Aniline, alkylation hydrolysis

P-amino acid products. Treatment of oxazoline 53 with 7V-lithiopiperidine followed by alkylation with iodomethane affords aniline derivative 54 in 94% yield and 99% de. Hydrolysis of the oxazoline group provided amino acid 55 in 92% yield and >99% ee. 

The complexity of the metabolism of alachlor, acetochlor, butachlor, and propachlor has led to the development of degradation methods capable of hydrolyzing the crop and animal product residues to readily quantitated degradation products. Alachlor and acetochlor metabolites can be hydrolyzed to two major classes of hydrolysis products, one which contains aniline with unsubstituted alkyl groups at the 2- and 6-positions, and the other which contains aniline with hydroxylation in the ring-attached ethyl group. For alachlor and acetochlor, the nonhydroxylated metabolites are hydrolyzed in base to 2,6-diethylaniline (DBA) and 2-ethyl-6-methylaniline (EMA), respectively, and hy-droxylated metabolites are hydrolyzed in base to 2-ethyl-6-(l-hydroxyethyl)aniline (HEEA) and 2-(l-hydroxyethyl)-6-methylaniline (HEMA), respectively. Butachlor is metabolized primarily to nonhydroxylated metabolites, which are hydrolyzed to DEA. Propachlor metabolites are hydrolyzed mainly to A-isopropylaniline (NIPA). The base hydrolysis products for each parent herbicide are shown in Eigure 1. Limited interference studies have been conducted with other herbicides such as metolachlor to confirm that its residues are not hydrolyzed to the EMA under the conditions used to determine acetochlor residues. Nonhydroxylated metabolites of alachlor and butachlor are both hydrolyzed to the same aniline, DEA, but these herbicides are not used on the same crops. 

Although geneologically related to indoles, the dihydroindoles behave chemically rather like alkyl anilines. When diphenylamine reacts with chloro-propionyl chloride, amide 40 results this in turn readily cyclizes to oxindole 41. Sodium hydride followed by 2-chloroethyldimethylamine alkylates the 3-position (possibly through an intermediate aziridinium ion) partial demethylation is accomplished by refluxing with ethylchiorocarbonate, followed by hydrolysis of the intermediate carbamate to give indolinone 42, the antidepressant amedalin Repetition of this sequence on the chloropropyl homologue, followed by reduction of the appropriate indolinone produces dihydroindole 43, daledalin, which also has antidepressant activity. ... 

A general route to allylanilines, reported by Harmata and co-workers <95TL4769> could be of value in organic synthesis. Deprotonation of 2,1-benzothiazines 193 with n-BuLi followed by alkylation with iodomethyltrimethylsilane, and subsequent desilylation with fluoride followed by hydrolysis led to allyl aniline 194 in good yields (Scheme 54). 

Other electrophilic substitution reactions on aromatic and heteroaromatic systems are summarized in Scheme 6.143. Friedel-Crafts alkylation of N,N-dimethyl-aniline with squaric acid dichloride was accomplished by heating the two components in dichloromethane at 120 °C in the absence of a Lewis acid catalyst to provide a 23% yield of the 2-aryl-l-chlorocydobut-l-ene-3,4-dione product (Scheme 6.143 a) [281]. Hydrolysis of the monochloride provided a 2-aryl-l-hydroxycyclobut-l-ene-3,4-dione, an inhibitor of protein tyrosine phosphatases [281], Formylation of 4-chloro-3-nitrophenol with hexamethylenetetramine and trifluoroacetic acid (TFA) at 115 °C for 5 h furnished the corresponding benzaldehyde in 43% yield, which was further manipulated into a benzofuran derivative (Scheme 6.143b) [282]. 4-Chloro-5-bromo-pyrazolopyrimidine is an important intermediate in the synthesis of pyrazolopyrimi-dine derivatives showing activity against multiple kinase subfamilies (see also Scheme 6.20) and can be rapidly prepared from 4-chloropyrazolopyrimidine and N-bromosuccinimide (NBS) by microwave irradiation in acetonitrile (Scheme... 

Use of a large, lipophilic nitrogenous component results in a 1idocaine like, local anesthetic type cardiac anti-arrhythmic drug, lorcainide (20). Synthesis begins with the Schiff s base (1 ) derived by reaction of p-chloro-aniline and borohydride followed by acylation with phenyl acetyl chloride produces amide 1 . Selective hydrolysis with HBr followed by alkylation with isopropyl bromide completes the synthesis of lorcainide (20). ... 

It of interest to note that the isobutyl group may also be replaced by a heterocyclic ring. The route to this compound, pirprofen (51-6), starts with the direct methylation of unesterihed 4-nitrophenylacetic acid (51-1). The observed selectivity for monoalkylation in this case may reside in the structure of the dianion, whose most stable form is presumably that depicted in (51-2). Catalytic reduction of the product (51-3) gives the corresponding aniline this is then converted to its acetanilide (51-4) with acetic anhydride. Treatment with chlorine followed by hydrolysis gives the chloroaniline (51-5). Double alkylation of this last intermediate with 1,4-dichloro-but-2-ene (depicted as the cis isomer for aesthetic reasons) forms the dihydropyrrole ring. There is thus obtained the NSAID pirprofen (51-6) [52]. 

In a closely related example, a Mannich reaction of the somewhat more complex phenol (20-1) with formaldehyde and fert-butylamine gives the aminomethylated product (20-2). Hydrolysis of the acetamide protecting group then affords the corresponding aniline (20-3). Alkylation with the quinoline (17-6) in this case also proceeds on aniline nitrogen. The selectivity over the more basic secondary side nitrogen can probably be ascribed to steric hindrance about the latter. There is thus obtained tebuquine (20-4) [22]. 

The Leuckart Thiophenol Reaction allows the preparation of thiophenols and corresponding thioethers from anilines or their corresponding diazonium salts. The first step is the reaction of an aryl diazonium salt with a potassium alkyl xanthate to give an aryl xanthate, which affords an aryl mercaptan upon basic hydrolysis or an aryl thioether upon warming. 

A series of pyrrolidines was conveniently prepared in a microwave-assisted double alkylation of aniline derivatives with alkyl dihalides in water in the presence of K2CO3 as a base (Scheme 1) [12,13]. Although the reaction mixture could be regarded as a multi-phase system, as neither reactant was soluble in the mildly basic aqueous medium, the microwave-assisted reaction proceeded readily without the use of phase-transfer reagents. The amount of side-reactions such as hydrolysis of bromides to alcohols in an alkaline reaction medium was substantially suppressed compared to the conventional thermal conditions. The reaction conditions were sufficiently mild to tolerate a variety of functional groups in anilines such as hydroxyls, ketones and esters. Alkyl bromides and tosylates were equally efficient as alkylating agents. Notably, isolation and purification comprised simply of phase separations (filtration or decantation) of the desired product from the aqueous media. 

With anilines and AT-alkylanilines the way of dimerization is influenced by the reaction conditions and the substitution of the aryl ring [70]. The benzidines predominate in strongly acidic aqueous media. The formation of benzidine is further favored by a low substrate concentration and a high current density. The benzidine derivatives may be reversibly oxidized to their dications. Diphenylamines are the major products under neutral conditions and higher pH values, a low current density, a high substrate concentration, a small alkyl group in monoalkylanilines, and a non-aqueous solvent [Eq. (7)]. Under weakly acidic conditions in aqueous medium, an additional electron discharge followed by hydrolysis produces benzoquinones in almost quantitative yield. 

In the presence of external protic acid, A-alkyl-iV-(4-methoxyphenyl)anilines (54a-59a) are converted to A-alkyl-l,2,4,9-tetrahydrocarbazol-3-ones (54b-59b) (equations 14—16)162. A conceivable mechanism is demonstrated for 54a in Scheme 8, where the dihydrocarbazole intermediate undergoes a successive formal [1,5] and [1,3] hydrogen shift and then acid assisted hydrolysis before the formation of final products. 

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