Primary, from aldehydes

Because the olefin geometry in compound 9 will most certainly have a bearing on the stereochemical outcome of the hydroboration step, a reliable process for the construction of the trans trisubsti-tuted olefin in 9 must be identified. A priori, the powerful and predictable Wittig reaction28 could be used to construct E u, [3-unsaturated ester 10 from aldehyde 11. Reduction of the ethoxycarbonyl grouping in 10, followed by benzylation of the resulting primary alcohol, would then complete the synthesis of 9. Aldehyde 11 is a known substance that can be prepared from 2-furylacetonitrile (12). 

The strategy for the construction of 13 from aldehyde 16 with two units of phosphonate 15 is summarized in Scheme 12. As expected, aldehyde 16 condenses smoothly with the anion derived from 15 to give, as the major product, the corresponding E,E,E-tri-ene ester. Reduction of the latter substance to the corresponding primary alcohol with Dibal-H, followed by oxidation with MnC>2, then furnishes aldehyde 60 in 86 % overall yield. Reiteration of this tactic and a simple deprotection step completes the synthesis of the desired intermediate 13 in good overall yield and with excellent stereoselectivity. 

Primary and secondary halides do not perform well, mostly because N-alkylation becomes important, particularly with enamines derived from aldehydes. An alternative method, which gives good yields of alkylation with primary and secondary halides, is alkylation of enamine salts, which are prepared by treating an imine with ethylmagnesium bromide in THF ... 

The imines are prepared by 16-12. The enamine salt method has also been used to give good yields of mono a alkylation of a,P-unsaturated ketones. Enamines prepared from aldehydes and butylisobutylamine can be alkylated by simple primary alkyl halides in good yields. N-alkylation in this case is presumably prevented by steric hindrance. 

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). 

As alkylaromatic hydrocarbon (toluene, p-xylene, etc.) is oxidized, aldehydes appear radicals and peracids formed from them play an important role. First, aldehydes react rapidly with the Co3+ and Mn3+ ions, which intensifies oxidation. Second, acylperoxyl radicals formed from aldehydes are very reactive and rapidly react with the initial hydrocarbon. Third, aldehydes form an adduct with primary hydroperoxide, which decomposes to form aldehyde and acid. 

Furan is a colorless liquid, boiling point 32°C. insoluble in water, soluble in alcohol or ether. Furan vapor produces a green coloration on pine wood moistened with hydrochloric acid. Furan may he made from mucic acid. COOHtCHOHLCOOH. by dry distillation into pyromneie acid, C4H1O - COOH. and then heating the latter under pressure at 270 C. Furan derivatives arc known, namely, methyl, primary alcohol, aldehyde, carboxylic acid, in which the group attachment is at carbon number 2 ... 

Dialkyl peroxides and hydroperoxides which have either a hydroxy, hydroperoxy, alkoxy, or alkylpcroxy group on the carbon adjacent to the parent peroxide group arc considered separately from the parent compounds due to their unique reactions and properties, hut mainly because of their unique syntheses. Their primary preparation from aldehydes and ketones via reaction with hydrogen peroxide, alkyl hydroperoxides and pcroxyacids is unique and makes it almost impossible to discuss diem without referring to the parent carbonyl compound(s). 

Reduction of carbonyl compounds with metal hydrides or boranes a. primary alcohols from aldehydes, acids, acid halides, and esters... 

The reaction of aldehydes and ketones with Grignard reagents is a useful method of synthesising primary, secondary, and tertiary alcohols (Following fig.). Primary alcohols can be obtained from formaldehydes, secondary alcohols can be obtained from aldehydes, and tertiary alcohols can be obtained from ketones. The reaction involves the formation of a carbon-carbon bond and so this is an important way of building up complex organic structures from simple starting materials. 

Aldehydes and ketones when reduced yield alcohols with a hydride ion that is provided by reducing reagents like sodium borohydride or lithiumborohydride. Primary alcohols are obtained from aldehydes and secondary alcohols from ketones. 

Imines are formed from aldehydes or ketones with primary amines... 

Note. Aza-enolates are formed from imines, which can be made only from primary am ines. Enamines are made from aldehydes or ketones with secondary am ines. 

Besides the initiation with the vinyl ether adducts, trimethylsilyl halides in conjunction with oxolane [135] or a carbonyl compound [136-141] also provide an interesting method of end-functionalization. As discussed in Chapter 4, Section V.E.2 (also Figure 9 therein), the a-end group is (CH3)3SiO—, derived from the silyl compound, to be converted into the hydroxyl group [140,141], Depending on the structure of the carbonyl compounds, it is either secondary (from aldehyde) [136-139] or tertiary (from ketone) [137,138,140,141], both of which are difficult to obtain from the vinyl ether adducts (note that the adduct of AcOVE leads to a primary alcohol [30,31]). 

Another route to carboxylic acids from aldehyde products (once again, generally produced via hydroformylation catalysis) was discovered by Wakamatsu and coworkers. They reported the carbonylation of aldehydes and primary organic amides to produce A-acylamino acids (equation 16). The reaction is efficiently catalyzed by HCo(CO)4 at 100 °C and 140 bar of 3 2 H2/CO (hydrogen is needed to help stabilize HCo(CO)4). Yields of over 90% of the appropriate... 

The preparations of hydroxypyrazines by primary syntheses have been described in Chapter II, and are summarized briefly, together with further data, as follows Section II.IG, from the reaction of a, 3-dicarbonyl compounds with ammonia [282 (cf. 281, 280), 283, 285] with additional information (1042, 1043) Section II.IM, from 1,2-dicarbonyl compounds with a-amino acids (311) Section II.IN, from a-amino acids through piperazine-2,5-diones (93,95,101,282,312,313)with additional data (843) Section 11.10, from aldehyde cyanohydrins ( ) [317-319 (cf. 282)1 and Section II.IP, from o-nitromandelonitrile and ethereal hydrogen cyanide (325). The preparations from a,iJ-dicarbonyl compounds with a,/ -diamino compounds are described in Section 11.2 (60, 80, 358, 359, 361-365b, 365d, 366-375) additional data have also been reported (824, 825, 827,845,846,971, 1044, 1045) and some reaction products have been isolated as the dihydro-pyrazines (340,341,357). 

Oxidation Products of Ethane —Oxalic acid is thus the simplest di-carboxy acid possible. It may be considered as derived from ethane by the oxidation of both methyl groups to primary alcohol, aldehyde, and carboxyl groups successively. The entire series of oxidation relationships, including all of the intermediate compounds which we have already discussed, may be represented as follows ... 

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