Cyclization tandem/cascade

We will encounter more of these fantastic tandem cascade Pd-induced cyclizations in Chapter 3. 

Tandem carbonyl ylide generation from the reaction of metallo carbenoids with carbonyl continues to be of great interest both mechanistically and synthetically. Effective carbonyl ylide formation in transition metal catalyzed reactions of diazo compounds depends on the catalyst, the diazo species, the nature of the interacting carbonyl group and competition with other processes. The many structurally diverse and highly successful examples of tetrahydrofuran formation cited in this mini-review clearly indicate that the tandem cyclization/cycloaddition cascade of metallo carbenoids has evolved as an important strategy in both carbo- and heterocyclic synthesis. 

We will encounter more of these fantastic tandem cascade Pd-induced cyclizations in Chapter 3. Using microwave heating, Beccalli and co-workers performed an intramolecular Heck cyclization with pyrrole 211 leading to tricycle 212 in excellent yield [127]. 

Beckwith and coworkers reported that the BS model accurately predicts the isomeric outcome during the tandem cascade cyclization of radical 24 (Scheme 2)... 

Triazole Derivatives. Triazole derivatives are known to possess tumor necrosis factor-a (TNF-a) production inhibitor activity. The synthesis of triazole derivatives can be achieved from alkynes or diynes by a tandem cascade reaction involving 1,3-dipolar cycloaddition, anionic cyclization and sigmatropic rearrangement on reaction with sodium azide. Some of the benzoyl triazole derivatives were considered to be potent local anaesthetics and are comparable with Lidocaine. The triazoles can also be prepared from benzoyl acetylenes,triazoloquina-zoline derivatives, 2-trifluoromethyl chromones, aliphatic alkynes, 2-nitroazobenzenes, ring opening of [ 1,2,4]triazolo [5,1-c] [2,4]benzothiazepin-10 (5//)-one, alkenyl esters and dendrimers. A number of these reactions are outlined in eqs 44 8. 

The transition metal catalysis of this tandem (cascade) reaction involving [3,3]-sigmatropic rearrangement (since it would be the carbonyl oxygen of the acetate forming a new bond to the p-acetylenic atom) followed by the formal Myers-Saito cyclization of allene 3.524 results in the formation of aromatic ketones 3.525 in up to 94% yield (Scheme 3.29) [265]. 

The domino cycloaddition-iV-acyliminium ion cyclization cascade has been extensively reviewed. Tandem reactions combining Diels-Alder reactions and sigma-tropic rearrangement reactions in organic synthesis have been extensively reviewed. The tandem Diels-Alder reaction between acetylenedicarboxaldehyde and N,N -dipyrrolylmethane has been extensively studied at the RHT/3-21G and RHF/6-31G levels.The molecular mechanism of the domino Diels-Alder reaction between hexafluorobut-2-yne and A,A -dipyrrolylmethane has been studied using density functional theory. 

Cascade Addition-Cyclization Reactions Given the importance of cascade reactions in modem chemical synthesis, the MacMillan group has proposed expansion of the realm of iminium catalysis to include the activation of tandem bond-forming processes, with a view toward the rapid constraction of natural products. In this context, the addition-cyclization of tryptamines with a,p-unsaturated aldehydes in the presence of imidazolidinone catalysts 11 or 15 has been accomplished to provide pyrroloindoline adducts in high yields and with excellent enantioselectivities (Scheme 11.3a). This transformation is successful... 

McDonald and coworkers studied a series of tandem endo-selective and stereospecific oxacyclization of polyepoxides by reaction with Lewis acid [92-95]. Polyepoxides, such as 50, can be obtained from the epoxidation of triene 49 with ketone 26 (Scheme 8). This cascade cyclization of polyepoxides provides an efficient method to synthesize substituted polycyclic ether structures, which are present in a number of biologically active marine natural products. 

In 2007, Terada et al. extended their previously described chiral phosphoric acid-catalyzed aza-ene-type reaction of M-acyl aldimines with disubstituted enecarbamates (Scheme 28) to a tandem aza-ene-type reaction/cyclization cascade as a one-pot entry to enantioenriched piperidines 121 (Scheme 48). The sequential process was rendered possible by using monosubstituted 122 instead of a disubstituted enecarbamate 76 to produce a reactive aldimine intermediate 123, which is prone to undergo a further aza-ene-type reaction with a second enecarbamate equivalent. Subsequent intramolecular cychzation of intermediate 124 terminates the sequence. The optimal chiral BINOL phosphate (R)-3h (2-5 mol%, R = 4-Ph-C H ) provided the 2,4,6-sub-stituted M-Boc-protected piperidines 121 in good to exceUent yields (68 to > 99%) and accomplished the formation of three stereogenic centers with high diastereo- and exceUent enantiocontrol (7.3 1 to 19 1 transicis, 97 to > 99% ee(trans)) [72]. 

Scheme 48 Tandem aza-ene-type reaction/cyclization cascade scope and reaction intermediates...

Radical cyclization is an effective approach to the synthesis of isoquinolines (Scheme 8). In some cases these offer an alternative to the palladium-catalyzed reactions with aryl halide intermediates <99EJOC1925, 99TL1125>. For example, the radical cyclization of the iodide 37 onto the vinylsulfide moiety was followed by a cascade cyclization to form the benzo[n]quinolizidine system <99TL1149>. In some cases the radical cyclization can take place without the need for a halo intermediate. The reactive intermediate of 38 was formed on the nitrogen as an amidyl radical, which underwent tandem cyclizations to the lycorane system <99TL2125, 99SL441>. 

The number of similar cyclizations, including tandem and cascade sequences where an SnH reaction is a key step, has been considerably increased. As a rule, they are easily performed allowing at times the synthesis of complex polynuclear heterocycles in one step. The present paper, which summarizes about 130 articles on this topic, shows SnH cyclizations to be a very promising strategy for heterocyclic ring annulations. 

An alternative route to the same bicyclic compound 254 is a sequence of cascade cyclizations starting from the acyclic stannane precursor 256. The 2-azabicyclo[2.2.1] heptane ring system is formed stereoselectively from 256 in low yield, by a tandem cyclization, together with the product from monocyclization, the pyrrolidine cis-259 (Scheme 80). 

In addition to cationic cyclizations, other conditions for the cyclization of polyenes and of ene-ynes to steroids have been investigated. Oxidative free-radical cyclizations of polyenes produce steroid nuclei with exquisite stereocontrol. For example, treatment of (259) and (260) with Mn(III) and Cu(II) afford the D-homo-5a-androstane-3-ones (261) and (262), respectively, in approximately 30% yield. In this cyclization, seven asymmetric centers are established in one chemical step (226,227). Another intramolecular cyclization reaction of iodo-ene poly-ynes was reported using a carbopaUadation cascade terminated by carbonylation. This carbometalation—carbonylation cascade using CO at 111 kPa (1.1 atm) at 70°C converted an acycHc iodo—tetra-yne (263) to a D-homo-steroid nucleus (264) [162878-44-6] in approximately 80% yield in one chemical step (228). Intramolecular aimulations between two alkynes and a chromium or tungsten carbene complex have been examined for the formation of a variety of different fiised-ring systems. A tandem Diels-Alder—two-alkyne annulation of a triynylcarbene complex demonstrated the feasibiHty of this strategy for the synthesis of steroid nuclei. Complex (265) was prepared in two steps from commercially available materials. Treatment of (265) with Danishefsky s diene in CH CN at room temperature under an atmosphere of carbon monoxide (101.3 kPa = 1 atm), followed by heating the reaction mixture to 110°C, provided (266) in 62% yield (TBS = tert — butyldimethylsilyl). In a second experiment, a sequential Diels-Alder—two-alkyne annulation of triynylcarbene complex (267) afforded a nonaromatic steroid nucleus (269) in approximately 50% overall yield from the acycHc precursors (229). 

The acyl radical cyclizations have been cleverly applied to the synthesis of complex natural and unnatural products (Eq. (13.4)). In one example, tandem radical cyclization of 14 provides access to the steroidal skeleton. The reaction proceeds through a 6-endo-trig cyclization to form the A/B ring and a macrocycliza-tion/transannulation to establish the C/D ring [12]. More recently, a cascade cyclization initiated by an acyl radical has allowed for the establishment of fourteen chiral centers in a single step [13]. Once again the formation of the polycyclic compound 17 involves sequential 6-endo-trig reactions. 

Some reaction sequences can also be orchestrated so that the first step provides an intermediate that triggers a subsequent conversion. Examples include tandem reactions [13], domino reactions [14], and cascade reactions [15], A comprehensive review of sequential transformations has been compiled by Tietze and Beifuss [16]. An example of the complexity produced by cascading palladium-catalyzed cyclizations [17] is shown in Figure 2.10. 

A tandem anionic cyclization/Dimroth rearrangement was employed for the preparation of y-lactams containing alkylidene substituents (02EJOC221). In this cascade sequence, the dianion of ethyl acetoacetate (272) reacted with 273 to provide furan derivative 274 (Scheme 50) which underwent a subsequent rearrangement to give 275 in 56% yield (04EJOC1897). 

In addition to their use in Mannich (and variant) reactions, iminium ions are useful for other cationic type cyclizations. Corey employed a novel tandem iminium ion cyclization as part of an elegant cascade used for the synthesis of aspidophytine. The reaction of tryptamine 292 and dialdehyde 293 in CH3CN at ambient temperature afforded the pentacyclic skeleton of the alkaloid (296 Scheme 54) (99JA6771). Condensation of the free amino functionality of 292 with the dialdehyde produced a dihydropyridinium intermediate 294 that then cyclized onto the indole n-bond to give 295. The iminium ion so produced underwent a second cyclization with the tethered allylsilane moiety to give 296. Protonation of the enamine in 296 provided still another iminium ion (297) that was then reduced with NaCNBH3 to furnish 298 in 66% yield. All of the above reactions could be made to occur in a single pot. 

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