Formate esters, from aldehydes

Verma et al. [62] observed a chemoselective behavior of iodine in diSeient solvents in the electrophilic iodocyclization of o-alkynyl aldehydes. o-Alkynyl aldehydes on reaction with in CH C with appropriate nucleophiles provided pyrano[4,3-6]quinolines 40 via the formation of cyclic iodonium intermediate 39. In case of using alcohols as a solvent as well as nucleophile, o-alkynyl esters 42 were obtained selectively in good to excellent yields via the formation of hypoio-dide intermediate 41. Subsequently, o-alkynyl esters 42 were converted into py-ranoquinolinones and isocoumarins by electrophilic iodocyclization. The developed oxidative esterification provides a novel access for the chemoselective synthesis of esters 43 from aldehydes without oxidizing primary alcohol present in the substrate (Scheme 10.28). 

The dynamic resolution of an aldehyde is shown in Figure 8.40. The racemization of starting aldehyde and enantioselective reduction of carbonyl group by baker s yeast resulted in the formation of chiral carbon centers. The enantiomeric excess value of the product was improved from 19 to 90% by changing the ester moiety from the isopropyl group to the neopentyl group [30a]. 

Due to the retractive forces in stretched mbber, the aldehyde and zwitterion fragments are separated at the molecular-relaxation rate. Therefore, the ozonides and peroxides form at sites remote from the initial cleavage, and underlying mbber chains are exposed to ozone. These unstable ozonides and polymeric peroxides cleave to a variety of oxygenated products, such as acids, esters, ketones, and aldehydes, and also expose new mbber chains to the effects of ozone. The net result is that when mbber chains are cleaved, they retract in the direction of the stress and expose underlying unsaturation. Continuation of this process results in the formation of the characteristic ozone cracks. It should be noted that in the case of butadiene mbbers a small amount of cross-linking occurs during ozonation. This is considered to be due to the reaction between the biradical of the carbonyl oxide and the double bonds of the butadiene mbber [47]. 

The addition of Grignard reagents to aldehydes, ketones, and esters is the basis for the synthesis of a wide variety of alcohols, and several examples are given in Scheme 7.3. Primary alcohols can be made from formaldehyde (Entry 1) or, with addition of two carbons, from ethylene oxide (Entry 2). Secondary alcohols are obtained from aldehydes (Entries 3 to 6) or formate esters (Entry 7). Tertiary alcohols can be made from esters (Entries 8 and 9) or ketones (Entry 10). Lactones give diols (Entry 11). Aldehydes can be prepared from trialkyl orthoformate esters (Entries 12 and 13). Ketones can be made from nitriles (Entries 14 and 15), pyridine-2-thiol esters (Entry 16), N-methoxy-A-methyl carboxamides (Entries 17 and 18), or anhydrides (Entry 19). Carboxylic acids are available by reaction with C02 (Entries 20 to 22). Amines can be prepared from imines (Entry 23). Two-step procedures that involve formation and dehydration of alcohols provide routes to certain alkenes (Entries 24 and 25). 

For instance, 2-methylpropene reacted with acetic acid at 18°C in the presence of Al-bentonite to form the ester product (75). Ion-exchanged bentonites are also efficient catalysts for formation of ketals from aldehydes or ketones. Cyclohexanone reacted with methanol in the presence of Al-bentonite at room temperature to give 33% yield of dimethyl ketal after 30 min of reaction time. On addition of the same clay to the mixture of cyclohexanone and trimethyl orthoformate at room-temperature, the exothermic reaction caused the liquid to boil and resulted in an almost quantitative yield of the dimethyl ketal in 5 min. When Na- instead of Al-bentonite is used, the same reaction did not take place (75). Solomon and Hawthorne (37) suggest that elimination reactions may have been involved in the geochemical transformation of lipid and other organic sediments into petroleum deposits. 

Parmar et al have developed a method for resolving racemic mixtures of a variety of natural and nonnatural amino acids using the ethyl ester of the amino acid protected at the amino position hy the formation of a Schiff base with an aromatic aldehyde such as /)-chlorobenzaldehyde. Both chymotrypsin and Lip such as porcine Lip gave good yields of the L-amino acid which precipitates out of solution as the amino acid ester released from the imine is cleaved by the hydrolase. 

Another possible mechanism for the racemization of amino acid esters involves the in situ, transient, formation of Schiff s bases by reaction of the amine group of an amino acid ester with an aldehyde. Using this approach, DKR of the methyl esters of proline 5 and pipecolic acid 6 was achieved using lipase A from C. ant-arclica as the enantioselective hydrolytic enzyme and acetaldehyde as the racemiz-ing agent (Scheme 2.4). Interestingly, the acetaldehyde was released in situ from vinyl butanoate, which acted as the acyl donor, in the presence of triethylamine. The use of other reaction additives was also investigated. Yields of up to 97% and up to 97% e.e. were obtained [6]. 

Reductive ring closure of l-(2-nitrobenzyl)-2-pyrrole carbaldehyde 200 results in pyrrolo[2,l-c][l,4]benzodiazepine 201 (Scheme 42 (1999BMCL1737)). On the other hand, oxo derivative 203 can be synthesized starting from aldehyde 200 through a nitrile formation/cyclizations multistep sequence. The alternate synthetic strategy included reduction of the intermediate acid (R = H) or ester (R = Et) 205 followed by CDI or thermal cyclization (1992JHC1005). 

The formation of carbonyl ylides from esters was also observed by a laser photolysis study conducted by Chateauneuf and Liu (6). The formation of ester ylides is much less common than from aldehydes or ketones (Scheme 4.4). 

The reactivity of acidified chlorite solutions is reduced for bleaching some textiles by adding compounds like polyamines, pyrophosphates, and hydrogen peroxide that suppress the formation of chlorine dioxide (57). Another method is to buffer the solution at pH 5—6 to reduce the rate of chlorine dioxide formation. Hydrolysis of anhydrides and esters or oxidation of alcohols can be used to slowly generate acids to promote chlorine dioxide formation (58). Aldehydes also promote chlorine dioxide generation from neutral chlorite solutions, but the effect is greater than simply lowering the pH as they... 

TISHCHENKO REACTION. Formation of esters from aldehydes by an oxidation-reduction process in the presence of aluminum or sodium alkoxidcs. 

The mechanism of diisobutylaluminum hydride reduction involves formation of a six-membered transition state with aluminum complexed to the carbonyl of the ester group, which is required for the delivery of the hydride from the electrophilic aluminum hydride to the carbonyl group. The alkoxy moiety is then displaced during workup resulting in the desired peptide aldehyde. This mechanism accounts for the fact that the reduction stops after the conversion of the ester into the aldehyde. 23 ... 

Chemoselective reduction of methyl ester 7 to aldehyde 2 is possible with DIB AH. The metallatcd hemiacetal that results from addition of DIBAII to the carbonyl group of ail ester usually decomposes rapidly in polar solvents like THF to an intermediate aldehyde This then competes with the ester and, as a result of its higher clcctrophilicity. js reduced by DIBAH to an alcohol. However, ester 7 bears a methoxymethyl residue in its a-position, which stabilizes the metallated hemiacetal by chelate formation. Chelate complex 22 is protolytically cleaved by way of the hemiacetal only in the course of aqueous workup, so in this case the DIBAH reaction produces only aldehyde 2, not the alcohol (see also Chapter 3), DIBAH, THF, -78 C 100. ... 

This topological rule readily explained the reaction product 211 (>90% stereoselectivity) of open-chain nitroolefins 209 with open-chain enamines 210. Seebach and Golinski have further pointed out that several condensation reactions can also be rationalized by using this approach (a) cyclopropane formation from olefin and carbene, (b) Wittig reaction with aldehydes yielding cis olefins, (c) trans-dialkyl oxirane from alkylidene triphenylarsane and aldehydes, (d) ketenes and cyclopentadiene 2+2-addition, le) (E)-silyl-nitronate and aldehydes, (f) syn and anti-Li and B-enolates of ketones, esters, amides and aldehydes, (g) Z-allylboranes and aldehydes, (h) E-alkyl-borane or E-allylchromium derivatives and aldehydes, (i) enamine from cyclohexanone and cinnamic aldehyde, (j) E-enamines and E-nitroolefins and finally, (k) enamines from cycloalkanones and styryl sulfone. 

A direct asymmetric reductive Mannich-type reaction that allows for the formation of three contiguous stereocentres with high chemo-, diastereo-, and enantio-selectivity (10 1 to 50 1 dr, 96-99% ee ) has been presented (Scheme 4). The reaction commences with the formation of the corresponding iminium ion from aldehyde (122) and prolinol (g) catalyst (125), followed by conjugate reduction with Hantzsch ester (123) to generate an enamine, which then undergoes Mannich reaction with imine (124) to produce (126).179... 

The yields from aldehyde alkylidenation is somewhat lower due to the reductive dimerization of aldehydes with low-valent Ti. Alkylidenation of esters is possible by the reaction of 1,1 -dibromoalkane. TiCU and Zn in the presence of TMEDA to give (Z) vinyl ethers [60], Cyclic vinyl ethers are prepared from unsaturated esters in two steps. The first step is formation of the acyclic enol ethers using a stoichiometric amount of the Ti reagent, and the second step is ring-closing alkene metathesis catalysed by Mo complex 19. Thus the benzofiiran moiety of sophora compound I (199, R = H) was synthesized by the carbonyl alkenation of ester in 197 with the Ti reagent prepared in situ, and the subsequent catalytic RCM of the resulting enol ether 198 catalysed by 19 [61]. 

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