Homologation ethers

The enthalpy of formation of methyl n-pentyl ether is unavailable from experiment, but a value of —316 kJmoP is obtained from the linear regression analysis of the known enthalpies of formation of methyl n-alkyl ethers vs. the number of carbon atoms in the ethers . The methylene increment of —25.3 kJmoP for this homologous ether series is nearly identical to the methylene increment for n-alkanes. Because the experimental protodelithiation enthalpies for the two primary lithio ethers are identical, the methylene increment in that homologous series as calculated here is necessarily identical to that of the homologous methoxy ethers. As calculated from the methylene increment or from equation 16, the enthalpy of formation of 5-lithiopentyl methyl ether is ca —309 kJmol. ... 

Esters and acids from simple carbonylation reactions Alcohols, ethers and esters with higher homologous alkyl groups. Hydrocarbons from hydrogenolysis of the alcohol and its homologs. Ethers from dehydration of the substrate. Esters of the reagent alcohol. s)oiefins from dehydration of the alcohols. Isomeric alcohols. Isomer products (linear/branched 50/50 - 60/40). Only 2-methyl butanol Dimers and trimers of i-butene. 

The interest attached to this alkaloid lies in the fact that its ethyl ether, the so-called optochin, is a remarkable and specific bactericide for die pneumococcus, while its homologous ethers are highly bactericidal for other micro-organisms18... 

Since the ethylene glycol ethers contain an ether as well as an alcohol group, they are veiy good solvents for cellulose esters. The ethylene glycol methyl ether is an excellent solvent for both nitro- and acetylcellulose, whereas the ethyl and the higher homologous ethers dissolve only the nitrocellulose. 

Fig. X-9. Zisman plots of the contact angles of various homologous series on Teflon O, RX , alkylbenzenes (f), n-alkanes , dialkyl ethers , siloxanes A, miscellaneous polar liquids. (Data from Ref. 78.)...

Homologous mono-alkyl ethers of ethylene glycol, such as monoethyl glycol (or 2-ethoxyethanol), HOC2H4OC2H5, form excellent solvents as they combine to a large extent the solvent properties of alcohols and ethers. The monoethyl and the monomethyl members have the technical names of ethyl cellosolve and methyl cellosolve respectively. Dioxan... 

The lower members of other homologous series of oxygen compounds— the acids, aldehydes, ketones, anhydrides, ethers and esters—have approximately the same limits of solubility as the alcohols and substitution and branching of the carbon chain has a similar influence. For the amines (primary, secondary and tertiary), the limit of solubility is about C whilst for the amides and nitriles it is about C4. 

Group I. This includes the lower members of the various homologous series (4-5 atoms in a normal chain) that contain oxygen and/or nitrogen in their structures they are soluble iu water because of their low carbon content. If the compound is soluble in both water and ether, it would also be soluble in other solvents so that further solubility tests are generally unnecessary the test with sodium bicarbonate solution should, however, be performed (see Section XI,6). 

Anionic surfactants are the most commonly used class of surfactant. Anionic surfactants include sulfates such as sodium alkylsulfate and the homologous ethoxylated versions and sulfonates, eg, sodium alkylglycerol ether sulfonate and sodium cocoyl isethionate. Nonionic surfactants are commonly used at low levels ( 1 2%) to reduce soap scum formation of the product, especially in hard water. These nonionic surfactants are usually ethoxylated fatty materials, such as H0CH2CH20(CH2CH20) R. These are commonly based on triglycerides or fatty alcohols. Amphoteric surfactants, such as cocamidopropyl betaine and cocoamphoacetate, are more recent surfactants in the bar soap area and are typically used at low levels (<2%) as secondary surfactants. These materials can have a dramatic impact on both the lathering and mildness of products (26). 

Hoffmaim-La Roche has produced -carotene since the 1950s and has rehed on core knowledge of vitamin A chemistry for the synthesis of this target. In this approach, a five-carbon homologation of vitamin A aldehyde (19) is accompHshed by successive acetalizations and enol ether condensations to prepare the aldehyde (46). Metal acetyUde coupling with two molecules of aldehyde (46) completes constmction of the C q carbon framework. Selective reduction of the internal triple bond of (47) is followed by dehydration and thermal isomerization to yield -carotene (21) (Fig. 10). 

The method should not be used for the first member of a homologous series or for temperatures much above the normal boiling point (T 0.75). Errors for both hydrocarbons and nonhydrocarbons average 15 percent for a wide variety of compounds. Higher errors are noted for amines, diols, ethers, and fluorides. Table 2-398 gives AN and AB contributions for most common groups. Space prohibits examples for... 

Nelson and Scliut investigated the reaction of 5a-cholestanone (lb) with diazomethane in a search for a direct, one-step preparation of A-homo ketones. Using a large excess of diazomethane generated in situ from A-methyl-nitrosourea with potassium hydroxide in ether-methanol at 0°, 5a-cholestanone (lb) is converted into the 7-membered ring homolog (3b) as the predominant product. Both theoretically possible A-homo ketones can be expected with an unsymmetrically-substituted cyclohexanone such as 5a-cholestanone (lb). 

For the preparation of 19-nor-B-homosteroids Tadanier s acetolysis procedure appears to be the method of choice. The mild reaction conditions employed with each of these procedures allows the maintainance of a variety of functional groups, e.g., double bonds, ethers, hydroxyls and the like during the homologation process. 

The homolog of epinephrine in this series is a potent vasoconstrictor. Reaction of 3,4-dimethoxypropiophenone with butyl nitrite leads to nitrosation at the a position (36). Stepwise reduction of the nitrosoketone leads to the amino alcohol (37). Removal of the methyl ether affords racemic 38. Resolution of this last followed by separation of the (-) isomer gives levonor-defrine (38). ... 

Reaction of estrone methyl ether with methyl Grignard reagent followed by Birch reduction and hydrolysis of the intermediate enol ether affords the prototype orally active androgen in the 19-nor series, normethandrolone (69). ° (Note that here again the addition of the methyl group proceeded stereoselectively by approach from the least hindered side.) The preparation of the ethyl homolog starts by catalytic reduction of mestranol treatment of the intermediate, 70, under the conditions of the Birch reduction and subsequent hydrolysis of the intermediate enol ether yields norethandrolone (71). ... 

Asymmetnc tandem cycloaddicion of a chiral carbohydrate tutroalkene with ethyl vmyl ether in the ptesence of electron-withdrawmgalkenes produces a facile assembly of bicychc systems, which can further be seletnvely cleaved to give homologated carbohydrates fEq 8 110 ... 

The homology between 22 and 21 is obviously very close. After lithium aluminum hydride reduction of the ethoxycarbonyl function in 22, oxidation of the resultant primary alcohol with PCC furnishes aldehyde 34. Subjection of 34 to sequential carbonyl addition, oxidation, and deprotection reactions then provides ketone 21 (31% overall yield from (—)-33). By virtue of its symmetry, the dextrorotatory monobenzyl ether, (/ )-(+)-33, can also be converted to compound 21, with the same absolute configuration as that derived from (S)-(-)-33, by using a synthetic route that differs only slightly from the one already described. 

The enol ether double bond contained within the ds-fused dioxa-bicyclo[3.2.0]heptene photoadducts can also be oxidized, in a completely diastereoselective fashion, with mCPBA. Treatment of intermediate XXII, derived in one step from a Patemo-Buchi reaction between 3,4-dimethylfuran and benzaldehyde, with mCPBA results in the formation of intermediate XXIII. Once again, consecutive photocycloaddition and oxidation reactions furnish a highly oxygenated system that possesses five contiguous stereocenters, one of which is quaternary. Intermediate XXIII is particularly interesting because its constitution and its relative stereochemical relationships bear close homology to a portion of a natural product known as asteltoxin. 

Note There appear to be no recent examples of this reaction with simple alkoxy substrates (perhaps because normal aliphatic ethers need quite vigorous treatment, such as boiling hydriodic acid), but so-called isopropylidenedioxy derivatives (that undergo facile hydrolysis) have been used in this way. l-[2,3-(Isopropylidenedioxy)propyl]-3-methyl-2(17/)-quinoxalinone (165) gave l-(2,3-dihydroxypropyl)-3-methyl-2(l//)-quinoxahnone (70% AcOH, reflux, 2 h 35% homologs likewise). ... 

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