Amines dehydration

Dihydropyrido[3,4-<7]pyrimidine-2,4(1 //,3//)-diones having a 1,3,6-trimethyluracil-5-yl group in the 6-position are obtained from the reaction of 1,3,6-trimethyl-2,4-dioxo-l,2,3,4-te-trahydropyrimidine-5-carbaldehyde and primary amines.480-482 The supposed mechanism includes the intermediate formation of a 5,6-dihydro-5,6-dimethylenepyrimidine-2,4(l//,3/7)-dione which gives a cycloaddition reaction with aldimines from the educt and the primary amines. Dehydration then completes the reaction. 

Hydroboration of (-f)-verbenone (202 X = 0) and treatment with hydroxyl-amine-O-sulphonic acid results in a 65% yield of (-l-)-cw-S-pinene (213) by elimination, with no resultant amine. Dehydrated neutral alumina may be used for the room-temperature concerted 1,2-elimination from 10-pinanyl tosylate to yield /3-pinene (70%) and some a-pinene (14%) with little rearrangement to camphene/ The addition of diethyl N,7V-dichlorophosphoroamidate to (-)-a-pinene yields (-t-)-(214) and the structure of the adduct (-)-(13) from MePCl2-AICI3 addition to (-)-a-pinene has been confirmed by X-ray analysis. The addition of HCNO to a- and / -pinene was reported earlier. 

Water-soluble calix[4]resorcinols with sulfur group substituents function as catalysts in the amination (dehydration) of alcohols in aqueous medium (Scheme 4.25) [91]. 

Amine dehydration. A steam or water leak into the system will dilute the amine. Weak, rich amine becomes acidic and corrosive. To increase amine concentration, reflux water can be diverted to a closed drain. This will require piping the reflux water to a place where H2S can be safely flashed off. Do not drain this water to an open sewer it is supersaturated with deadly HjS. This is one mistake nobody makes more than once. 

Acetic anhydride/sodium acetate dehydrating agent, 86, 87, 89 isomaleimide rearrangement catalyst, 89, 90 Acetic anhydride/tertiary amines, dehydrating agent, 86, 89... 

Scheme 37.8 Synthesis of trifluoromethyl-substituted 2-isoxazolines through a domino oxa-Michael-intramolecular hemi-aminalization-dehydration reaction.

Since heterocycles containing a trifluoromethyl group are representatives of a major structure type in agricultural and medicinal chemistry, Shibata et al. have developed a novel enantioselective synthesis of trifluoromethyl-substituted 2-isoxazoHnes 46 on the basis of a domino oxa-Michael—intramolecular hemi-aminalization-dehydration reaction of hydroxylamine with a range of (B)-trifluoromethylated enone derivatives 47 [81]. This process, which employed N-3,5-bis(trifluoromethyl)benzyl-quinidinium bromide 48 as a chiral phase-transfer catalyst combined with CsOH as a base provided a series of trifluoromethyl-substituted 2-isoxazolines 46 in high yields and enantioselectivities of up to 94% ee (Scheme 37.8). 

It is used as a catalyst in esterification, dehydration, polymerization and alkylation reactions. Converted by e.g., ihionyl chloride, to melhanesulphonyl chloride (mesyl chloride) which is useful for characterizing alcohols, amines, etc. as melhanesulphonyl (mesyl) derivatives. 

Metallic sodium. This metal is employed for the drying of ethers and of saturated and aromatic hydrocarbons. The bulk of the water should first be removed from the liquid or solution by a preliminary drying with anhydrous calcium chloride or magnesium sulphate. Sodium is most effective in the form of fine wire, which is forced directly into the liquid by means of a sodium press (see under Ether, Section II,47,i) a large surface is thus presented to the liquid. It cannot be used for any compound with which it reacts or which is affected by alkalis or is easily subject to reduction (due to the hydrogen evolved during the dehydration), viz., alcohols, acids, esters, organic halides, ketones, aldehydes, and some amines. 

Derivatives with 3-nitrophthalic anhydride. 3-Nitrophthalic anhydride reacts with primary and secondary amines to yield nitro-phthalamic acids it does not react with tertiary amines. The phthalamic acid derived from a primary amine undergoes dehydration when heated to 145° to give a neutral A -substituted 3-nitrophthalimide. The phthalamic acid from a secondary amine is stable to heat and is, of course, soluble in alkali. The reagent therefore provides a method for distinguishing and separating a mixture of primary and secondary amines. 

The cyclic carbonate of benzoin (4,5-diphenyl-l,3-dioxol-2-one, prepared from benzoin and phosgene) blocks both hydrogen atoms of primary amines after dehydration acid stable, easily crystallizable Sheehan oxazolinones are formed, which are also called Ox derivatives. The amine is quantitatively deblocked by catalytic hydrogenation in the presence of 1 equiv. of aqueous acid (J.C Sheehan, 1972, 1973 M.J. Miller, 1983). An intelligent application to syntheses of acid labile -lactams is given in the previous section (p. 161). 

Step in the dehydration phase is rate determining when the reaction is carried out in acid solution If the solution is too acidic however protonation of the amine blocks step 1 Therefore there is some optimum pH usually about 5 at which the reaction rate is a maximum Too basic a solution reduces the rate of step 4 too acidic a solution reduces the rate of step 1... 

The carbinolamine is formed by nucleophilic addition of the amine to the carbonyl group Its dehydration gives the imine product... 

Secondary amines are compounds of the type R2NH They add to aldehydes and ketones to form carbmolammes but their carbmolamme intermediates can dehydrate to a stable product only m the direction that leads to a carbon-carbon double bond... 

The product of this dehydration is an alkenyl substituted amine or enamine... 

Reaction with secondary amines (Sec tion 17 11) Isolated product IS an en amine Carbinolamine intermediate can not dehydrate to a stable imine... 

Primary amines undergo nucleo philic addition to the carbonyl group of aldehydes and ketones to form carbinol amines These carbinolamines dehydrate under the conditions of their formation to give N substituted imines Secondary amines yield enamines... 

At the other end of the reaction, deviations from idealized rate laws are attributed to secondary reactions such as degradations of acids, alcohols, and amines through decarboxylation, dehydration, and deamination, respectively. The step-growth polymers which have been most widely studied are simple... 

A method for making ben2onitri1e by dehydrogenation of the Diels-Alder adduct of butadiene and acrylonitrile also has been described (79). Ben2onitri1e also can be made on a small scale by the dehydration of ben2amide ia an iaert solvent with phosphoms oxychloride or ben2enesulfonyl chloride and an organic amine (80,81). 

Butyrolactone reacts rapidly and reversibly with ammonia or an amine forming 4-hydroxybutyramides (175), which dissociate to the starting materials when heated. At high temperatures and pressures the hydroxybutyramides slowly and irreversibly dehydrate to pyrroHdinones (176). A copper-exchanged Y-2eohte (177) or magnesium siUcate (178) is said to accelerate this dehydration. 

Stripping is accompHshed by dehydration using sulfuric acid (38), lithium chloride [7447-41-8] (39), and tertiary amines containing from 14—32 carbon atoms in an organic solvent immiscible with water followed by thermal treatment of the HCl—organic complex (40). 

A production plant for salt-free ethyleneimine synthesis by catalytic dehydration of monoethanol amine [141-45-5] in the gas phase has started operation at the Japanese company Nippon Shokubai (366). 

A simpler nonphosgene process for the manufacture of isocyanates consists of the reaction of amines with carbon dioxide in the presence of an aprotic organic solvent and a nitrogeneous base. The corresponding ammonium carbamate is treated with a dehydrating agent. This concept has been apphed to the synthesis of aromatic and aUphatic isocyanates. The process rehes on the facile formation of amine—carbon dioxide salts using acid haUdes such as phosphoryl chloride [10025-87-3] and thionyl chloride [7719-09-7] (30). 

Monsanto has disclosed the use of carbon dioxide—amine complexes which are dehydrated, at low temperatures, with phosphoryl chloride [10025-87-3] or thionyl chloride [7719-09-7] as a viable route to a variety of aUphatic isocyanates. The process rehes on the facile formation of the intermediate salt (30).REPLACEVariations of this process, in which phosgene is used as a dehydrating agent, have been reported earlier (84). Table 2 Hsts commercially available aUphatic isocyanates. 

The reactions of primary amines and maleic anhydride yield amic acids that can be dehydrated to imides, polyimides (qv), or isoimides depending on the reaction conditions (35—37). However, these products require multistep processes. Pathways with favorable economics are difficult to achieve. Amines and pyridines decompose maleic anhydride, often ia a violent reaction. Carbon dioxide [124-38-9] is a typical end product for this exothermic reaction (38). 

Nitio olefins can be made in some cases by dehydration of the aromatic nitrohydroxy derivatives. Subsequent reduction yields the aromatic amine. The following three-step reaction yielding 2-amino-l-phenylbutane illustrates the synthesis of this class of valuable pharmaceutical compounds. 

The zwitterion (6) can react with protic solvents to produce a variety of products. Reaction with water yields a transient hydroperoxy alcohol (10) that can dehydrate to a carboxyUc acid or spHt out H2O2 to form a carbonyl compound (aldehyde or ketone, R2CO). In alcohoHc media, the product is an isolable hydroperoxy ether (11) that can be hydrolyzed or reduced (with (CH O) or (CH2)2S) to a carbonyl compound. Reductive amination of (11) over Raney nickel produces amides and amines (64). Reaction of the zwitterion with a carboxyUc acid to form a hydroperoxy ester (12) is commercially important because it can be oxidized to other acids, RCOOH and R COOH. Reaction of zwitterion with HCN produces a-hydroxy nitriles that can be hydrolyzed to a-hydroxy carboxyUc acids. Carboxylates are obtained with H2O2/OH (65). The zwitterion can be reduced during the course of the reaction by tetracyanoethylene to produce its epoxide (66). 

Hydrolysis of primary amides cataly2ed by acids or bases is very slow. Even more difficult is the hydrolysis of substituted amides. The dehydration of amides which produces nitriles is of great commercial value (8). Amides can also be reduced to primary and secondary amines using copper chromite catalyst (9) or metallic hydrides (10). The generally unreactive nature of amides makes them attractive for many appHcations where harsh conditions exist, such as high temperature, pressure, and physical shear. 

Primary cycloaUphatic amines react with phosgene to form isocyanates. Reaction of isocyanates with primary and secondary amines forms ureas. Dehydration of ureas or dehydrosulfuri2ation of thioureas results in carhodiimides. The nucleophilicity that deterrnines rapid amine reactivity with acid chlorides and isocyanates also promotes epoxide ring opening to form hydroxyalkyl- and dihydroxyalkylaniines. Michael addition to acrylonitrile yields stable cyanoethylcycloalkylarnines. 

Reductive amination of cyclohexanone using primary and secondary aHphatic amines provides A/-alkylated cyclohexylamines. Dehydration to imine for the primary amines, to endocycHc enamine for the secondary amines is usually performed in situ prior to hydrogenation in batch processing. Alternatively, reduction of the /V-a1ky1ani1ines may be performed, as for /V,/V-dimethy1 cyclohexyl amine from /V, /V- di m e th y1 a n i1 i n e [121 -69-7] (12,13). One-step routes from phenol and the alkylamine (14) have also been practiced. 

Amin omethyl-3,5,5-trimethyl cyclohexyl amine (21), commonly called isophoronediamine (IPD) (51), is made by hydrocyanation of (17) (52), (53) followed by transformation of the ketone (19) to an imine (20) by dehydrative condensation of ammonia (54), then concomitant hydrogenation of the imine and nitrile functions at 15—16 MPa (- 2200 psi) system pressure and 120 °C using methanol diluent in addition to YL NH. Integrated imine formation and nitrile reduction by reductive amination of the ketone leads to alcohol by-product. There are two geometric isomers of IPD the major product is ds-(22) [71954-30-5] and the minor, tram-(25) [71954-29-5] (55). 

The 1,4-isomer has been similarly generated from terephthalonitdle [623-26-7] (56) using a mixed Pd/Ru catalyst and ammonia plus solvent at 125 °C and 10 MPa (100 atm). It is also potentially derived (57) from terephthaUc acid [100-21-0] by amination of 1,4-cyclohexanedimethanol (30) [105-08-8], Endocyclization, however, competes favorably and results in formation of the secondary amine (31) 3-a2abicyclo[3.2.2]nonane [283-24-9] upon diol reaction with ammonia over dehydration and dehydrogenation catalysts (58) ... 

Amination. Isopropyl alcohol can be aminated by either ammonolysis ia the presence of dehydration catalysts or reductive ammonolysis usiag hydrogeaatioa catalysts. Either method produces two amines isopropylamine [75-31-0] and diisopropylamine [108-18-9]. Virtually no trisubstituted amine, ie, triisopropyl amine [122-20-3], is produced. The ratio of mono- to diisopropylamine produced depends on the molar ratio of isopropyl alcohol and ammonia [7664-41-7] employed. Molar ratios of ammonia and hydrogen to alcohol range from 2 1—5 1 (35,36). 

Pyrrohdines also can be obtained by reaction of 1,4-dihydroxyaLkanes with amines in the presence of dehydrating agents at elevated temperatures or by reaction of primary amines with 1,4-dihaloaLkanes. The dry distillation of 1,4-butanediamine dihydrochloride also generates pyrrohdine. Pyrroles can also be catalyticahy hydrogenated to pyrrohdines. 

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