthesis by Jefford et al. commenced with conjugate addition between pyrrole and Ae atropate ester 849 followed by homologation of the acid 850 with diazomethane and rhodium-induced intramolecular carbene cyclization of the resulting diazoketone 851 (574). The bicyclic product 852 was converted into ( )-842 in a further four steps. The approach taken by Danishefsky and Vogel centered on acid-catalyzed cyclocondensation between the silyl ketene acetal 853 and A -pyrroline (854) to give indolizidinone 855 (575). Reduction of the lactam and cleavage of the aryl ether completed the synthesis of ( )-842. 

Ketone (8) has a three-membered ring and another, protected, ketone group. Disconnection of the three-membered ring is guided by the availability of diazoketones (9) (Chapter 31). Intermediate (10) is clearly a Birch reduction product (Chapter 37). 

Reduction of the carbonyl group in cyclic and acylic 2-diazo- 1,3-diketones (129, 135-137, 143, 146, and 196) with NaBH in aqueous alcoholic solution, followed by hydrolysis of the reaction mixture over wet silica gel, affords the corresponding 3-hydroxy-2-diazoketones (190-195 and 197) in 58-87% yield.85 Steric hindrance at a to the carbonyl decreases the yield of reduced products.85... 

Reduction of a,p-unsaturated y-lactones to furanes (1,262). Pelletier et al. have developed a general method for conversion of 2(5H)-furanones (1) into substituted furanes (4). The method involves cycloaddition of diazoalkanes, diazo esters, and diazoketones, followed by decomposition to alkylated 2(5H)-furanones (3). The final step involves reduction with diisobutylaluminum hydride. 

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