Allylamines, synthetic

Synthetic Polymers. Examples of polymers in this class include acrylamide—acryHc polymers and their derivatives, polyamines and their derivatives, poly-(ethylene oxide), and allylamine polymers. 

Pyrrohdinone (2-pyrrohdone, butyrolactam or 2-Pyrol) (27) was first reported in 1889 as a product of the dehydration of 4-aminobutanoic acid (49). The synthesis used for commercial manufacture, ie, condensation of butyrolactone with ammonia at high temperatures, was first described in 1936 (50). Other synthetic routes include carbon monoxide insertion into allylamine (51,52), hydrolytic hydrogenation of succinonitnle (53,54), and hydrogenation of ammoniacal solutions of maleic or succinic acids (55—57). Properties of 2-pyrrohdinone are Hsted in Table 2. 2-Pyrrohdinone is completely miscible with water, lower alcohols, lower ketones, ether, ethyl acetate, chloroform, and benzene. It is soluble to ca 1 wt % in aUphatic hydrocarbons. 

This synthetic allylamine derivative inhibits the enzyme squalene epoxidase at an early stage in fungal sterol biosynthesis. Acting as a structural analogue of squalene, naffidine causes the accumulation of this unsaturated hydrocarbon, and a decrease in ergosterol in the fungal cell membrane. 

Metal-catalyzed C-H bond formation through isomerization, especially asymmetric variant of that, is highly useful in organic synthesis. The most successful example is no doubt the enantioselective isomerization of allylamines catalyzed by Rh(i)/TolBINAP complex, which was applied to the industrial synthesis of (—)-menthol. A highly enantioselective isomerization of allylic alcohols was also developed using Rh(l)/phosphaferrocene complex. Despite these successful examples, an enantioselective isomerization of unfunctionalized alkenes and metal-catalyzed isomerization of acetylenic triple bonds has not been extensively studied. Future developments of new catalysts and ligands for these reactions will enhance the synthetic utility of the metal-catalyzed isomerization reaction. 

Examples of synthetic applications of these three principal reaction types can be illustrated by the TiCLt-catalyzed interaction of the allylamine 613 with 2-phenylpropanal 614 in refluxing toluene (equation 265)358 as well as by the ZnCl2 promoted rearrangement of N-allylated benzoyl substituted heterocyclic keteneaminals 615 (equation 266)359. 

Isomerization is a frequent side-reaction of catalytic transformations of olefins, however, it can be a very useful synthetic method, as well. One of the best-known examples is the enantioselective allylamine enamine isomerization catalyzed by [Rh (jR)-or(S)-BINAP (COD)] which is the crucial step in the industrial synthesis of L-menthol by Takasago [42]... 

It is a synthetic allylamine derivative, which exerts its antifungal effect by inhibiting squalene epoxidase leading to deficiency of ergosterol and corresponding accumulation of squalene which causes fungal cell death. 

Since the use of ammonia is not practical in transition metal catalyzed processes, the identification of its synthetic equivalents is of major importance. Benzophenone imine was found to couple with 3-bromopyridine readily under the above mentioned conditions (7.72.), The masking benzophenone was removed in transamination with hydroxylamine, which gave the desired 3-aminopyridine in 81% overall yield.92 Allylamine was also successfully employed as ammonia equivalent93... 

The large volume solvents, trichloroethylene and perchloroethylene, are still chiefly made from acetylene, but appreciable amounts of the former are derived from ethylene. The competitive situation between these source materials runs through the whole chlorinated hydrocarbon picture, and extends on to other compound classes as well—for example, acrylonitrile is just on the threshold of a severalfold expansion, as demand grows for synthetic fibers based thereon. Acrylonitrile can be made either from ethylene oxide and hydrogen cyanide, from acetylene and hydrogen cyanide, or from allylamines. The ethylene oxide route is reported to be the only one in current commercial use, but new facilities now under construction will involve the addition of hydrogen cyanide to acetylene (27). 

The cyclization of carbamate derivatives of unsaturated amines has proven synthetically useful. Cyclizations of carbamates of allylamines containing a terminal vinyl group give oxazolidinone products (equation 60 and Table 17, entries 1 and 2).99,161 Bromocyclizations of systems with a di- or tri-sub-stituted alkene often give mixtures of oxazolidinones and tetrahydrooxazinones,163 while cyclization of an A -cinnamyl carbamate with phenylsulfenyl chloride gave only the oxazolidinone product.163b,163c The stereochemistry of the cyclization of primary carbamates of either allylic or homoallylic amines is low... 

Recently it has been reported that the catalytic isomerization of allylic alcohols is promoted by [Rh(diphosphine)(solvent)2]+ at 25°C yields synthetically useful quantities of the corresponding simple enols and that the transformation of allylic alcohols to enols and thereby to ketonic products proceeds catalytically via hydrido-7t-allylic and hydrido-7t-oxy-allylic intermediates, respectively [20]. Consistently observed, enantioselection has been in the process of conversion of a prochiral enol to a chiral aldehyde. Thus, the prochiral substrate 32 is transformed to the optically active aldehyde 34 with 18% ee by using [Rh(BINAP)]+ catalyst (eq 3.13). Accordingly, this isomerization proceeds via a different mechanism from that of the isomerization of allylamine. For the reaction mechanism of the... 

During the past decade, metal-catalyzed asymmetric reactions have become one of the indispensable synthetic methodologies in academic and industrial fields. The asymmetric isomerization of allylamine to an optically active enamine is a typical example of the successful application of basic research to an industrial process. We believe that Takasago s successful development of large-scale asymmetric catalysis will have a great impact on both synthetic chemistry and the fine chemical industries. The Rh-BINAP catalysts, though very expensive, have become one of the cheapest catalysts in the chemical industry through extensive process development. 

Metalated Hydrazones, Formamides, Allylamines, and Aminonitriles in "Current Trends in Organic Synthesis", Nozaki, H., Ed. Pergamon Press Oxford, 1983 p. 151 (d) Enders, D. "Asymmetric Synthesis of Carbonyl Compounds and Primary Amines" in Selectivity - a Goal for Synthetic Efficiency", Bartmann, W. Trost, B. M., Eds. Verlag Chemie Weinheim, 1984 p. 65. (e) Enders, D. Chemiaa Seripta 1985, 25, 139. 

There are rather few reactions that can be described as fully atom economical , i.e. when there are no co-products and all the atoms in the starting material(s) appear in the product(s). However, all isomerisation reactions necessarily fall into this category. The use of a transition metal to catalyse such a process with an appropriate substrate brings the possibility of effecting asymmetric isomerisation, a very efficient method to generate enantiomerically enriched products. Indeed, the asymmetric Rh-catalysed isomerisation of an allylamine to an enamine, which proceeds in over 96% ee, was scaled up a number of years ago for industrial production. The enamine product forms a multi-tonne feedstock for menthol and perfumery synthesis. In contrast, the cyclo-isomerisation of dienes, an equally atom-economical process that generates synthetically useful cyclic products, has seen relatively little development despite the reaction having been known for some 30 years. 

G Petranyi, NS Ryder, A Stutz. Allylamine derivatives new class of synthetic antifungal agents inhibiting fungal squalene epoxidase. Science 224 1239-1241,1984. 

Enantioselective isomerization of olefins for preparation of optically active olefins has great synthetic potential with a long tradition [1] and the non-stereoselective version is probably the most intensively investigated reaction in transition metal catalysis [2]. In particular, stereoselective hydrogen migration in a-functionalized olefins, for example allyl alcohols and allylamines [3], affording optically active aldehydes, ketones and amines, is part of the standard repertoire of enantioselec-... 

Alkenyl aziridines are useful synthetic building blocks and can be converted to allylamines by conjugate addition of organocuprates [29], to pyrroline derivatives by rearrangement [30] and to P-lactams by Pd-catalyzed carbonylation [31]. 

Beak reported that sparteine (111) mediated the conjugate addition of lithi-ated allylamine 114 to give nitroalkene adduct 115 with high diastereoselectivi-ty and enantioselectivity [62]. The product 115 was converted to paroxetine (88) by conventional synthetic manipulations. 

Compound 1216 was then reacted with allylamine in the presence of Et3N to give A, A -diallyl-9//-carbazole-3,6-dicarboxamide 1217, subsequent treatment of compound 1217 with phosgene gave 3,6-dicarboximidoyl dichloride derivative 1218. Ring closure of dichloride 1218 was carried out under basic conditions to give 9-ethyl-3,6-di(l//-pyrrol-2-yl)-9//-carbazole 1219, a relatively low oxidation potential monomer with electron-rich pyrrole rings as terminal electropolymerizable moieties, in an overall synthetic yield of 5.8%. 

As will be further detailed in Section 4.1.2.2, it is possible to effect equilibration of allylamines and the corresponding enamines (for example, equation 11). Such a procedure obviously lacks generality, as in the majority of cases the allylamine would be more difficult to prepare than the enamine. Furthermore, and more importantly, such a sequence for forming enamines removes the ketone functionality from its central role in the synthetic sequence. 

Of particular interest is the asymmetric isomerization with chiral catalysts (e. g., eq. (16)), converting allylic alcohols and ethers as well as allylamines into useful synthetic building blocks [26-29]. 

Addition reactions to olefins can be used both for the construction and for the functionalization of molecules. Accordingly, chiral catalysts have been developed for many different types of reactions, often with very high enantioselectiv-ity. Unfortunately, most either have a narrow synthetic scope or are not yet developed for immediate industrial application due to insufficient activities and/ or productivities. These reactions include hydrocarbonylation [Ilf], hydrosilyla-tion [12 i], hydroboration [12j], hydrocyanation [12 k], Michael addition [11 g, 121, 12 m], Diels-Alder reaction [11 h, 12n] and the insertion of carbenes in C-H bonds [Hi, 12p, 12q, 38], Cyclopropanation [Hi, 12p, 12q] and the isomerization of allylamines [12 s] are already used commercially for the manufacture of Cilastatin (one of the first industrial processes) [12 r], and citronellol and menthol (presently the second largest enantioselective process) [12t] respectively. 

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