Intramolecular reactions aldehyde trapping

MacMillan s catalysts 56a and 61 allowed also the combination of the domino 1,4-hydride addition followed by intramolecular Michael addition [44]. The reaction is chemoselective, as the hydride addition takes place first on the iminium-activated enal. The enamine-product of the reaction is trapped in a rapid intramolecular reaction by the enone, as depicted in Scheme 2.54. The intramolecular trapping is efficient, as no formation of the saturated aldehyde can be observed. The best results were obtained with MacMillan s imidazolidinium salt 61 and Hantzsch ester 62 as hydride source. As was the case in the cyclization reaction, the reaction affords the thermodynamic trans product in high selectivity. This transformation sequence is particularly important in demonstrating that the same catalyst may trigger different reactions via different mechanistic pathways, in the same reaction mixture. 

Under strictly anhydrous conditions, the iminophosphorane intermediate that is formed as a result of the Staudinger reaction can react with aldehydes and ketones in an intermolecular fashion (as in the synthesis of imine 36 described above) or intramolecularly with a variety of carbonyl containing functional groups to afford a host of products. Nitrogen containing ring systems such as cyclic imines (44) represent just one of the many products one can prepare and the reaction is particularly well suited for the facile synthesis of five, six, and seven-membered rings. In addition to aldehydes and ketones, carboxylic acids, esters, thio-esters, and amides can also react in an intramolecular fashion to trap an iminophosphorane to afford a variety of heterocycles. Examples from the current literature are described in Section 2.5.5. 

The reaction of aldehydes with Wilkinson s catalyst goes through complexes of the form 26 and 27, which have been trapped. The reaction has been shown to give retention of configuration at a chiral and deuterium labeling demonstrates that the reaction is intramolecular RCOD give RD. 

These lithiooxiranes can be trapped by various electrophiles with retention of the configuration. The addition to aldehydes occurs with a low diastereoselectivity [but this can be enhanced by adding ClTi(OPr-/)3]. The reaction with enones occurs in a 1,2 fashion only. Intramolecular 1,4-silicon shift has also been reported. The reaction of the enantiomerically pure TMS-stabilized lithiooxirane 189 (Scheme 80) with an aldehyde has been used in a total synthesis of (-l-)-cerulenine. It must be noted that protodesi-lylation using TBAF (tetrabutylammonium fluoride) occurs with conservation of the oxirane stereochemistry. 

Hence, lithium salt 343a is trapped by aldehydes, and subsequent intramolecular attack of the intermediate alkoxide on the lactam moiety leads to pyridinophanes 405a and b. Ethanolysis of lactam 288 under acidic or basic conditions, even at —78°C, affords ester 406, whereas the reactions of lactams 288 and 290 with 4-methyl-l,2,4-triazoledione (MXAD) give mixtures of cycloadducts 407a and b or the respective isoquinolines. Tricyclic 290 when irradiated suffers loss of carbon monoxide to form butadiene 408. 

Efforts to trap the carbonyl ylide intermediate by intramolecular [3 + 2] cycloaddition to a C=C bond were unsuccessful. Rather, the decomposition of allyl (trimethylsilyl)diazoacetate (218) (equation 69) in the presence of aldehydes gave 1,3-dioxolan-4-oncs 219 their formation has been explained by 1,5-cyclization of the carbonyl ylide intermediate followed by a Claisen rearrangement122. With acetone as carbonyl component, the reaction proceeds analogously. Clean formation of 219 occurred only with Rh2(OOCC3F7)4 as catalyst, while the copper triflate catalyzed version led to a mixture of 219, an oxirane and the product of intramolecular carbenoid... 

A plausible mechanism for the reaction is depicted in Scheme 13.73. Enol ether 200 reacts with the activated aldehyde to give the oxonium cation 204. This species is trapped intramolecularly by the allylsilane nucleophile and a new tetrahydro-pyran ring 202 is formed. 

The synthesis of complex polycyclic molecules has been achieved by Montgomery et al. by cascade cyclization processes involving nickel enolates [40]. Up to three cycles could be generated in the intramolecular version of the reaction. Alkynyl enal or enone were first converted into their corresponding seven-membered cyclic enolates in the presence of Ni(cod)2/TMEDA [41 ]. These species could be trapped by electrophiles such as aldehydes. For example, upon treatment with the nickel catalyst, dialdehyde 32 afforded spiro-cycle 35 in 49% yield as a single diastereomer (Scheme 17). 

On the basis of the same principle, we developed a three-component synthesis of macrocycles starting from azido amide (46), aldehyde (47) and a-isocyanoaceta-mide (48) (the cx-isocyanoacetamides are easily available, see [84—86]) bearing a terminal triple bond (Scheme 11) [87]. The sequence is initiated by a nucleophilic addition of isonitrile carbon to the in situ generated imine 50 led to the nitrilium intermediate 51, which was in turn trapped by the amide oxygen to afford oxazole 52 (selected examples [88-94]). The oxazole 52, although isolable, was in situ converted to macrocycle 51 by an intramolecular [3+2] cycloaddition upon addition of Cul and diisopropylethylamine (DIPEA). In this MCR, the azido and alkyne functions were not directly involved in the three-component construction of oxazole, but reacted intramolecularly leading to macrocycle once the oxazole (52) was built up. The reaction created five chemical bonds with concurrent formation of one macrocycle, one oxazole and one triazole (Scheme 15). 

Samarium acyl anions can be trapped by electrophiles other than acid halides. For example, addition of a mixture of a carboxylic acid chloride and an aldehyde or ketone to a solution of Sml2 in THF results in the synthesis of a-hydroxy ketones (equations 78 and 79). Intramolecular versions of the reaction have also been performed, although the scope of the reaction is limited owing to the difficulty in obtaining suitable substrates for the reaction (equation 80). ... 

Trimethylsiloxy cyanohydrins (9) derived from an a,3-unsaturatied aldehyde form ambident anions (9a) on deprotonation. The latter can react with electrophiles at the a-position as an acyl anion equivalent (at -78 C) or at the -y-position as a homoenolate equivalent (at 0 C). The lithium salt of (9) reacts exclusively at the a-position with aldehydes and ketones. The initial kinetic product (10) formed at -78 C undergoes an intramolecular 1,4-silyl rearrangement at higher temperature to give (11). Thus the initial kinetic product is trapped and only products resulting from a-attack are observed (see Scheme 11). The a-hydroxyenones (12), -y-lactones (13) and a-trimethylsiloxyenones (11) formed are useful precursors to cyclopentenones and the overall reaction sequence constitutes a three-carbon annelation procedure. 

Low-valent titanium alkoxide complexes have proved to be particularly useful in intramolecular nucleophilic acyl substitution (INAS) reactions. Addition of propargyl alcohol derivatives to 236 has been used as an efficient and practical method for the synthesis of allenyltitanium compounds (Scheme 43).197 Performing the reaction with a homopropargylic carbonate provides access to an alkenyltitanium compound with a lactone moiety.198 This methodology has since been extended to include olefinic carbonates and, through trapping with appropriate electrophiles such as aldehydes and iodine, affords substituted lactones.199... 

Some typical reactions of 1,1 -difluoroethene with nucleophiles are summarized in Scheme 2.18. Alkoxides [3], trialkylsilyl anion [4], ester enolates [5], and diphenylphosphinyl anion [6] attack the gem-difluorinated carbon of 5. However, it is noteworthy that nucleophilic substitution and proton abstraction are in some cases competitive, and thus s -butyl lithium abstracts the (3 -vinylic proton predominantly to generate vinyllithium. The lithium species can be trapped with an aldehyde, providing difluoroallyl alcohol, which is then hydrolyzed to a, (3-unsaturated carboxylic ester (11) [ 7 ] (Scheme 2.19). Some synthetically useful examples are shown in Schemes 2.20 and 2.21. Tetrathiafulvalene derivative (14) is prepared from difluorinated derivative (13) [8]. An elegant intramolecular version was demonstrated by Ichikawa, which provided a range of cyclized compounds (17), including dihydrofurans, thiophenes, pyrroles, and cyclopentenes, and also corresponding benzo derivatives (20) [2]. 

Taking advantage of the multifunctionalities and ready accessibility of methyl (2)-3-(dimethylamino)-2-isocyanoacrylate (Schollkopfs isocyanide) (53), Bienayme and Bouzid developed a four-component synthesis of bicyclic tetrazole 54 (Scheme 5.16) [34]. Simply stirring a methanolic solution of an aldehyde, an amine, 53, and TMSN3 afforded 54 in good to excellent yield. Trapping the nitrilium 55 by azide afforded the intermediate 56, which was subsequently cyclized to furnish the tetrazole 57. A sequence of intramolecular Michael addition followed by (3-elimina-tion of dimethylamine then provided the final product 54. The intermediate tetrazole 57 could be isolated and was found to cyclize to the bicyclic tetrazole 11 in essentially quantitative yield under the reaction conditions. 

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