Formation intramolecular selectivity

The selectivity, functional group tolerance, and mild reaction conditions of the various Pd° cross-coupling reactions have made them invaluable tools for carbon-carbon bond formation. Intramolecular variations to construct macrocycles have also been described. 

The scope aromatic C-N bond formation extends beyond simple amine substrates. For example, selected imines, sulfoximines, hydrazines, lactams, azoles, and carbamates give useful products from intermolecular aromatic C-N bond formation. Intramolecular formation of aryl amides has been reported. In addition, allylamine undergoes arylation, providing a readily cleaved amine alternative to the ammonia surrogates benzylamine, t-butylcarbamate, or benzophenone imine. Although it is an amine substrate, the reaction of this reagent is included here because of its special purpose. 

The present evidence on these points comes from published work (8)of Moodie, Schofield and their group at the University of Exeter. They have studied the nitration of pseudocumene and have shown that there is about a 9 1 selectivity of attack on positions 5 and 6 provided that one makes the reasonable assumption that any ipso-attack is not followed by rearrangement under the chosen conditions. Both positions are reactive enough to achieve the limiting rate and have similar steric requirements. This deduction rules out the explanation in terms of early transition states of the positionally oriented type and also precludes the possibility of detectable positionally oriented intermediates prior to the Wheland intermediates. It means that there must be a common intermediate prior to Wheland intermediate formation, but the extent of intramolecular selectivity is certainly not sufficient to make it necessary to postulate any attractive interaction in this intermediate. 

Various bicyclic and polycyclic compounds are produced by intramolecular reactions] 127]. In the syntheses of the decalin systems 157 [38] and 158 [128], cis ring Junctions are selectively generated. In the formation of 158, allyhc silyl ether remains intact. A bridged bicyclo[3.3. l]nonane ring 159 was constructed... 

As an extension of this reaction the intramolecular cycloaddition of 5-propynyloxycycloalkanepyrimidines was studied. It was found that bi-and tricyclic annelated pyridine derivatives are formed by expulsion of either X-CH2-CN and/or HCN, respectively. A marked selectivity in the product formation was observed, depending on the size of the cycloalkane ring. With cyclohexapyrimidines a mixture of A and B is formed, while with the cycloheptapyrimidine derivative exclusive formation of the tricyclic compound B takes place (92T1643, 92T1657) (Scheme 39a). 

Formation of diamines from dinitro compounds, which are unable to interact intramolecularly, presents no problem. Very large volumes of diaminotoluene, a precursor to toluene diisocyanate, are produced by hydrogenation of dinitrotoluene over either nickel or palladium-on-carbon. Selective hydrogenation of one or the other of two nitro groups is much more of a challenge, but a number of outstanding successes have been recorded. A case in point is the hydrogenation of 2,4-dinitroaniline (11) to 4-nitro-l,2-benzenediamine (12) (2) or to 2-nitro-l,4-benzenediamine (10). 

The most useful of the insertion processes is the intramolecular reactions that occur with high selectivity for the formation of five-membered ring products. The electrophilic nature of the process is suggested by C-H bond reactivity in competitive experiments (3°>20 >1°) [76, 77]. Asymmetric catalysis with Rh2(MPPIM)4 has been used to prepare a wide variety of lignans that include (-)-enterolactone (3) [8], as well as (R)-(-)-baclofen (2) [7],2-deoxyxylolactone (31) [80,81],and (S)-(+)-imperanane (32) [82].Enantioselectivities are 91-96%... 

In summary, all the experiments expressly selected to check the theoretical description provided fairly clear evidence in favour of both the basic electronic model proposed for the BMPC photoisomerization (involving a TICT-like state) and the essential characteristics of the intramolecular S and S, potential surfaces as derived from CS INDO Cl calculations. Now, combining the results of the present investigation with those of previous studies [24,25] we are in a position to fix the following points about the mechanism and dynamics of BMPC excited-state relaxation l)photoexcitation (So-Si)of the stable (trans) form results in the formation of the 3-4 cis planar isomer, as well as recovery of the trans one, through a perpendicular CT-like S] minimum of intramolecular origin, 2) a small intramolecular barrier (1.-1.2 kcal mol ) is interposed between the secondary trans and the absolute perp minima, 3) the thermal back 3-4 cis trans isomerization requires travelling over a substantial intramolecular barrier (=18 kcal moM) at the perp conformation, 4) solvent polarity effects come into play primarily around the perp conformation, due to localization of the... 

Metal-catalyzed hydrophosphination has been explored with only a few metals and with a limited array of substrates. Although these reactions usually proceed more quickly and with improved selectivity than their uncatalyzed counterparts, their potential for organic synthesis has not yet been exploited fully because of some drawbacks to the known reactions. The selectivity of Pt-catalyzed reactions is not sufficiently high in many cases, and only activated substrates can be used. Lanthanide-catalyzed reactions have been reported only for intramolecular cases and also sulfer from the formation of by-products. Recent studies of the mechanisms of these reactions may lead to improved selectivity and rate profiles. Further work on asymmetric hydrophosphination can be expected, since it is unlikely that good stereocontrol can be obtained in radical or acid/base-catalyzed processes. 

There is some increase in selectivity with functionally substituted carbenes, but it is still not high enough to prevent formation of mixtures. Phenylchlorocarbene gives a relative reactivity ratio of 2.1 1 0.09 in insertion reactions with i-propylbenzene, ethylbenzene, and toluene.212 For cycloalkanes, tertiary positions are about 15 times more reactive than secondary positions toward phenylchlorocarbene.213 Carbethoxycarbene inserts at tertiary C—H bonds about three times as fast as at primary C—H bonds in simple alkanes.214 Owing to low selectivity, intermolecular insertion reactions are seldom useful in syntheses. Intramolecular insertion reactions are of considerably more value. Intramolecular insertion reactions usually occur at the C—H bond that is closest to the carbene and good yields can frequently be achieved. Intramolecular insertion reactions can provide routes to highly strained structures that would be difficult to obtain in other ways. 

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