Ring closure compounds

The reaction of 2-iodobenzoic acids derivatives (288) with tetralone enolate ions (284) gives the products 291 which, after acid treatment, afford the ring closure compounds 292 (60-75% yield) (equation 179)328. 

Our first approach to 1 is based on a retrosynthetic analysis depicted in Fig (8). The crucial step to construct the cw-fused bicyclic ring skeleton of 1 is the intramolecular allylic amination of a cw-allylic carbonate 25. The paUadium-catalyzed allylation takes place with retention of the configuration [76] and requires the c/s-isomer 25 for the ring closure. Compound 25 may be derived from keto acid 24 through a sequence of reactions including esterification, O-methoxycarbonylation, removal of the Boc and benzylidene groups, dehydrative cyclization, reductive alkylation and ureido formation. The last five transformations are to be conducted in a successive manner, i.e., without isolation of the intermediates. The 4-carboxybutyl chain of 1 may be installed by the reaction of O-trimethylsilyl (TMS) cyanohydrin 23 with a di-Grignard... 

The aldehyde group in 137 was reduced with NaBH, and the resulting primary hydroxy group in 139 was selectively mesylated to produce 140. Hydrogenolysis of the carbamate 140 provided the ring-closure compound... 

The thiazolyl-2-thioglycollic acid (119) undergoes intramolecular ring closure to give mesoionic compound 120 under treatment with acetic anhydride and triethylamine (Scheme 60) (192). The parent acid (119) can be recovered from 120 by hydration with hot 50% aqueous sulfuric add. Compound 120 affords monohydrate of bis(-cyclopentenothiazolyi-2-thio)acetone (121) (192). 

The reaction of phosphorus pentasulfide with a-acylamino carbonyl compounds of type Ilia also yields thiazoles. Even more commonly, a mercaptoketone is condensed with a nitrile of type IVa or a-mercaptoacids or their esters with Schiff bases. This ring closure is limited to the thiazolidines. In the Va ring-closure type, /3-mercaptoalkylamines serve as the principal starting materials, and ethylformate is the reactant that supplies the carbon at the 2-position of the ring. These syntheses constitute the most important route for the preparation of many thiazolidines and 2-thiazohnes. In the Vb t3fpe of synthesis, one of the reactant supplies only the carbon at the 5-position of the resultant thiazole. Then in these latter years new modern synthetic methods of thiazole ring have been developed (see Section 7 also Refs. 515, 758, 807, 812, 822). 

With R] different from R2 two isomeric compounds (138 and 139) are possible, depending on the direction of ring closure (86). However, only one form is generally obtained. Finally, the trisubstituted thioureas such as N,N,N -trimethylthiourea react with chloroacetone to give a thiazolium salt, in a reaction identical to that of the N-monosubstituted thioamides (Scheme 67). 

Bis(azol-2-5l)stilbenes (2(i]ll such as (4) have been prepared. 4,4 -Dihydrazinostilbene-2,2 -disulfonic acid, obtained from the diamino compound, on treatment with 2 moles of oximinoacetophenone and subsequent ring closure, leads to the formation of (4) [23743-28 ]. Such compounds are used chiefly as washing powder additives for the brightening of cotton fabrics, and exhibit excellent light- and hypochlorite-stabiUty. 

Bis(benZoxaZol-2-yl) Derivatives. Bis(benzoxazol-2-yl) derivatives (8) (Table 3) aie prepared in most cases by treatment of dicaiboxyhc acid derivatives of the central nucleus, eg, stilbene-4,4Cdicarboxyhc acid, naphthalene-l,4-dicarboxyhc acid, thiophene-2,5-dicarboxyhc acid, etc, with 2 moles of an appropriately substituted o-aminophenol, followed by a ring-closure reaction. These compounds are suitable for the brightening of plastics and synthetic fibers. 

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. 

Condensation ofDianhydrides with Diamines. The preparation of polyetherknides by the reaction of a diamine with a dianhydride has advantages over nitro-displacement polymerization sodium nitrite is not a by-product and thus does not have to be removed from the polymer, and a dipolar aprotic solvent is not required, which makes solvent-free melt polymerization a possibiUty. Aromatic dianhydride monomers (8) can be prepared from A/-substituted rutrophthalimides by a three-step sequence that utilizes the nitro-displacement reaction in the first step, followed by hydrolysis and then ring closure. For the 4-nitro compounds, the procedure is as follows. 

Alkylphenols can be synthesized by several approaches, including alkylation of a phenol, hydroxylation of an alkylbenzene, dehydrogenation of an alkylcyclohexanol, or ring closure of an appropriately substituted acycHc compound. The choice of approach depends on the target alkylphenol, availabihty of the starting materials, and cost of processing. The procedures discussed herein encompass commercial methods, general methods, and a few specific examples of commercial interest. 

Ethyltoluene is manufactured by aluminum chloride-cataly2ed alkylation similar to that used for ethylbenzene production. All three isomers are formed. A typical analysis of the reactor effluent is shown in Table 9. After the unconverted toluene and light by-products are removed, the mixture of ethyltoluene isomers and polyethyltoluenes is fractionated to recover the meta and para isomers (bp 161.3 and 162.0°C, respectively) as the overhead product, which typically contains 0.2% or less ortho isomer (bp 165.1°C). This isomer separation is difficult but essential because (9-ethyltoluene undergoes ring closure to form indan and indene in the subsequent dehydrogenation process. These compounds are even more difficult to remove from vinyltoluene, and their presence in the monomer results in inferior polymers. The o-ethyltoluene and polyethyltoluenes are recovered and recycled to the reactor for isomerization and transalkylation to produce more ethyltoluenes. Fina uses a zeoHte-catalyzed vapor-phase alkylation process to produce ethyltoluenes. 

Chelation itself is sometimes useful in directing the course of synthesis. This is called the template effect (37). The presence of a suitable metal ion facihtates the preparation of the crown ethers, porphyrins, and similar heteroatom macrocycHc compounds. Coordination of the heteroatoms about the metal orients the end groups of the reactants for ring closure. The product is the chelate from which the metal may be removed by a suitable method. In other catalytic effects, reactive centers may be brought into close proximity, charge or bond strain effects may be created, or electron transfers may be made possible. 

The photochemical ring closure of certain stilbenes, eg, the highly methyl substituted compound (2) [108028-39-3], C22H2g, and their heterocycHc analogues is the basis for another class of photochromic compounds (31—33). 

This type of cyclization is important only for the formation of cinnolines. In all cases, the starting compounds have an ortho amino group, which upon diazotization undergoes ring closure with the other functionality, most frequently with a multiple bond. 

Another ring closure, presumably initiated by attack on the heteroatom, is the formation of 1,1,3-triphenylisoindoline from diphenyldichloromethane and benzophenone imine (Scheme 60) the ability of this compound to undergo a thermal 1,5-phenyl shift, thereby forming 1,2,3-triphenylisoindole, makes this an attractive overall synthetic route (64LA(673)96). 

Numerous variations of this reaction have been studied, principally those involving a prior inclusion of the nuclear sulfur atom in a thioacylamino compound. Thus, thiobenz-amido acetaldehyde diethyl acetal (8) underwent ring closure to 2-phenylthiazole (9) on gentle heating (57JCS1556). Similarly, iV-thioacyl a-amino acids also undergo ready ring closure to thiazoles. 

A related ring closure is also successful in the thiazole series. Treatment of a /3-amino-a,/3-unsaturated ketone with thiocyanogen gave the intermediate thiocyano compound (323) which underwent ring closure to the 2-iminothiazoline derivative (324) (83MI40300). Related reactions are described in Chapter 4.19, and for those involving potassium selenocyanate see Chapter 4.20. 

This ring closure is the final step of the reaction of hydrazines with 1,3-difunctional compounds (Section 4.04.3.1.2(ii)), and numerous examples in the literature of pyrazoles have been described. In some cases the N—C ring closure occurs by a concerted mechanism, classified by Huisgen (80AG(E)947) as 1,5-electrocyclizations. 

Anthra[l,9]pyrazol-6(2//)-one (735) dyes have also been described in the literature (B-70MI40403). TTiesc compounds result by acid ring closure of 1-anthraquinonyl hydrazine or its V-sulfonic acid. 

The synthesis of isoxazolecarboxylic acids has been well investigated. They can be prepared either from compounds which already contain an isoxazole nucleus or by isoxazole ring-closure methods using appropriate starting materials containing carboxy or alkoxycar-bonyl groups. 

Methylvinyldiazirine (199) rearranges at room temperature in the course of some days. Formation of the linear isomer is followed by electrocyclic ring closure to give 3-methyl-pyrazole. The linear diazo compound could be trapped by its reaction with acids to form esters, while the starting diazirine (199) is inert towards acids (B-71MI50801). 

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