Thionyl chloride reaction with amides

Now let s draw the forward scheme. Acid catalyzed hydrolysis of the amide gives a carboxylic acid which is then converted to the acid chloride upon treatment with thionyl chloride. Reaction with a hthium friatkoxyaluminum hydride, followed by water, produces the aldehyde. Subsequent treatment of the aldehyde with methylamine under acid-catalyzed conditions (with removal of water) gives the desired imine. 

In one synthesis of this drug, L-proline (11-2) is acylated with the acid chloride (11-1) obtained from the addition of hydrogen chloride to the double bond in methacrylic acid followed by reaction with thionyl chloride to give amide (11-3) as a mixture of diastereomers. The pure 2S isomer is then isolated from the mixture by fractionation as the dicyclohexylamine salt. Treatment of that compound with ammonium hydrosulfide leads to the displacement of chlorine by a thiol group and the formation of captopril (11-4) [13]. 

Carboxylic acids react with thionyl chloride to form acid chlorides. Reaction with alcohols gives esters, and with amines, amides are formed. 

Nitriles and Isocyanides via Amide Dehydration. Thionyl chloride dehydrates primary amides to form nitriles (eq 8) for example, 2-ethylhexanonitrile is produced in about 90% yield by heating with SOCI2 in benzene. Substituted benzonitriles are readily produced from benzamides. These reactions may also be catalyzed by DMF. A -Alkylformamides may be dehydrated to isocyanides. ... 

Benzisothiazoles are best prepared by oxidative cyclization of o-aminothiobenz-amides (see Section 4.17.9.1.1), reaction of o-toluidines with thionyl chloride (see Section 4.17.9.2.1) or by sulfuration of 2,1-benzisoxazoles (see Section 4.17.10.2). 1,2-Benzisothiazoles can also be prepared from o-disubstituted benzene compounds, cyclodehydration of o-mercaptobenzaldoximes or oxidative cyclization of p-mercaptobenzylamines (see Section 4.17.9.1.1) being the most convenient. Both series of benzo compounds are readily substituted at the 5- and 7-positions by electrophilic reagents. 

The simplest method of nitrile preparation is the Sj 2 reaction of CN with a primary or secondary alkyl halide, as discussed in Section 20.5. Another method for preparing nitriles is by dehydration of a primary amide, RCONH2. Thionyl chloride is often used for the reaction, although other dehydrating agents such as POCI3 also work. 

Many procedures for the formation of carboxylic acid amides are known in the literature. The most widely practiced method employs carboxylic acid chlorides as the electrophiles which react with the amine in the presence of an acid scavenger. Despite its wide scope, this protocol suffers from several drawbacks. Most notable are the limited stability of many acid chlorides and the need for hazardous reagents for their preparation (thionyl chloride, oxalyl chloride, phosgene etc.) which release corrosive and volatile by-products. Moreover, almost any other functional group in either reaction partner needs to be protected to ensure chemoselective amide formation.2 The procedure outlined above presents a convenient and catalytic alternative to this standard protocol. 

The traditional method for transforming carboxylic acids into reactive acylating agents capable of converting alcohols to esters or amines to amides is by formation of the acyl chloride. Molecules devoid of acid-sensitive functional groups can be converted to acyl chlorides with thionyl chloride or phosphorus pentachloride. When milder conditions are necessary, the reaction of the acid or its sodium salt with oxalyl chloride provides the acyl chloride. When a salt is used, the reaction solution remains essentially neutral. 

Ester 324 is hydrolyzed to acid 325 by refluxing in 10% NaOH. In a reaction with thionyl chloride, acid 325 is converted to acid chloride 326, which is isolated as a solid in 96% yield and consecutively converted into amide 327 in 85% yield. Treatment of amide 327 with LDA extracts a proton from the methyl group. The generated anion is trapped by added benzonitrile. Subsequent cyclocondensation of the obtained imine anion with the amide group provides derivative 328 in 62% isolated yield (Scheme 50) <2003EJM983>. 

In contrast to uridine,389 cytidine does not yield a 5 -chloro-5 -deoxy derivative on reaction with N,N-dimethyl(chlorometh-animinium) chloride instead 2,2 -anhydrocytidine is formed.395 However, thionyl chloride or bromide in hexamethylphosphor-amide at room temperature achieves this selective replacement of the primary hydroxyl group of halogen in cytidine, and also in adenosine, in respective yields of 80 and 75% for the chloro compounds, and 55 and 30% for the bromo analogs.396... 

The carboxylic functionalities inserted onto the tubes can be used as platforms to obtain further transformations (Fig. 3.5). A commonly utilized route is the reaction of carboxylic groups with thionyl chloride or oxalyl chloride to prepare the corresponding acyl chlorides, which are useful intermediates for amidation or esterification reactions. Amides can also be prepared directly from the acids by means of standard solution chemistry conditions, using carbodiimide derivatives in the presence of the selected amine. 

There are several chemical reactions that can be used as an alternative to achieve covalent functionalization of CNTs. Two of them are amidation and/or esterification reactions. Both reactions take advantage of the carboxylic groups sitting on the side-walls and tips of CNTs. In particular, they are converted to acyl chloride groups (-C0-C1) via a reaction with thionyl (SO) or oxalyl chloride before adding an alcohol or an amine. This procedure is very versatile and allows the functionalization of CNTs with different entities such as biomolecules [154-156], polymers [157], and organic compounds [158,159] among others. 

This method has been used extensively for the generation of diene- and triene-conjugated nitrile ylides (see Section 7.4.1.2) using strong bases. Potasium tert-butoxide (58) was used for the most part but in recent work (59,60) it was reported that lithium bisftrimethylsilyl)amide is both more effective and more convenient. It has also been shown that thermally unstable imidoyl chlorides for use in these reactions can be prepared by reaction of the corresponding amides with chlorodi-methylformiminium chloride at 0 °C, a reaction that is more effective than using either thionyl chloride or phosphoms pentachloride at higher temperatures (61). 

Wuts and co-workers recently reported that the Vilsmeier reagent is superior to thionyl chloride for the cyclodehydration of primary and secondary p-hydroxy amides to prepare oxazolines, in particular, for oxazoline 18b, which is used in Taxol synthesis (Scheme 8.10). Some other examples are shown in Table 8.5 (Fig. 8.3). As expected, inversion of configuration at the alcohol bearing carbon atom is observed. Of the examples examined, serine afforded low yields due to the formation of dehydroalanine. The reaction is conveniently carried out in pyridine at room temperature. p-Chloro amides are also formed, which can be converted to the oxazoline with DBU, generally using the same mixture without isolation. The... 

Electrophilic additions to 7t-deficient heterocycles are less common than those to 7t-excessive heterocycles. However, intramolecular electrophilic cyclizations have been used to access the heterocycles of interest in this chapter <1996CHEC-II(7)49>. Recent examples include the preparation of a pyrrolo[2,3-f]pyrazole 165 by acid-catalyzed condensation of 163 and 164 (Equation 37) <1999SC311> and the reaction of 3-(4-pyrazolyl)acrylic acids 166 with excess thionyl chloride in the presence of benzyltriethylammonium chloride (BTEAC) to afford 4-chlorothieno[2,3-f]pyrazole-5-carbonyl chlorides 167 (Equation 38) <2003RJ0893, 2003ZOK942>. In the latter case, the reaction products were readily manipulated to prepare corresponding carboxylic acids, esters, and amides using standard procedures. 

Inhibitors of the blood clotting factor thrombin would in principle prove useful in preventing inappropriate clot formation that potentially leads to stroke and heart attack. Reaction of the carboxylic acid (56-2) with thionyl chloride leads to the corresponding acid chloride (56-3). Treatment of that intermediate with the substituted pyridyl amine (56-1) leads to the amide (56-4). Catalytic hydrogenation of (56-4) reduces the nitro group to the primary amine (56-5). Condensation of that ortho-diamine with the carboxyhc acid (56-6) in the presence of carbonyl diimidazole... 

---