Amine-thioureas

Direct measurements on metals such as iron, nickel and stainless steel have shown that adsorption occurs from acid solutions of inhibitors such as iodide ions, carbon monoxide and organic compounds such as amines , thioureas , sulphoxides , sulphidesand mer-captans. These studies have shown that the efficiency of inhibition (expressed as the relative reduction in corrosion rate) can be qualitatively related to the amount of adsorbed inhibitor on the metal surface. However, no detailed quantitative correlation has yet been achieved between these parameters. There is some evidence that adsorption of inhibitor species at low surface coverage d (for complete surface coverage 0=1) may be more effective in producing inhibition than adsorption at high surface coverage. In particular, the adsorption of polyvinyl pyridine on iron in hydrochloric acid at 0 < 0 -1 monolayer has been found to produce an 80% reduction in corrosion rate . 

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]. 

With ketone donors, both syn and anti selective reactions are possible. Typically, a,p-unsaturated nitro compounds are used as acceptors. The majority of these reactions are syn selective (Scheme 28) [94, 269, 271, 278, 279, 288-309]. This is a result of favored formation of the (fj-configured enamine and favorable electrostatic interactions between the nitro group and the enamine (Scheme 29) [290, 291, 310]. Of the known anti selective reactions, primary amine-thiourea catalysts such as 158 appear to perform best (Scheme 28) [271, 299, 301]. 

Wang and co-workers reported a novel class of organocatalysts for the asymmetric Michael addition of 2,4-pentandiones to nitro-olefms [131]. A screen of catalyst types showed that the binaphthol-derived amine thiourea promoted the enantiose-lective addition in high yield and selectivity, unlike the cyclohexane-diamine catalysts and Cinchona alkaloids (Scheme 77, Table 5). 

Apart from the increased catalytic efficiency, this structure design produced two positive side effects. In contrast to monofunctional (thio)ureas, which exhibit low solubility in nonpolar solvents due to intermolecular hydrogen-bonding association, tertiary amine thioureas of type 12 revealed intramolecular hydrogen bonding between the amine group and the amide protons making these (thio)ureas soluble in nonpolar reaction media such as toluene. The analysis of the X-ray crystal-... 

Figure 6.22 Primary and tertiary amine thioureas evaluated for catalytic efficiency in the cyanosilylation of acetophenone.

Scheme 6.102 Bifunctional catalysis with primary amine thiourea 99 Proposed transition states to explain the onfi-diastereoselectivity (A) and the syn- diastereoselectivity (B) of the Michael addition of both acylic and cyclic ketones to frans-P-nitrostyrene.

Scheme 6.105 Asymmetric Michael addition of phenylpropionaldehyde to trar)s- 3-nitrostyrene catalyzed by primary amine thioureas 102, 104, and 105.

Scheme 6.154 Proposed catalytic cycle for the binaphthyl amine thiourea-promoted MBH reaction of aldehydes with 2-cyclohexen-l-one revealing the bifunctional mode of action of catalyst 148, 149, and 150.

Scheme 6.176 Synthesis of bifunctional saccharide-based amine thioureas 207-210 from the corresponding glucose-, maltose, and lactose-isothiocyanates, respectively.

The highly enantioselective direct conjugate addition of ketones to nitroalkenes has been promoted by a chiral primary amine-thiourea catalyst (7).31 The observed anti diastereoselectivity has suggested participation of a (Z)-enamine intermediate, given (g) the complementary diastereoselectivity obtained in analogous reactions involving (E)-enamines generated from secondary amine catalysts. 

One of the most commonly used class of derivatization agents for diasteromer formation are isothiocyanates and isocyanates. Enantiomers of /3-blockers, amphetamine, epinephrine, methamphetamine, and mexiletine have been resolved after derivatization with these agents. Isothiocyanates produce thiourea derivatives upon reaction with primary and secondary amines. Thiourea derivatives also provide a strong UV absorbance for the detection of enantiomers lacking a strong UV chromophore. Isocyanates produce ureas when reacted with amines. The physical properties of these ureas are similar to thiourea derivatives. Isocyanates will also react with alcohols to yield carbamates. 

Cyclohexanediamine-derived amine thiourea 70, which provided high enantio-selectivities for the Michael addition [77] and aza-Henry reactions [78], showed poor activity in the MBH reaction. This fact is not surprising when one considers that a chiral urea catalyst functions by fundamentally different stereoinduction mechanisms in the MBH reaction, and in the activation of related imine substrates in Mannich or Streclcer reactions [80]. In contrast, the binaph-thylamine thiourea 71 mediated the addition of dihydrocinnamaldehyde 74 to cyclohexenone 75 in high yield (83%) and enantioselectivity (71% ee) (Table 5.6, entry 2) [79]. The more bulky diethyl analogue 72 displayed similar enantioselectivity (73% ee) while affording a lower yield (56%, entry 3). Catalyst 73 showed only low catalytic activity in the MBH reaction (18%, entry 4). 

Table 5.6 The chiral tertiary amine/thiourea-catalyzed MBH reaction of dihydrocinnamaldehyde with cyclohexenone.

Table 5.7 Bifunctional tertiary amine/thiourea catalyst in MBH reaction of cyclohexenone and selected aldehydes.

Chen and co-workers later reported the successful asymmetric 1,4-addition of aryl thiols to a,/ -unsaturated cyclic enones and imides using Takemoto s elegantly simple catalyst (3) [43]. This bifunctional amine-thiourea catalyst gives optimal reactivity and reproducibility when used at 10 mol% loading in the presence of freshly dried 4 A molecular sieves (MS). This combination afforded the expected addition products in high yields (90-99%) and moderate to good enantioselectiv-ities (55-85% ee) for a variety of cyclic and acyclic Michael acceptors (Table 6.2). 

Disubstituted thiochroman-4-ols are formed with excellent enantio- and diastereo-selectivity when thiosalicylaldehydes react with an a,P-unsaturated oxazolidinone in the presence of a chiral bifunctional amine-thiourea catalyst. A tandem Michael - aldol process is involved (Scheme 43) <07JA1036>. 

Chiral bifunctional primary amine-thiourea/ f-BuNH2.TFA/DCM/25 °C (09MI1) 12/EtOH/rt (09MI2)... 

A number of BINOL-based bifunctional organocatalysts, for example (7.171-7.173), containing both Bronsted acidic and Lewis basic sites have been used to good effect in the asymmetric MBH reaction. The amine-thiourea (7.171) promotes the MBH reaction of aliphatic aldehydes with 2-cyclohexenone with ees ranging from 80 to 94% while both the (pyridinylaminomethyl)BINOL (7.172) and phosphine (7.173) catalyse the aza-Bayhs-Hilhnan reaction of simple a,p-carbonyls such as MVK and phenyl acrylate with N-tosyl arylaldmines with similar levels of enantioselectivity. 

Scheme 2.9 Enantioselective Michael reactions of ketones with nitrost5renes catalyzed by primary amine-thiourea catalysts.

On the other hand, several primary amines have also been successfully employed as catalysts in the reaction using aldehydes as Michael donors. Important representative examples are shown in Figure 2.7, like bifunctional sulfamide 36 and primary amine-thioureas 37a and 23b,the latter being developed by Jacobsen and very similar to that used by the same group in the reaction with ketones as donors (see Scheme 2.7) and which performs exceptionally well in the Michael reaction of a,a-disubstituted aldehydes to both aromatic and aliphatic nitroolefins. 

There is an interesting variant of this reaction which involves the use of tert-butyldimethylsilyloxyacetaldehyde as Michael donors and chiral primary amine thiourea bifunctional catalyst 37b (Scheme 2.13). In this case, the diastereoselectivity of the reaction changed from the usually observed syn relative stereochemistry at the final Michael adduct to the formation of the anti diastereoisomer as the major product. This change in diastereoselectivity was explained in terms of the generation of a Z-enamine intermediate assisted by the formation of an intramolecular hydrogen bond between the secondary... 

Scheme 3.21 Enantioselective Michael addition of nitroalkanes to acyclic enones catalyzed by imidazolidines 53a and 53c, proline tetrazole 2a and amine-thiourea ent-37b.

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