Imines with terminal alkynes

Sommer et al. found that Cu(I)-exchanged zeolites (Cu(l)-USY) could be utilized as heterogeneous catalysts for [3 + 2] cycloaddition of azomethine imines with terminal alkynes (Scheme 4.20). This method provides an efficient, versatile, and highly regi-oselective approach to Af,Af-bicyclic pyrazolidinone derivatives, which might exhibit useful bioactivities. The catalysts were readily available, convenient to remove, and reusable (Keller et al., 2009). 

Kobayashi and co-workers successfully achieved the asymmetric 1,3-dipolar cycloaddition reaction of azomethine imines with terminal alkynes catalyzed by CuHMDS and DIP-BINAP ligand to provide N,N-bicyclic pyrazolidinone derivatives in high yields with exclusive regioselectivity and excellent enantioselectivity (Scheme 26) [46]. Mechanistic studies elucidated a stepwise reaction pathway and revealed that the steric character of the ligand determines the regioselectivity. Arai and co-workers applied chiral bis(imidazolidine)pyridine-CuOAc complex to the [3+2]cycloaddition of azomethine imines with propiolates for the construction of bicyclic pyrazolo[l,2-a]pyrazolone derivatives with up to 74% ee [47]. 

Scheme 26 Asymmetric [3+2] cycloaddition of azomethine imines with terminal alkynes...

SCHEME 7.1 Enantioselective cycloadditioD reactions of azomefhine imines with terminal alkynes. 

Asymmetric 1,3-dipolar cycloadditions of azomethine imines with terminal alkynes have been catalysed by 11 chiral ligand (8) coordinated metal amides to form N,N-bicyclic pyrazolidinone derivatives. Mechanistic studies have established the factors that determine the regioselectivity of the stepwise reaction. Novel phosphoramidite ligands (9) coordinated with palladium have been used to effect enantioselective synthesis of pyrrolidines by 3-P 2-cycloaddition of trimethylenemethane (from 2-trimethylsilylmethyl allyl acetate) to a wide range of imine acceptors (Scheme 11). ... 

Application of carbon-carbon cross-coupling/67C-electrocyclization cascade reactions in pyridine synthesis is well known. Larock and coworkers developed a palladium-catalyzed coupling of vinylic imines 279 with terminal alkynes 280 followed by subsequent copper-catalyzed cyclization of 281 to give aryl, vinyl, and alkyl-substituted pyridines 282 in moderate yields. ... 

Sulfonyl azides participate in unique CuAAC reactions with terminal alkynes. Depending on the conditions and reagents, products other than the expected triazole 20 [118] can be obtained, as shown in Scheme 7.9. For example, N-sulfonyl azides are converted to N-sulfonyl amidines 21 when the reaction is conducted in the presence of amines [119]. In the aqueous conditions, N-acyl sulfonamides 22 are the major products [120,121]. In addition to amines and water, the latter can be trapped with imines, furnishing N-sulfonyl azetidinimines 23 [122]. 

The Au(III)-catalyzed double hydroamination cascade reaction of ortho-alkynyla-nilines 167 with terminal alkynes 168 affording N-vinylindoles 169 was reported by li (Scheme 9.63) [221]. In the case of alkyl-substituted acetylenes, this protocol provided mixtures of isomeric N-vinylindoles with both terminal and internal double bonds. This transformation is believed to occur via the Au(III)-catalyzed cydoisomerization of transient key alkynyl imines, similar to 162 utilized by Yamamoto, which were generated via the initial Au(111)-catalyzed hydroamination of the corresponding anilines 167 with alkynes 168. 

It is assumed that cyclization proceeds by Cu-promoted intramolecular nucleophilic addition of the imine moiety to the triple bond (77 —78) with loss of the tBu group by formation of isobutene. The imines 77 are accessible from (2-halogeno)benzaldehydes 80 (X = Br, I) by Sonogashira coupling with terminal alkynes and imine formation with (CH3)3C-NH2 or vice versa. 

From a mechanistic point of view, after a CDC reaction and the loss of a proton (see 4.3), the imine intermediate 32-B is produced and can then react with terminal alkynes to give the all nylated species 32-C. Then, via a Friedel-Crafts reaction of the electron-rich aryl ring with the internal triple bond, followed by an iron-mediated re-aromatization, the desired quinolines are obtained (Scheme 4.32). 

Ytterbium/imine complex [Yb( / -Ph2CNPh)(HMPA)6] was reported as a catalyst for hydrophosphination of alkynes (Scheme 8.55) [137]. From 52% to quantitative product yields were found in the reaction. Regio- and stereoselective transformation was observed in case of internal alkynes, but the reaction with terminal alkynes gave a mixture of a- and -adducts with the former being... 

In a manner analogous to classic nitrile iinines, the additions of trifluoro-methylacetonitrile phenylimine occur regiospecifically with activated terminal alkenes but less selectively with alkynes [39], The nitnle imine reacts with both dimethyl fumarate and dimethyl maleate m moderate yields to give exclusively the trans product, presumably via epimenzation of the labile H at position 4 [40] (equation 42) The nitrile imine exhibits exo selectivities in its reactions with norbornene and norbornadiene, which are similar to those seen for the nitrile oxide [37], and even greater reactivity with enolates than that of the nitnle oxide [38, 41], Reactions of trifluoroacetomtrile phenyl imine with isocyanates, isothiocyanates, and carbodiimides are also reported [42]... 

In the racemic version, the reaction of various terminal alkynes 105 with nitrones 106 was carried out using 10 mol % of Cul in pyridine-DMF at room temperature. As expected, the corresponding azetidinones 107 were formed as a mixture of trans and czs-isomers, along with the imines 108 (Scheme 30). 

The hydroamination of alkynes with primary and secondary ahphatic amines necessitates the use of higher amounts of catalyst (17%) and higher temperatures, and TOFs are low (<1 h ) [260]. With ahphatic and aromatic terminal alkynes and a 5-fold excess of primary aliphahc amines, the products are the corresponding imines (40-78% yield, TOF up to 0.3 h ). In contrast to the CujClj-catalyzed reaction of phenylacetylene and secondary ahphatic amines (Scheme 4-12), the HgClj-catalyzed reachon is fully regioselechve for the Markovnikov hydroamination products which do not evolve under the reachon condihons (Eq. 4.66) [260]. 

Hydroamination of terminal alkynes with primary amines has been performed using organoactinides as catalysts [301, 302]. The organouranium complex Cp 2UMe catalyzes the regioselective formation of imines in fair to high yields (Eq. 4.82). 

Another example of the addition of terminal alkynes to C=N in water is the coupling of alkynes with in-situ-generated A-acylimines (Eq. 4.32) and A-acyliminium ions (Eq. 4.33). In 2002, Li et al. developed a coupling reaction of alkynes with A-acylimines and A-acyliminium ions mediated by Cu(I) in water to generate propargyl amide derivatives.57 Either an activated imine derivative or imininum derivative was proposed as the intermediate, respectively. 

Multicomponent reaction systems are highly valued in solid-phase organic synthesis because several elements of diversity can be introduced in a single transformation.1 The Mannich reaction is a classic example of a three-component system in which an active hydrogen component, such as a terminal alkyne, undergoes condensation with the putative imine species formed from the condensation of an amine with an aldehyde.2 The resultant Mannich adducts contain at least three potential sites for diversification specifically, each individual component—the amine, aldehyde, and alkyne—can be varied in structure and thus provide an element of diversity. 

Terminal alkynes readily react with coordinatively unsaturated transition metal complexes to yield vinylidene complexes. If the vinylidene complex is sufficiently electrophilic, nucleophiles such as amides, alcohols or water can add to the a-carbon atom to yield heteroatom-substituted carbene complexes (Figure 2.10) [129 -135]. If the nucleophile is bound to the alkyne, intramolecular addition to the intermediate vinylidene will lead to the formation of heterocyclic carbene complexes [136-141]. Vinylidene complexes can further undergo [2 -i- 2] cycloadditions with imines, forming azetidin-2-ylidene complexes [142,143]. Cycloaddition to azines leads to the formation of pyrazolidin-3-ylidene complexes [143] (Table 2.7). 

In an analogous late-stage arylation approach, terminal alkyne 31 was envisioned as a versatile intermediate. Slow addition of 4-pentynoyl chloride to imine 3 and (n-Bu)3N at reflux (efficient condenser, 100°C, 12 h, 1 1 toluene heptane) afforded only trace amounts of 31. Reaction of 4-pentynoyl chloride with triethylamine in methylene chloride under preformed ketene conditions ( 78°C, 1 h), followed by addition of 3 and warming to — 10°C over 4 h, afforded a complex mixture of products. Since high-yield preparation of 31 remained elusive, access to internal alkynyl analogs (type 33) was accomplished by preassembly of the appropriate arylalkynyl acid substrate for the ketene-imine cycloaddition reaction (Scheme 13.9). 

Recently, Nakamura and coworkers described a related reaction of the zinc enolates derived from /3-aminocrotonamides of type 395256. In the presence of a stoichiometric amount of Et2Zn, the latter underwent smooth addition to terminal alkynes upon heating in hexane and afforded the corresponding tetrasubstituted 2-alkylidene acetoacetamides 396 (after acidic hydrolysis of the imine) with high (Z)-stereoselectivity (equation 173). 

Laurel Schafer of the University of British Columbia reports (Organic Lett. 2003,5,4733-4736) that terminal alkynes undergo smooth hydroamination with a Ti catalyst. The intermediate imine 4 can be hydrolyzed to the aldehyde 5 or reduced directly to the amine 6. The alkyne to aldehyde conversion has previously been carried out by hydroboration/oxidation (J. Org. Chem. 1996, 61, 3224), hydrosilylation/oxidation (Tetrahedron Lett. 1984,25, 321), or Ru catalysis (J. Am. Chem. Soc. 2001, 123, 11917). There was no previous general procedure for the anti-Markownikov conversion of a terminal alkyne to the amine. 

It has been demonstrated625 that ytterbium-aromatic imine dianion complexes can act as effective catalysts for the isomerization of terminal alkynes to internal alk-2-ynes. Isomerization of acetylenic pentafluorophenyl esters in the presence of phosphines has been found to give rise to activated dienoic acids, which have been coupled directly with amines (and alcohols) in a simple one-pot procedure626 (see Scheme 124). 

Cross-coupling reactions 5-alkenylboron boron compounds, 9, 208 with alkenylpalladium(II) complexes, 8, 280 5-alkylboron boron, 9, 206 in alkyne C-H activations, 10, 157 5-alkynylboron compounds, 9, 212 5-allylboron compounds, 9, 212 allystannanes, 3, 840 for aryl and alkenyl ethers via copper catalysts, 10, 650 via palladium catalysts, 10, 654 5-arylboron boron compounds, 9, 208 with bis(alkoxide)titanium alkyne complexes, 4, 276 carbonyls and imines, 11, 66 in catalytic C-F activation, 1, 737, 1, 748 for C-C bond formation Cadiot-Chodkiewicz reaction, 11, 19 Hiyama reaction, 11, 23 Kumada-Tamao-Corriu reaction, 11, 20 via Migita-Kosugi-Stille reaction, 11, 12 Negishi coupling, 11, 27 overview, 11, 1-37 via Suzuki-Miyaura reaction, 11, 2 terminal alkyne reactions, 11, 15 for C-H activation, 10, 116-117 for C-N bonds via amination, 10, 706 diborons, 9, 167... 

Attylic amines.2 Reaction of 1 with lithium trimethylsilylbenzylamide generates the imine complex (a), a zirconaaziridine, which couples with terminal or symmetrical alkynes to form metallapyrrolines (b). Methanol cleaves Zr-C and Zr-N bonds to provide (Z)-allylic amines in 48-75% yield. 

Treatment of tantalum-alkyne complexes, prepared in situ from TaCls, Zn and RC=CR (R = n-C5Hn), with the lithio-imine Li N=CR Me (R = n-CgHn), followed by aqueous NaOH, gives primary ( )-allylic amines E-RCH=CR-CR Me(NH2). Treatment of these complexes with the terminal alkyne R"C=CH (R" = n-CeHis), followed by aqueous NaOH, yields tetrasubstituted benzene derivatives (99a-d). ... 

Reaction with an amine, AIBN, CO and a tetraalkyltin catalyst also leads to an amide.Benzylic and allylic halides were converted to carboxylic acids electroca-talytically, with CO and a cobalt imine complex. Vinylic halides were similarly converted with CO and nickel cyanide, under phase-transfer conditions.Allylic (9-phosphates were converted to allylic amides with CO and ClTi=NTMS, in the presence of a palladium catalyst. Terminal alkynes were converted to the alkynyl ester using CO, PdBr2, CuBr2 in methanol and sodium bicarbonate. ... 

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