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Intramolecular chemoselectivity

The selectivity for two-alkyne annulation can be increased by involving an intramolecular tethering of the carbene complex to both alkynes. This was accomplished by the synthesis of aryl-diynecarbene complexes 115 and 116 from the triynylcarbene complexes 113 and 114, respectively, and Danishefsky s diene in a Diels-Alder reaction [70a]. The diene adds chemoselectively to the triple bond next to the electrophilic carbene carbon. The thermally induced two-alkyne annulation of the complexes 115 and 116 was performed in benzene and yielded the steroid ring systems 117 and 118 (Scheme 51). This tandem Diels-Alder/two-alkyne annulation, which could also be applied in a one-pot procedure, offers new strategies for steroid synthesis in the class O—>ABCD. [Pg.149]

In this chapter we describe a novel, safe and efficient large-scale synthetic approach to tricycle thienobenzazepines. The key steps in the synthesis include a chemoselective hydrogenation of an aryl-nitro functionality in the presence of a 3-bromo thiophene and a subsequent palladium-catalyzed intramolecular aminocarbonylation telescoped sequentially after simple catalyst and solvent exchange. [Pg.62]

Palladium-catalyzed cyclization of alkenes and alkynes were reported by Balme and co-workers.143 144 Intramolecular carbopalladation occurs to give polycyclic compounds. It has been shown that the nucleophile type has a large influence on the cyclization process. Both 5-exo- and 6-endo-cyclization are observed for substrates with nitrile (116 and 118) and ester (120, 122, and 124) substituents, respectively (Scheme 36). When a mixed nucleophile (CN and C02Me) is used, a mixture of 5-exo and 6-endo products is obtained. The chemoselectivity is controlled by the size of the nucleophile used. The stereochemistry of the initial double bond plays an important role on the stereoselectivity of the cyclization. (Z)-olefins (118 and 120) and (/. )-olefins (116 and 124) afford as- (119 and 121) and trans-cyclization products (117 and 123), respectively. [Pg.316]

An intramolecular cycloaddition also occurred with 3-ylidenepiperazine-2,5-diones such as 124 or 125, obtained by Wittig-Horner-Emmons reaction from phosphonate 121 and aldehydes 122 or 123, respectively. The products of the Diels-Alder reaction are the bridged bicyclo[2.2.2]diazaoctane rings 126 and 127 that have been found in biologically active secondary metabolite such as VM55599 and brevianamide A. The different type of structures employed in this case requires a chemoselective reaction in order to produce the expected products as single diastereoisomers after 20 days (Scheme 18) <2001JOC3984>. [Pg.512]

An unusual case of intramolecular competition (chemoselectivity, see Chapt. 1 in [la]) between ester and oxirane occurs in the detoxification of (oxiran-2-yl)methyl 2-ethyl-2,5-dimethylhexanoate (10.49), one of the most abundant isomers of an epoxy resin. The compound is chemically very stable, i.e., resistant to aqueous hydrolysis, but is rapidly hydrolyzed in cytosolic and microsomal preparations by epoxide hydrolase and carboxylesterase, which attack the epoxide and ester groups, respectively [129], The rate of overall enzymatic hydrolysis was species dependent, decreasing in the order mouse > rat > human, but was relatively fast in all tissues examined (lung and skin as portals of entry, and liver as a further barrier). In mouse and rat lung microsomes, ester hydrolysis was 3-4 times faster than epoxide hydration, whereas the opposite was true in human lung microsomes. [Pg.639]

Chemoselective anodic methoxylation at a distinct carbon atom in the a-position to an amino group in a polypeptide was achieved by prior introduction of a silyl group as an electroauxiliary at this carbon atom [156]. Amide oxidation in A-acetylpyrrolidines substituted with electron-rich phenyl rings led to either methoxylation a to the nitrogen atom or in the benzylic position. Mechanistic studies indicate that both the amide and the phenyl oxidation compete, but intramolecular electron transfer leads to... [Pg.418]

Sometimes, instead of using protecting groups as chemoselective control elements it may be more convenient to resort to activating groups as, for instance, the S-2-pyridylcarboxylic esters (24) which react intramolecularly to give macrolides 25 in excellent yields [20] (Scheme 12.7). [Pg.323]

The different synthetic applications of acceptor-substituted carbene complexes will be discussed in the following sections. The reactions have been ordered according to their mechanism. Because electrophilic carbene complexes can undergo several different types of reaction, elaborate substrates might be transformed with little chemoselectivity. For instance, the phenylalanine-derived diazoamide shown in Figure 4.5 undergoes simultaneous intramolecular C-H insertion into both benzylic positions, intramolecular cyclopropanation of one phenyl group, and hydride abstraction when treated with rhodium(II) acetate. [Pg.178]

Intramolecular C-H bond insertion and ylide formation can compete with cyclopropanation. As shown in Figure 4.21, however, the chemoselectivity of the intermediate carbene complex can sometimes be controlled by the remaining metal-bound ligands [21,990,1075,1081,1223]. [Pg.221]

The skeleton of 47 is a heterocyclic tricyclo[6.2.0.0 ]decane and the similarity to the tricyclic kelsoene is obvious. In the course of the above-mentioned studies we had become curious whether the high facial diastereocontrol in the photocycloaddition reaction could be extended to other bridged 1,6-hexadienes. Kelsoene was an ideal test case. The retrosynthetic strategy for kelsoene along an intramolecular [2+2]-photocycloaddition pathway appeared straightforward. To avoid chemoselectivity problems the precursor to kelsoene should not contain additional double bonds. Alcohol 48, the hydroxy group of which was possibly to be protected, seemed to be a suitable substrate for the photocycloaddition (Scheme 14). Access to the 1,2,3-substi-... [Pg.14]

The sulfone moiety was reductively removed and the TBS ether was cleaved chemoselectively in the presence of a TPS ether to afford a primary alcohol (Scheme 13). The alcohol was transformed into the corresponding bromide that served as alkylating agent for the deprotonated ethyl 2-(di-ethylphosphono)propionate. Bromination and phosphonate alkylation were performed in a one-pot procedure [33]. The TPS protecting group was removed and the alcohol was then oxidized to afford the aldehyde 68 [42]. An intramolecular HWE reaction under Masamune-Roush conditions provided a macrocycle as a mixture of double bond isomers [43]. The ElZ isomers were separated after the reduction of the a, -unsaturated ester to the allylic alcohol 84. Deprotection of the tertiary alcohol and protection of the prima-... [Pg.91]

The most spectacular application of the donor/acceptor-substituted carbenoids has been intermolecular C-H activation by means of carbenoid-induced C-H insertion [17]. Prior to the development of the donor/acceptor carbenoids, the intermolecular C-H insertion was not considered synthetically useful [5]. Since these carbenoid intermediates were not sufficiently selective and they were very prone to carbene dimerization, intramolecular reactions were required in order to control the chemistry effectively [17]. The enhanced chemoselectivity of the donor/acceptor-substituted carbenoids has enabled intermolecular C-H insertion to become a very practical enantioselective method for C-H activation. Since the initial report in 1997 [121], the field of intermolecular enantioselective C-H insertion has undergone explosive growth [14, 15]. Excellent levels of asymmetric induction are obtained when these carbenoids are derived... [Pg.328]

Intramolecular carbon-hydrogen insertion reactions have well known to be elTectively promoted by dirhodium(ll) catalysts [19-23]. Insertion into the y-position to form five-membered ring compounds is virtually exclusive, and in competitive experiments the expected reactivity for electrophilic carbene insertion (3°>2° 1°) is observed [49], as is heteroatom activation [50]. A recent theoretical treatment [51] confirmed the mechanistic proposal (Scheme 15.4) that C-C and C-H bond formation with the carbene carbon proceeds in a concerted fashion as the ligated metal dissociates [52]. Chemoselectivity is dependent on the catalyst ligands [53]. [Pg.348]

As with any modern review of the chemical Hterature, the subject discussed in this chapter touches upon topics that are the focus of related books and articles. For example, there is a well recognized tome on the 1,3-dipolar cycloaddition reaction that is an excellent introduction to the many varieties of this transformation [1]. More specific reviews involving the use of rhodium(II) in carbonyl ylide cycloadditions [2] and intramolecular 1,3-dipolar cycloaddition reactions have also appeared [3, 4]. The use of rhodium for the creation and reaction of carbenes as electrophilic species [5, 6], their use in intramolecular carbenoid reactions [7], and the formation of ylides via the reaction with heteroatoms have also been described [8]. Reviews of rhodium(II) ligand-based chemoselectivity [9], rhodium(11)-mediated macrocyclizations [10], and asymmetric rho-dium(II)-carbene transformations [11, 12] detail the multiple aspects of control and applications that make this such a powerful chemical transformation. In addition to these reviews, several books have appeared since around 1998 describing the catalytic reactions of diazo compounds [13], cycloaddition reactions in organic synthesis [14], and synthetic applications of the 1,3-dipolar cycloaddition [15]. [Pg.433]

While the perfluorinated acetates do prefer insertion, they are still capable of forming 1,3-dipoles and have demonstrated interesting effects on the regioselectivity of intramolecular cycloaddition reactions, presumably through Lewis acid-mediated effects on the dipolarophile [83]. Other chemoselectivity effects have been noted in the intramolecular cycloaddition reactions and may or may not be partially induced by conformation and sterics [84]. It was further demonstrated thaL when possible, O-H insertion is the predominant outcome over other types of insertion for rhodium]II)-car-benes, independently of the catalyst. However, cycloaddition reactions have been demonstrated to be hgand-dependent [85]. [Pg.438]

Convertible isocyanide reagent 66 allows a mild and chemoselective in situ post-Ugi activation of the isonitrile bom amide with simultaneous deprotection of the nucleophilic amine, that is, liberation and activation of two Ugi-reactive groups, if desired also under subsequent lactam formation [33]. Another recently introduced convertible isocyanide, l-isocyano-2-(2,2-dimethoxyethyl)-benzene 73, was shown effective by Rhoden et al. In the course of this short sequence, a hydrolytically labile W-acylindole 78 is formed, which is displaced intramolecularly by the amine portion of the former Boc-protected amino acid 75 (Scheme 13). [Pg.98]

Bennasar et al. reported a new radical-based route for the synthesis of calothrixin B (378) (869). This synthesis starts from the 2,3-disubstituted N-Boc indole 1558 and uses a regioselective intramolecular acylation of a quinoline ring as the key step for the construction of the calothrixin pentacyclic framework. Chemoselective reaction of in s/fM-generated 3-lithio-2-bromoquinoline [from 2-bromoquinoline 1559 with LDA] with the 3-formylindole 1558 followed by triethylsilane reduction of the... [Pg.379]

Chatani s proposed mechanism bears some similarity to that of Jun s reaction (Scheme 9.12). They both begin with hydroamination of the C=C 7t-bond of a rhodium vinylidene. The resultant aminocarbene complexes (71 and 62) are each in equilibrium with two tautomers. The conversion of 71 to imidoyl-alkyne complex 74 involves an intramolecular olefin hydroalkynylation. Intramolecular syn-carbome-tallation of intermediate 74 is thought to be responsible for ring closure and the apparent stereospecificity of the overall reaction. In the light of the complexity of Chatani and coworkers mechanism, the levels of chemoselectivity that they achieved should be considered remarkable. For example, 5 -endo-cyclization of intermediate 72 was not observed, though it has been for more stabilized rhodium aminocarbenes bearing pendant olefins [27]. [Pg.296]

Section 2 discusses the syntheses of different classes of concave acids and bases. Convergent synthetic strategies were chosen for an easy structural variation of the reagents (modular assembly). Section 3 characterizes the concave acids and concave bases and checks whether the acid/base properties of the parent compounds benzoic acid, pyridine and 1,10-phenanthroline are conserved in the bimacrocyclic structures. In Section 4, the influence of the concave shielding on the reactivity and selectivity of the concave reagents is measured in model reactions. In principle, the concave shielding should be able to influence inter- and intramolecular competitions as well as chemoselectivity and (dia)stereoselectivity. If the reagent is chiral, enantioselectivity should also be observable. [Pg.61]

See other pages where Intramolecular chemoselectivity is mentioned: [Pg.105]    [Pg.105]    [Pg.172]    [Pg.387]    [Pg.298]    [Pg.270]    [Pg.160]    [Pg.108]    [Pg.232]    [Pg.182]    [Pg.357]    [Pg.809]    [Pg.46]    [Pg.523]    [Pg.47]    [Pg.232]    [Pg.247]    [Pg.376]    [Pg.221]    [Pg.544]    [Pg.234]    [Pg.312]    [Pg.892]    [Pg.153]    [Pg.318]    [Pg.70]    [Pg.93]    [Pg.481]    [Pg.707]    [Pg.454]    [Pg.80]    [Pg.205]   
See also in sourсe #XX -- [ Pg.347 ]



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