Addition, intramolecular cyclization

The reaction mechanism proposed for the LiBr/NEta induced azomethine ylide cycloadditions to a,p-unsaturated carbonyl acceptors is illustrated in Scheme 11.10. The ( , )-ylides, reversibly generated from the imine esters, interact with acceptors under frontier orbital control, and the lithium atom of ylides coordinates with the carbonyl oxygen of the acceptors. Either through a direct cycloaddition (path a) or a sequence of Michael addition-intramolecular cyclization (path b), the cycloadducts are produced with endo- and regioselectivity. Path b is more likely, since in some cases Michael adducts are isolated. 

In the presence of cinchona derivatives as catalysts, peroxides or hypochlorites as Michael donors react with electron-deficient olefins to give epoxides via conjugate addition-intramolecular cyclization sequence reactions. Two complementary methodologies have been developed for the asymmetric epoxidation of electron-poor olefins, in which either cinchona-based phase-transfer catalysts or 9-amino-9(deoxy)-epi-dnchona alkaloids are used as organocatalysts. Mechanistically, in these two... 

The greater scope of this reaction was attributed to the dual cyclic Bronsted acid/H-Bond donar cocatalysis mechanism. The catalytic cycle initially involves imine protonation by the chiral thiourea catalyst 170 associated via H-bonding to the conjugate base (X ) of a weak Bronsted acid (H-X, benzoic acid in this case) additive. Intramolecular cyclization of the protonated iminium ion 146, followed by rearomatization regenerates the Bronsted acid cocatlayst (benzoic acid). Note for brevity, the plausible rearrangement (RR) step of the inital CCij-spiroalkylated adduct to the final tetrahydrohydroisoquinoline scaffold 147 is not shown. 

AW-NA-IC Aza-Wittig/intermolecular nucleophilic addition/intramolecular cyclization... 

In contrast to the above additions A-allyl- and substituted A-allyl-amides, -urethanes, -ureas and -thioureas undergo intramolecular cyclization only in 6(3-96% sulfuric acid to give the corresponding oxazolinium and thiazolinium salts. Treatment of these cations with base yields 2-oxazolines and 2-thiazolines in moderate to good yields. The reaction is illustrated by the conversion of A-2-phenylallylacetamide (342) into 2,5-dimethyl-5-phenyl-2-oxazoline (343) in 70% yield 70JOC3768) (see also Chapter 4.19). 

A 1 1 adduct from diphenylsulfilimine and a benzoylacetylene underwent an intramolecular cyclization reaction to give an isoxazole in good yield (equation 40). Similarly, the 1 1 adduct from iodoazide and chalcone gave 3,5-diphenylisoxazole (equation 41). These two approaches to regiospecific isoxazole synthesis are of little practical significance. Additional examples of the (OCCCN) reaction are given in equations (42) and (43). 

Three general approaches to the synthesis of pjTido[2,3-d]pyrimi-dines from pyrimidines are available, all of which utilize an appropriately substituted 4-aminopyrimidine. The pyridine ring may be formed by the addition of three (route i), or two (route ii) carbon atoms, or by the intramolecular cyclization of a propionyl derivative (route in). 

As a substrate, 4-amino-5-acetylenylpyrazole 71 was chosen in this compound the position of interacting groups is the most favorable for intramolecular cyclization. Indeed, 4-amino-l,3-dimethyl-5-phenylethynylpyrazole 71 isomerized into l,3-dimethyl-5-phenylpyrrolo[3,2-c]pyrazole 70 in 65% yield under heating in DMF for 4 h in the presence of Cul (83IZV688). The authors have noticed that the cyclization of 71 is accelerated by the addition of CuC=CPh. 

The Parham cyclization of the iodinated imide 270 by BuLi in dry THF at —78°C afforded 1 lZ -hydroxy-l,3,4,6,7,l lZ -hexahydro[l,4]oxazine[3,4-a]iso-quinolin-4-one 258 (97JOC2080). Iodide-lithium exchange was faster then addition to the carbonyl group of imide 270 and intramolecular cyclization of the initially formed anion gave compound 258. 

In addition to the radical ipso-substitution of indolyl sulfones producing stannanes described earlier <96T11329>, Caddick has also reported an approach to fused [l,2-a]indoles based on the intramolecular cyclization of alkyl radicals. Thus, treatment of 112 with BuaSnH leads to the fused ring derivatives 113 (n = 1-4) <96JCS(P1)675>. 

A stmple and general synthesis of 2,2,4,5-tetrasubstituted furan-3(2//)-ones from 4-hydroxyalk-2-ynones and alkyl halides via tandem CO, addition-elimination protocol is described <96S 1431>. Palladiuni-mediated intramolecular cyclization of substituted pentynoic adds offers a new route to y-arylidenebutyrolactones <96TL1429>. The first total synthesis of (-)-goniofupyrone 39 was reported. Constmction of the dioxabicyclo[4.3.0]nonenone skeleton was achieved by tosylation of an allylic hydroxy group, followed by exposure to TBAF-HF <96TL5389>. 

Chapter 10 considers the role of reactive intermediates—carbocations, carbenes, and radicals—in synthesis. The carbocation reactions covered include the carbonyl-ene reaction, polyolefin cyclization, and carbocation rearrangements. In the carbene section, addition (cyclopropanation) and insertion reactions are emphasized. Recent development of catalysts that provide both selectivity and enantioselectivity are discussed, and both intermolecular and intramolecular (cyclization) addition reactions of radicals are dealt with. The use of atom transfer steps and tandem sequences in synthesis is also illustrated. 

Other degradation products of the cytosine moiety were isolated and characterized. These include 5-hydroxy-2 -deoxycytidine (5-OHdCyd) (22) and 5-hydroxy-2 -deoxyuridine (5-OHdUrd) (23) that are produced from dehydration reactions of 5,6-dihydroxy-5,6-dihydro-2 -deoxycytidine (20) and 5,6-dihydroxy-5,6-dihydro-2 -deoxyuridine (21), respectively. MQ-photosen-sitized oxidation of dCyd also results in the formation of six minor nucleoside photoproducts, which include the two trans diastereomers of AT-(2-de-oxy-/j-D-eryf/iro-pentofuranosyl)-l-carbamoyl-4 5-dihydroxy-imidazolidin-2-one, h/1-(2-deoxy-J8-D-crythro-pentofuranosyl)-N4-ureidocarboxylic acid and the a and [5 anomers of N-(2-deoxy-D-eryfhro-pentosyl)-biuret [32, 53]. In contrast, formation of the latter compounds predominates in OH radical-mediated oxidation of the pyrimidine ring of dCyd, which involves preferential addition of OH radicals at C-5 followed by intramolecular cyclization of 6-hydroperoxy-5-hydroxy-5,6-dihydro-2 -deoxycytidine and subsequent generation of the 4,6-endoperoxides [53]. 

Interestingly, the nucleophilic addition of water in the sequence of events giving rise to 41 represents a relevant model system for investigating the mechanism of the generation of DNA-protein cross-links under radical-mediated oxidative conditions [80, 81]. Thus, it was shown that lysine tethered to dGuo via the 5 -hydroxyl group is able to participate in an intramolecular cyclization reaction with the purine base at C-8, subsequent to one electron oxidation [81]. 

N-donor ligand. The reaction appears to proceed via an acyclic iminoplatinum(II) intermediate that undergoes a subsequent intramolecular cyclization. Some mechanistic aspects of this versatile reaction have been elucidated.225,226 A4-l,2,4-oxadiazolines have been prepared by the [2+3] cycloaddition of various nitrones to coordinated benzonitrile in m-[PtCl2( D M SO)(PhCN)] precursors.227,228 Racemic and chiral [PtCl2(PhMeSO)(PhCN)] complexes have also been used in order to introduce a degree of stereoselectivity into the reaction, resulting in the first enantioselective synthesis of A4-l,2,4-oxadiazolines, which can be liberated from the complexes by the addition of excess ethane-1,2-diamine. 

Interesting intramolecular cyclization of 1-nitroalkyl radicals generated by one-electron oxidation of aci-nitro anions with CAN is reported. As shown in Eq. 5.44, stereoselective formation of 3,4-functionalized tetrahydrofurans is observed.62 l-Nitro-6-heptenyl radicals generated by one electron oxidation of aci-nitroanions with CAN afford 2,3,4-trisubstituted tetrahydropyrans.63 The requisite nitro compounds are prepared by the Michael addition of 3-buten-l-al to nitroalkenes. 

The reaction of 2-polyfluoroalkylchromones (e.g., 323) with l,3,3-dimethyl-3,4-dihydroisoquinolines (e.g., 324) gave zwitterionic 6,7-dihydrobenzo[ ]quinolizinium compounds such as 326 (Scheme 70). The mechanism proposed for this transformation involves an addition-elimination displacement of the chromane heterocyclic oxygen by the enamine tautomer of the dihydroisoquinoline, followed by intramolecular cyclization of the intermediate 325 <20030L3123>. 

Intramolecular cyclizations could also be achieved by oxidation of 57 with PCC to 65 regioselective addition of an organometallic onto the 7(2)-carbonyl carbon of 65 was followed by treatment with acid to generate the iminium cation, and intramolecular trapping of the cation by an appropriate N-2 substituent (e.g., phenylethyl substituent) <2001TA2883> or C-4 substituent (e.g., benzyl group) <2002T6163>. 

Many versatile approaches to the construction of fused heterocyclic systems (6 5 6) with ring junction heteroatoms have been reported. More general reactions which can be used for synthesis of derivatives of several tricyclic systems, and transformations which have potential for use in the preparation of a series of substituted compounds, are discussed in this section. Formation of the five-membered ring is presented first because it is a conceptually simple approach. It should be noted, however, that the addition of a fused six-membered ring to a bicyclic component offers much more versatility in the construction of a (6 5 6) system. Each subsection below starts with intramolecular cyclization of an isolated intermediate product. Reactions which follow are one-pot intermolecular cyclizations. 

Diterpenoids related to lambertianic acid were prepared by intramolecular cyclization of either an alkene or an alkyne with a furan ring <2005RJ01145>. On heating amine 101 with allyl bromide, the intermediate ammonium ion 102 was formed which then underwent [4+2] cycloadditions in situ to give the spiroazonium bromides 103 and 104 (Scheme 13). These isomers arose from either endo- or co-transition states. The analogous reaction was also carried out with the same amine 101 and propargyl bromide. The products 105 and 106 contain an additional double bond and were isolated in 58% yield. The product ratios of 103 104 and 105 106 were not presented. 

The most studied catalyst family of this type are lithium alkyls. With relatively non-bulky substituents, for example nBuLi, the polymerization of MMA is complicated by side reactions.4 0 These may be suppressed if bulkier initiators such as 1,1-diphenylhexyllithium are used,431 especially at low temperature (typically —78 °C), allowing the synthesis of block copolymers.432,433 The addition of bulky lithium alkoxides to alkyllithium initiators also retards the rate of intramolecular cyclization, thus allowing the polymerization temperature to be raised.427 LiCl has been used to similar effect, allowing monodisperse PMMA (Mw/Mn = 1.2) to be prepared at —20 °C.434 Sterically hindered lithium aluminum alkyls have been used at ambient (or higher) temperature to polymerize MMA in a controlled way.435 This process has been termed screened anionic polymerization since the bulky alkyl substituents screen the propagating terminus from side reactions. 

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