Skeleton bicycle

The silyl enol ethers 209 and 212 are considered to be sources of carbanions. and their transmetallation with Pd(OAc)2 forms the Pd enolate 210. or o.w-tt-allylpalladium, which undergoes the intramolecular alkene insertion and. 1-elimination to give 3-methylcyclopentenone (211) and a bicyclic system 213[199], Five- and six-membered rings can be prepared by this reaction[200]. Use of benzoquinone makes the reaction catalytic. The reaction has been used for syntheses of skeletons of natural products, such as the phyllocladine intermediate 214[201], capnellene[202], the stemodin intermediate 215[203] and hir-sutene [204]. 

The same tertiary carbocation serves as the precursor to numerous bicyclic monoterpenes A carbocation having a bicychc skeleton is formed by intramolecular attack of the rr electrons of the double bond on the positively charged carbon... 

For bicyclic structures the von Baeyer name consists of the prefix bicyclo-, followed in square brackets by the numbers of carbon atoms separating the bridgeheads on the three possible routes from one bridgehead to the other, followed in turn by the name of the alkane (or other homogeneous hydride, or repeating unit hydride) containing the same number of atoms in the chain as the whole bicyclic skeleton (examples 55-57). Replacement nomenclature can be applied to hydrocarbon names (example 58). 

Chemistry of conjugated heterocycles built from furan pyrrole, or thiophene ring fused with bicyclic (norbomadiene, bomene, or azanorbomene) skeletons 98YGK192. 

The combination of the Diels-Alder reaction of fi-sulfonylnitroethylene and the Barton-Zard reaction provides a new synthesis of pyrroles fused with polycyclic skeletons fEq 10 31 Pyrroles fused with bicycle [3 3 3 Qctodiene are important precursors for synthesis of isoindoles via the retro Diels-Alder reaction fEq 10 33 ... 

Bicyclic phthalocyanines possess an unusual skeleton built from three halves of a normal phthalocyanine macrocycle, arranged like a propeller. Such compounds are formed by treating phthalonitrile at low pressure and high temperature (0.1 atm, N2,210 C, 1-2 d) in the presence of thallium148 or indium (yield 5%).146... 

Following Uskokovic s seminal quinine synthesis [40], Jacobsen has very recently reported the first catalytic asymmetric synthesis of quinine and quinidine. The stereospecific construction of the bicyclic framework, introducing the relative and absolute stereochemistry at the Cg- and expositions, was achieved by way of the enantiomerically enriched trans epoxide 87, prepared from olefin 86 by SAD (AD-mix (3) and subsequent one-pot cyclization of the corresponding diol [2b], The key intramolecular SN2 reaction between the Ni- and the Cg-positions was accomplished by removal of the benzyl carbamate with Et2AlCl/thioanisole and subsequent thermal cyclization to give the desired quinudidine skeleton (Scheme 8.22) [41],... 

Aziridinocyclopropanes 163 derived from 2-phenylsulfonyl-l,3-dienes undergo BF3-induced rearrangement to bicyclic amines 165, which feature the skeleton of the tropane alkaloids. The reaction proceeds via cyclopropyl carbinyl cation 164, an intermediate also invoked in the analogous epoxide rearrangements. Trapping by fluoride ion is a competing pathway <96TL3371>. 

Whenever we have a structure where the wedges and dashes are implied but not drawn, it is much easier to use this method. There are other examples of carbon skeletons that, by convention, do not show the wedges and dashes. Most of these examples are rigid bicyclic systems. For example. 

Cyclopropyl ketones 95 also react with enol ether 100 in presence of 5 mol% of [Au(NTf2)(lPr)] in a [4+2] cycloaddition reaction to afford the bicycle[3.2.0] heptane skeleton 101 (Scheme 5.26) [26]. 

Thus, the dianion derived from a-amino acid substitutes the j8-chloride to give the ester of 2-(phenylsulfonyl)ethenyl amino acid and subsequent desulfonylation provides N-(benzoyl)vinylalanine methyl ester (62) (equation 61). The conjugate addition of enolates to methyl styryl sulfone (63) and subsequent intramolecular addition to the carbonyl moiety provide a synthetically valuable method for the construction of bicyclic and tricyclic skeletons . Desulfonylation of the cyclization product 64 with sodium in ethanol-THF gives the diene 65 in good yield (equation 62). 

An interesting extension of the above reactions in the achiral series is the facile, regioselective, one-pot bicyclization of aminodialkenes leading to a variety of polycyclic heteroatom-containing skeletons (Eq. 4.25) [137]. 

As in the case of aminodialkenes (see above), hydroamination/bicyclizations of aminoalkenynes allow the regiospecific synthesis of pyrrolizidine skeletons (Eq. 4.87) [138, 303]. 

Scheme 10.1 gives some representative examples of laboratory syntheses involving polyene cyclization. The cyclization in Entry 1 is done in anhydrous formic acid and involves the formation of a symmetric tertiary allylic carbocation. The cyclization forms a six-membered ring by attack at the terminal carbon of the vinyl group. The bicyclic cation is captured as the formate ester. Entry 2 also involves initiation by a symmetric allylic cation. In this case, the triene unit cyclizes to a tricyclic ring system. Entry 3 results in the formation of the steroidal skeleton with termination by capture of the alkynyl group and formation of a ketone. The cyclization in Entry 4 is initiated by epoxide opening. 

Subsequently we demonstrated the generality and effectiveness of this synthetic approach to bicyclic peroxides. Among the basic skeletons that have been prepared, figure the [2.2.1]-, [2.2.2]-, [3.2.2]-, [4.2.1]- and [4.2.2]-bicycloperoxides, whose structures are shown below. 

This important modification enabled us to prepare a number of bicyclic peroxides possessing the [2.2.1]-skeleton, of which the important ones are shown below. 

Not only has the prostanoid [2.2.1] skeleton yielded to the onslaught, but seven other bicyclic peroxide systems have also been obtained. Particularly versatile have been the singlet oxygen-diimide and silver salt routes which have provided higher [n.2.2] systems (n = 2-4), and [n.2.1] systems (n = 3-5) respectively the [3.3.2] skeleton, unique in its lack of both 5- and 6-membered peroxide rings, was afforded via peroxymercuration. 

Another Lewis acid-catalyzed atom-transfer domino radical cyclization, to produce various bicyclic and tricyclic ring skeletons, has been developed by Yang and coworkers [54]. Reactions of the a-bromo-(3-keto ester 3-125 with Yb(OTf)3 and Et3B/02 led to the bicycle 3-126 in 85 % yield (Scheme 3.33). The reaction proceeds via a (>-endo-Irig and 5-exo-trig cyclization after initial abstraction of the bromine... 

An additional prerequisite in this reaction, however, is inhibition of a premature P-hydrogen elimination. Reaction of 6/4-56 and 6/4-57 led to 6/4-58 with 41 % yield. Again, one can assume that first a Ni-complex 6/4-59 is formed, which gives the bicyclic 6/4-60 followed by formation of the triquinane skeleton 6/4-58 via 6/4-61 with a P-hydride elimination being the last step (Scheme 6/4.15). 

A double RCM reaction of 367 permitted the efficient construction of the fused bicyclic quinolizidine skeleton 368 as the major product, together with a small amount of the other possible double-metathesis product 369 (Scheme 84) <20020L639, 2004CEJ3286>. Similarly, an RCEYM process from substrate 370, carried out in an atmosphere of ethylene, afforded the quinolizine derivative 371 <2004JOC6305>. 

Intramolecular cycloadditions are among the most efficient methods for the synthesis of fused bicyclic ring systems [30]. From this perspective, the hetisine skeleton encompasses two key retro-cycloaddition key elements. (1) a bridging pyrrolidine ring accessible via a [3+2] azomethine dipolar cycloaddition and (2) a [2.2.2] bicyclo-octane accessible via a [4+2] Diels-Alder carbocyclic cycloaddition (Chart 1.4). While intramolecular [4+2] Diels—Alder cycloadditions to form [2.2.2] bicycle-octane systems have extensive precedence [3+2], azomethine dipolar cycloadditions to form highly fused aza systems are rare [31-33]. The staging of these two operations in sequence is critical to a unified synthetic plan. As the proposed [3+2] dipolar cycloaddition is expected to be the more challenging of the two transformations, it should be conducted in an early phase in the forward synthetic direction. As a result, a retrosynthetic analysis would entail initial consideration of the [4+2] cycloaddition to arrive at the optimal retrosynthetic C-C bond disconnections for this transformation. 

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