Ring closure alcohols

Acetoiicetyliition Reactions. The best known and commercially most important reaction of diketene is the aceto acetylation of nucleophiles to give derivatives of acetoacetic acid (Fig. 2) (1,5,6). A wide variety of substances with acidic hydrogens can be acetoacetylated. This includes alcohols, amines, phenols, thiols, carboxyHc acids, amides, ureas, thioureas, urethanes, and sulfonamides. Where more than one functional group is present, ring closure often follows aceto acetylation, giving access to a variety of heterocycHc compounds. These reactions often require catalysts in the form of tertiary amines, acids, and mercury salts. Acetoacetate esters and acetoacetamides are the most important industrial intermediates prepared from diketene. 

Hydroisoquinolines. In addition to the ring-closure reactions previously cited, a variety of reduction methods are available for the synthesis of these important ring systems. Lithium aluminum hydride or sodium in Hquid ammonia convert isoquinoline to 1,2-dihydroisoquinoline (175). Further reduction of this intermediate or reduction of isoquinoline with tin and hydrochloric acid, sodium and alcohol, or catalyticaHy using platinum produces... 

Propargyl alcohol (332) and (328) react readily with isocyanates in the presence of a basic catalyst to give 4-methylene-2-oxazolidinones (334) and 4-methylene-2-imidazolinones (336), respectively (63JOC991). In the absence of sodium methoxide the intermediate methanes (333) and ureas (335) were obtained and on treatment with sodium methoxide underwent ring closure. Moderate to excellent yields were obtained. 

J E G E R Tetrahydrefuran synthesis Free radical ring closure of alcohols with F%> AcO)41<> tetrahydrofurans... 

In terms of cost, the effectiveness of the catalytic cycle in the ring closure makes this process economical in palladium. The first three steps in the reaction sequence -- ring opening of an epoxide by a Grignard reagent, converison of an alcohol to an amine with inversion, and sulfonamide formation from the amine — are all standard synthetic processes. 

Alcoholic potassium hydroxide or sodium hydroxide are normally used to convert the halohydrins to oxiranes. Other bases have also been employed to effect ring closure in the presence of labile functional groups such as a-ketols, e.g., potassium acetate in ethanol, potassium acetate in acetone or potassium carbonate in methanol.However, weaker bases can lead to solvolytic side reactions. Ring closure under neutral conditions employing potassiunT fluoride in dimethyl sulfoxide, dimethylformamide or A-methyl-pyrrolidone has been reported in the patent literature. 

An interesting approach to quinindoline (227) is due to Gabriel and Eschenbach who found that reductive ring closure of a,jS-bis-o-nitrophenylpropionic acid with ferrous sulfate and ammonia or of its nitrile (226) with alcoholic ammonium sulfide in a sealed tube at 100°... 

The behavior of unsaturated azlactones with organometallic reagents has been studied in detail. Arylmagnesium halides and phenyllithium attack 4-arylidene-5-oxazolones at the carbonyl carbon to give ring-opened amido tertiary alcohols (26) and oxazolines (27) (by ring closure), usually as mixtures [Eq. (17)]. The nature of the... 

The hetero ring in 4-(l -hydroxyalkylidene)-5-oxazolones is cleaved by alcoholic HCl to form alkyl a-acylaminoacylacetates, which cyclize to oxazole-4-carboxylates [Eq. (25)]. This rearrangement occurs directly in alkali, and a carbon-14 tracer study has substantiated a mechanism involving ring opening followed by the alternative ring closure. ... 

The cydization to structurally defined, soluble LPPP then takes place in a two-step sequence, consisting of reduction of the keto group followed by ring closure of the secondary alcohol groups of 14 in a Friedcl-Crafts-type alkylation. 

Cyciization processes involve ring-closure of amino alcohols (Scheme 4.3) or equivalents, and as the aziridine precursors are often available as single stereoisomers, the method is an attractive one if the aziridine target is a key synthetic intermediate. 

An example of the efficient formation of an electron-deficient double bond by RCM was disclosed by a Japanese group in a novel total synthesis of the macrosphelides A (209) and B (208) (Scheme 41) [100]. When the PMB-pro-tected compound 204 was examined as a metathesis substrate, the ring closure did not proceed at all in dichloromethane using catalysts A or C. When the reaction was carried out using equimolar amounts of catalyst C in refluxing 1,2-dichloroethane, the cyclized product 205 was obtained in 65% yield after 5 days. On the other hand, the free allylic alcohol 206 reacted smoothly at room temperature leading to the desired macrocycle 207 in improved yield. 

Here the alcoholic hydroxyl is first protonated and then eliminated as water. The allylcarbenium ion (2) is initially stabilized by elimination of the proton at C-14. Then the ether link is opened after protonation of the ring oxygen with the formation of carbenium ion (3), whereby the neighboring C-C bond of the piperidine ring is cleaved with aromatization of the C ring. The carbenium ion (4) formed is stabilized by elimination of a proton and ring closure to apomorphine (5). 

The versatility of the INOC reaction is evident from the synthesis of tetrahy-drofurans fused to an isoxazoline 22a-f (Eq. 3) [181. a-Allyloxyaldoximes 21, formed by the reduction of jS-nitrostyrenes 19 with SnCl2 2H2O in the presence of an unsaturated alcohol 20, are transformed to isoxazolines 22 in high yield on treatment with NaOCl via stereoselective ring closure of a nitrile oxide intermediate (Table 2). 

The 10 OC route was followed for the synthesis of tetrahydrofurans possessing a y-amino alcohol moiety 247 (Eq. 29) 118]. Aldoximes 21a-f (see also Eq. 3 and Table 2), when heated in benzene in a sealed tube at 110 -120 °C for 6 h, underwent smooth intramolecular cycloaddition to the tetrahydrofuranoisoxazo-lidines 246a-f in 70-83% yield (Eq. 29). This ring closure proceeded stereo-specifically to generate three adjacent stereogenic centers. LAH reduction of 246 b resulted in isolation of stereospecifically functionalized tetrahydrofuran derivative 247b in 75% yield. 

An attractive and useful method for the preparation of aziridine-2-carboxylic esters makes use of the readily available amino acids serine and threonine. Essentially, this synthesis involves the ring closure of 1,2-amino alcohols. 

Wan s group showed that the observed photodehydration of hydroxybenzyl alcohols can be extended to several other chromophores as well, giving rise to many new types of quinone methides. For example, he has shown that a variety of biphenyl quinone methides can be photogenerated from the appropriate biaryl hydroxybenzyl alcohols.32,33 Isomeric biaryls 27-29 each have the benzylic moiety on the ring that does not contain the phenol, yet all were found to efficiently give rise to the corresponding quinone methides (30-32) (Eqs. [1.4—1.6]). Quinone methides 31 and 32 were detected via LFP and showed absorption maxima of 570 and 525 nm, respectively (in 100% water, Table 1.2). Quinone methide 30 was too short lived to be detected by LFP, but was implicated by formation of product 33 that would arise from electrocyclic ring closure of 30 (Eq. 1.4). 

Acetal handle 78 synthesized from Merrifield resin and 4-hydroxy-benzaldehyde was applied to the solid-phase synthesis of carbohydrates and 1-oxacephams (Scheme 41) [90]. For the latter, a 1,3-diol was initially anchored to the support to form a cyclic acetal. A ring opening reaction with DIBAL generated a resin-bound alcohol which was converted to the corresponding triflate for A-alkylation with 4-vinyl-oxyazetidin-2-one. A Lewis acid catalyzed ring closure released 1-oxa-cephams from the support. 

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