Guanidination with alkyl

Although there are many claims in patents to the preparation of alkylguanidines by reaction of guanidine with alkyl halides, this method, which was first studied by Schenck [ 16 5 ], has only rarely been found satisfactory. Primary and secondary alcohols in 80-85 per cent sulphuric acid react with guanidines to give the mono-and di-alkyl derivatives [166]. A process for direct alkylation of guanidine by an alkyl tosylate has been developed [95, 138, 167]. 

Some substituted guanidines have been obtained [457] by reaction of amines with the disulphide H2N(HN )C S S C( NH)NH2. Papers on the structure and p/fa s [458], and the synthesis [458, 459] of acylguanidines have been published. Reaction of guanidine with alkyl-, alkenyl-, and benzyl-halides, followed by distillation under basic conditions, is reported to give useful yields of amines [460]. A novel electrophilic substitution of benzene to give A -methyl-A -phenyl-guanidine amongst other products has been published [461 ]. 

Preparation.—Alkylation of guanidine with alkyl halides followed by basic hydrolysis affords a new method for the preparation of pure primary amines primary alkyl halides give the most satisfactory results. ... 

An important development of the synthesis described above is derived from the observations of Scott, O Donovan and Reilly [159], which were taken up by others [109]. l-Guanyl-3,5-dimethylpyrazole nitrate reacts with alkyl- and aryl-amines in hot water, ethanol, or without solvent to give good yields of guanidines. Use of this pyrazole nitrate or other salt for obtaining guanidines now competes with older methods if yield and ease of isolation of the product are the main considerations [95, 138, 140, 143, 160-164]. 

Reaction of carboxamides with isatoic anhydrides 7 in place of anthranilic acid as a source of the anthraniloyl group is an attractive extension of the Niementowski synthesis (cf. p 30). The reaction of isatoic anhydrides 7 with formamide or 2-hydroxybenzamides at elevated temperatures in a melt or in tbe presence of suitable solvents gives high yields of tbe respective quinazolin-4(3//)-oncs 8/ whereas with alkyl-, aralkyl-, or arylcarboxamides the yields of the corresponding 2-substituted quinazolin-4(3//)-oncs arc low Guanidine and ami-... 

With /V-acylthioamides the reaction proceeds very slowly and the products are difficult to purify. Therefore, the Af-acylthioamides 32 are first converted into the S -alkyl derivatives 33 by the reaction with alkyl halides under strongly basic conditions. The resulting A -acylthioimi-dates 33 react with amidines and guanidines in alcoholic solution in the presence of sodium alkoxide to form 2,4,6-trisubstituted 1,3,5-triazines 34 in moderate to good yields.438,439 This procedure is an extension of the synthesis of trisubstituted 1,3,5-triazines from A -acylimidates 17 and amidines (vide supra).325... 

Although in the dry state carbon tetrachloride may be stored indefinitely in contact with some metal surfaces, its decomposition upon contact with water or on heating in air makes it desirable, if not always necessary, to add a smaH quantity of stabHizer to the commercial product. A number of compounds have been claimed to be effective stabHizers for carbon tetrachloride, eg, alkyl cyanamides such as diethyl cyanamide (39), 0.34—1% diphenylamine (40), ethyl acetate to protect copper (41), up to 1% ethyl cyanide (42), fatty acid derivatives to protect aluminum (43), hexamethylenetetramine (44), resins and amines (45), thiocarbamide (46), and a ureide, ie, guanidine (47). 

Amidines and related systems such as guanidines react with a-halogenoketones to form imidazoles. a-Hydroxyketones also take part in this reaction to form imidazoles, and a variety of substituents can be introduced into the imidazole nucleus by these procedures. Reaction of the a-halogenoketone (73) with an alkyl- or aryl-substituted carboxamidine (76) readily gave the imidazole (77) (01CB637, 48JCS1960). Variation of the reaction components that successfully take part in this reaction process is described in Chapter 4.08. 

The guanidine function, when attached to an appropriate lipophilic function, often yields compounds that exhibit antihypertensive activity by means of their peripheral sympathetic blocking effects. Attachment of an aromatic ring via a phenolic ether seems to fulfill these structural requirements. Alkylation of 2,6-dichlorophenol with bromochloroethane leads to the intermediate, 58. Alkylation of hydrazine with that halide gives 59. Reaction of the hydrazine with S-methylthiourea affords the guanidine, guanoclor (60). ... 

An early application of this reaction to the preparation of barbiturates starts by the condensation of the ketone, I21, with ethyl cyanoacetate by Knoevenagel condensation. Alkylation of the product (122) with ethyl bromide by means of sodium ethoxide affords 123. Condensation of this intermediate with guanidine in the presence of sodium ethoxide gives the diimino analog of a barbiturate (124). Hydrolysis affords vinbarbital (111). > ... 

In a somewhat similar vein, alkylation of the urea derivative 109 with methyl iodide affords the S-methyl ether 110. Condensation of that with taurine (111), leads to the guanidine 112, again by an addition elimination process. The product is the anthelmintic agent netobimin (112) [271. 

Rolgamidine (14) is a dihydropyrrole derivative which has antidiarrheal activity It can be synthesized by alkylation of trans 2,5-dimethyl-3 pyrroline (12) with methyl bromoacefate to give 13 An amide-ester exchange reaction with guanidine hydrochloride completes the synthesis of rolgamidine (14) [3]... 

When cyanogen bromide was used instead of CS2, the corresponding guanidines 169 were obtained under analogous conditions [108]. Moreover, differently substituted guanidines 171 could be obtained in very good yields when the isothiourea 168 was alkylated with Mel under microwave irradiation and the product treated with a primary amine. An intramolecular version of this reaction was also described for the preparation of structure 172 present in several important natural products (Scheme 61). 

An alternative to the Gabriel synthesis, in which alkyl halides can be converted to primary amines in good yields, involves treatment of the halide with the strong base guanidine followed by alkaline hydrolysis. There are several alternative... 

Diamines can also react with only one equivalent of isothiocyanate to form bi-functionnal amine-thiourea ligands 59-68% yields obtained for several alkyl isothiocyanates. However, reaction of phenyhsocyanate with 1,2-diamines could also lead to the formation of the guanidine derivative by cyclisation and elimination of H2S (Scheme 4) [42,43]. 

As yet, a number of experiments have failed to convert ureas 205 such as N-phenylurea or imidazolin-2-one by silylation amination with excess amines R3NHR4 such as benzylamine or morpholine and excess HMDS 2 as well as equivalent amounts of NH4X (for X=C1, I) via the silylated intermediates 206 and 207 in one reaction step at 110-150°C into their corresponding guanidines 208 with formation of NH3 and HMDSO 7 [35] (Scheme 4.13). This failure is possibly due to the steric repulsion of the two neighbouring bulky trimethylsilyl groups in the assumed activated intermediate 207, which prevents the formation of 207 in the equilibrium with 206. Thus the two step Rathke-method, which demands the prior S-alkylation of 2-thioureas followed by amination with liberation of alkyl-mercaptans, will remain one of the standard syntheses of guanidines [21, 35a,b,c]. 

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