Cyclization, high dilution

First the protected oligopeptide is coupled with polymer-bound nitrophenol by DCC. N"-Deblocking leads then to simultaneous cycliiation and detachment of the product from the polymer (M. Fridkin, 1965). Recent work indicates that high dilution in liquid-phase cycli-zation is only necessary, if the cyclization reaction is sterically hindered. Working at low temperatures and moderate dilution with moderately activated acid derivatives is the method of choice for the formation of macrocyclic lactams (R.F. Nutt, 1980). 

The intramolecular cyclization can be favored by (i) high dilution techniques, (ii) the action of a template which forces the reacting ends together, and (ill) stepwise condensations. 

Synthesis by high-dilution techniques requires slow admixture of reagents ( 8-24 hrs) or very large volumes of solvents 100 1/mmol). Fast reactions can also be carried out in suitable flow cells (J.L. Dye, 1973). High dilution conditions have been used in the dilactam formation from l,8-diamino-3,6-dioxaoctane and 3,6-dioxaoctanedioyl dichloride in benzene. The amide groups were reduced with lithium aluminum hydride, and a second cyclization with the same dichloride was then carried out. The new bicyclic compound was reduced with diborane. This ligand envelops metal ions completely and is therefore called a cryptand (B. Dietrich, 1969). 

The intramolecular version for synthesizing cyclic and polycyclic compounds offers a powerful synthetic method for naturally occurring macrocyclic and polycyclic compounds, and novel total syntheses of many naturally occurring complex molecules have been achieved by synthetic designs based on this methodology. Cyclization by the coupling of an enone and alkenyl iodide has been applied to the synthesis of a model compound of l6-membered car-bomycin B 162 in 55% yield. A stoichiometric amount of the catalyst was used because the reaction was carried out under high dilution conditions[132]. 

Shortly after their first report of all-oxygen bridged cryptands, Dietrich, Lehn and Sauvage reported incorporation of sulfur in the strands. The experimental methods used were essentially similar to those applied in the syntheses of the parent cryptands. As in previous cases, a diacyl chloride was condensed with a diamine under high dilution conditions. In this case, however, the diamine contained sulfur atoms rather than oxygen. The synthesis of compound 5 was accomplished in two stages as illustrated below in Eq. (8.3). The first cyclization step affords the macrocyclic amine in 55% yield. The macrobicyclic product (5) is formed in 25% yield from the monocyclic diamine and the acid chloride. 

In the latter process Dieckmann cyclization of diester (11) using high dilution conditions failed. However, A-homo-5a-cholestan-3-one (5b) identical to the product of diazomethane ring enlargement of (lb) was obtained in 35 % yield when diester (11) was hydrolyzed to the bis-homo diacid and this converted to the thorium salt and pyrolyzed. 

The Friedel-Crafts cyclization of w-(2-thienyl) substituted longer fatty acids (130, n = 5,8,9) under high dilution conditions has been investigated by Goldfarb et They used boiling ethereal AlClg,... 

Additions of carbon nucleophiles to vinylepoxides are well documented and can be accomplished by several different techniques. Palladium-catalyzed allylic alkylation of these substrates with soft carbon nucleophiles (pKa 10-20) proceeds under neutral conditions and with excellent regioselectivities [103, 104]. The sul-fone 51, for example, was cyclized through the use of catalytic amounts of Pd(PPh3)4 and bis(diphenylphosphino)ethane (dppe) under high-dilution conditions to give macrocycle 52, an intermediate in a total synthesis of the antitumor agent roseophilin, in excellent yield (Scheme 9.26) [115, 116]. 

Trost and coworkers137 have reported the polymer-supported palladium catalyzed cyclization of 1, l-bis(phenylsulfonyl)epoxyalkene 235 which gives cycloalkanes 236 and 237 in a 2 1 ratio (equation 143). This method has proven useful for the synthesis of macrocyclic compounds under neutral conditions without using high dilution technique. Temperature and concentrations are critical. The best results are achieved if a reaction mixture of 0.1-0.5 m is added to a preheated (at 65 °C) suspension of the catalyst. 

When disodium (Z)-l,2-dicyanoethene-l,2-dithiolate and 1,3-dibromopropane are cyclized under high dilution conditions, the desired 14-membered macrocyclic tetrathioether was isolated <96LA1005>. 

Although the unsaturated nitrile oxides 124 can be prepared via the aldoxime route (see Scheme 8), the older procedure suffers from the disadvantage that a tenfold excess of allyl alcohol and two additional steps are required when compared to Scheme 15. Therefore, unsaturated nitro ether 123 that can be prepared by condensation of an aldehyde 120 and a nitro alkane followed by Michael addition of alcohol 122, was a useful precursor to nitrile oxide 124 [381. The nitrile oxide 124 spontaneously cyclized to ether 125. This procedure is particularly suitable for the synthesis of tetrahydrofurans (125a-h) and tetrahydropyrans (125i-k) possessing Ar substituents in 72-95% yield (Table 12). The seven-membered ether 1251 was obtained only in 30% yield on high dilution. The acetylenic nitro ether 126 underwent INOC reaction to provide the isoxazole 127. 

The high-dilution and template methods are frequently used in the synthesis of cyclic compounds with the aim of increasing the yield. The former method is carried out at substrate concentrations lower than 1 mM [18-20]. This reaction condition decreases the contact of the substrate molecules in the solution. The linear intermediate produced prefers the intramolecular cyclization reaction rather than the intermolecular reaction. Therefore, this reaction condition is useful for the intramolecular reaction, method B (Fig. 2). 

The Jacobs-Gould intramolecular cyclization of diethyl N-(6-methyl-2-pyridyl)amino-methylenemalonate to 3-ethoxycarbonyl-7-methyl-l,8-naphthyrid-4-one is another reaction ideally suited to microwave heating, although conductively heated equipment was employed for laboratory-scale experiments [45]. The product is a key intermediate in the synthesis of nalidixic acid, the first of the quinolone antibacterials. The process usually is conducted at temperatures of 200-250 °C and in high dilution, with heat transfer oils such as the eutectic mixture of diphenyl ether and biphenyl. However, it proceeded rapidly, predictably and controllably under solvent-free conditions. 

A small number of macrocycles with an odd-number of Se atoms have been reported. Both [12]aneSe3 and [20]aneSe5 involve stepwise introduction of the Se atoms, with ring closure occurring via a high dilution cyclization of NaSe(CH2)3SeNa with TsO(CH2)3 Se(CH2)3 OTs, n = 1 or 3, respectively (Scheme 3).101... 

Diastereomerically pure diene 89 (R=SiMe2tBu) was assembled in a straightforward manner starting from cycloheptene 90 (Scheme 28). It is not surprising to find that this particular substrate fails to cyclize when reacted with Id under standard high dilution conditions. 

Pyrrolo[l,2- ][l,2]oxazines are a class of compounds with very few references regarding synthesis and reactivity. An interesting preparation has been described by intramolecular cyclization of IV-hydroxy pyrrolidines carrying a methoxyallene substituent at C-2 (242, Scheme 32). These compounds were obtained by addition of a lithiated allene to chiral cyclic nitrones 241. Cyclization occurred spontaneously after some days at relatively high dilution (0.05 M). Compounds 243 (obtained with excellent diastereoselectivity) can be submitted to further elaboration of the double bond or to hydrogenolysis of the N-O bond to form chiral pyrrolidine derivatives (Section 11.11.6.1) <2003EJ01153>. 

Azetidones (p-lactams) are generally obtained in high yield from (3-halopropion-amides (Table 5.18) and the low yield from the reaction of N-phenyl (3-chloropropi-onamide can be reconciled with the isolation of A-phenyl acrylamide in 58% yield [34]. The unwanted elimination reaction can be obviated by conducting the cyclization in a soliddiquid system under high dilution [35, 36]. Azetidones are also formed by a predominant intramolecular cyclization of intermolecular dimerization to yield piperazine-2,5-diones, or intramolecular alkylation to yield aziridones. Aone-pot formation of azetidones in 45-58% yield from the amine and P-bromocarboxylic acid chloride has also been reported [38]. 

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