Acid chloride reaction with LiAlH

Primary and secondary amines also react with epoxides (or in situ produced episulfides )r aziridines)to /J-hydroxyamines (or /J-mercaptoamines or 1,2-diamines). The Michael type iddition of amines to activated C—C double bonds is also a useful synthetic reaction. Rnally unines react readily with. carbonyl compounds to form imines and enamines and with carbo-tylic acid chlorides or esters to give amides which can be reduced to amines with LiAlH (p. Ilf.). All these reactions are often applied in synthesis to produce polycyclic alkaloids with itrogen bridgeheads (J.W. Huffman, 1967) G. Stork, 1963 S.S. Klioze, 1975). 

Acid chlorides, R(Ar)COCl, are reduced to R(Ar)CHO by Hj/Pd(S), a moderate catalyst that does not reduce RCHO to RCHjOH (Rosenmund reduction). Acid chlorides, esters (R(Ar)COOR), and nitriles (RC N) are reduced with lithium tri-t-butoxyaluminum hydride, LiAlH[OC(CH3)3]j, at very low temperatures, followed by HjO. The net reaction is a displacement of X by H",... 

Carboxylic acids, acid chlorides, acid anhydrides and esters get reduced to primary alcohols when treated with lithium aluminium hydride (LiAlH) (Fig.M). The reaction involves nucleophilic substitution by a hydride ion to give an intermediate aldehyde. This cannot be isolated since the aldehyde immediately undergoes a nucleophilic addition reaction with another hydride ion (Fig.N). The detailed mechanism is as shown in fig.O. 

So far, we have considered protocols that result in chiral centres in the C and position (actnally always with the same substiment). Let us now turn to satnrated carbenes that have only one chiral centre in the backbone. Figure 5.15 shows a procedure that utilises a chiral diamine derived from proline, a naturally occurring a-amino acid. Reaction with aniline to the corresponding amide and reduction with LiAlH yields the diamine used [60]. The actual synthesis of the chiral carbene then calls for reaction of the proUne derived diamine with thiophosgene and subsequent S/Cl exchange with oxalyl chloride [50]. The... 

Steric protection can be provided by adamantyl wingtip groups that are introduced by the reaction of the l,r-diaminobiphenyl to the Schiff base (with 2-adamantone) followed by reduction with LiAlH [79,80] (see Figure 5.24). Ring closure with triethyl orthoformate to the corresponding azolium salt proceeds as usual and subsequent reaction with [Pd(allyl)Cl]j in the presence of a suitable auxiliary base (potassium tcrt-butylate) yields the respective palladium allyl complex. The paUadium(II) allyl complex can then be reacted with hydrochloric acid to form the [Pd(NHC)Cy dimer. Subsequent reaction with a silver(I) salt predictably breaks up the dimer under chloride abstraction and anion transfer from silver to palladium. 

The aldehyde intermediate can be isolated if a leas puwerfu] reducintt agent such as lithiu.ni trt>lerl but0xyalurniiiii3n hydride is ii. ed in place of LiAlH. This reagent, which is obtained by reaction of LiAlK with 3 cciuiv-alente of lerl-butyl alcohol, is particularly effective far carrying out the partial reduction of acid chlorides to aldehyde (Section 19.2>. 

The chemistry of acid anhydrides is similar to that of acid chlorides. Although anhydrides react more slowly than acid chlorides, the kinds of reactions the two groups undergo are the same. Thus, acid anhydrides react with water to form acids, with alcohols to form esters, with amines to form amides, and with LiAlH.i to form primary alcohols (Figure 21.7, p. 864). 

For example, reduction of acid chlorides (RCOCl), prepared from carboxylic acids by reaction between the acid and, for example, thionyl chloride (vide infra), with hydrogen over a barium sulfate (BaS04) poisoned palladium (Pd) catalyst (the Rosenmund reduction), can often be used to produce the corresponding aldehyde (RCHO). The same product can more easily be obtained from the same starting material by using commercially available lithium aluminum tri-r-butoxy hydride (LiAlH[OC(CH3)3]3) in an ether solvent,such as bis(2-methoxyethyl)ether [diglyme, (CH30CH2CH2)20], at -78°C (Scheme 9.106). 

These chiral alkylboronic esters are exceptionally promising intermediates for C-C bond formation reaction in the synthesis [8, 9] of a-chiral aldehydes, P Chiral alcohols, a-chiral acids, and a-chiral amines. Brown et al [10], in a real breakthrough, discovered that LiAlH readily converts these relatively inert boronic esters to a very high reactive lithium monoalkylborohydrides R BHjLi (5) of very high optical purity. The optically active monoalkylborane (R BH2) is generated, when required, by a convenient reaction with trimethylsilyl chloride [6]. Consequently, the desired B-R -9-BBN is prepared conveniently by hydroboration of 1,5-cyclooctadiene with RBHj (prepared in situ), and the desired stable 1,5-isomer is obtained by thermal isomerization. The whole sequence is illustrated in Scheme 9.1. 

The benzyl group has been widely used for the protection of hydroxyl functions in carbohydrate and nucleotide chemistry (C.M. McCloskey, 1957 C.B. Reese, 1965 B.E. Griffin, 1966). A common benzylation procedure involves heating with neat benzyl chloride and strong bases. A milder procedure is the reaction in DMF solution at room temperature with the aid of silver oxide (E. Reinefeld, 1971). Benzyl ethers are not affected by hydroxides and are stable towards oxidants (e.g. periodate, lead tetraacetate), LiAlH, and weak acids. They are, however, readily cleaved in neutral solution at room temperature by palladium-catalyzed hydrogenolysis (S. Tejima, 1963) or by sodium in liquid ammonia or alcohols (E.J. Reist, 1964). 

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