Ring closure substitution

When 7V-allyl-(2-chloro-phenyl)-amine 23 (Z = NH) is allowed to react with Me3Sn ions in liquid ammonia, a low yield of product 24 (Z = NH) is obtained (Sch. 24). When the amino group is protected as 23 (Z = TV-allyl, Wacetyl derivatives), good yields of ring closure—substitution products 24 (Z = Wallyl, TV-acetyl) are obtained [98]. 

In the photostimulated reaction of SCH2C02Et ions with 2-bromo-3-cyano or 3-bromo-4-cyano pyridines, the substitution product formed is deprotonated, and the anion formed reacts with the cyano group to give ultimately the ring closure substitution products 304 (90%) and 305 (98%), respectively. The yields are high, because in these cases fragmentation of the radical-anion intermediates does not take place288. 

The novelty of this work involves the versatile application of 5-exo ring closure processes during the propagation cycle of the SRN1 reaction the alkyl radical intermediates formed then reacted with the nucleophiles to afford the ring closure-substituted heterocycles. The factors governing the observed product distribution are discussed and one of the examples is illustrated below <02JOC8500>. 

SUBSTITUTED BUTADIENES. The consequences of p-type orbitals rotations, become apparent when substituents are added. Many structural isomers of butadiene can be foiined (Structures VIII-XI), and the electrocylic ring-closure reaction to form cyclobutene can be phase inverting or preserving if the motion is conrotatory or disrotatory, respectively. The four cyclobutene structures XII-XV of cyclobutene may be formed by cyclization. Table I shows the different possibilities for the cyclization of the four isomers VIII-XI. These structmes are shown in Figure 35. 

Thus, to name just a few examples, a nucleophilic aliphatic substitution such as the reaction of the bromide 3.5 with sodium iodide (Figure 3-21a) can lead to a range of stereochemical products, from a l l mbrture of 3.6 and 3.7 (racemization) to only 3.7 (inversion) depending on the groups a, b, and c that are bonded to the central carbon atom. The ring closure of the 1,3-butadiene, 3.8, to cyclobutene... 

A very mild and efficient synthesis of N-substituted -lactams uses the Mitsunobu reaction (see section 2.6.2) for the ring closure of seryl dipeptides protected at the terminal N as 4,5-diphenyloxazol-2(3f/)-one ( Ox ) derivatives (see section 2,6.3)... 

A-4-Thiazoline-2-ones and ring substituted derivatives are usually prepared by the general ring-closure methods described in Chapter II. Some special methods where the thiazole ring is already formed have been used, however. An original synthesis of 4- 2-carboxyphenyl)-A-4-thiazoline-2-one (18) starting from 2-thiocyanato-2-halophenyl-l-3-indandione (19) has been proposed (Scheme 8) (20, 21). Reaction of bicyclic quaternary salts (20) may provide 3-substituted A-4-thiazoline-2-one derivatives (21) (Scheme 9) (22). Sykes et al. (23) report the formation of A-4-thiazoline-2-ones (24) by treatment ef 2-bromo (22) or 2-dimethylaminothiazole (23) quaternary salts with base (Scheme 10). 

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. 

An excess of phosgene is used during the initial reaction of amine and phosgene to retard the formation of substituted ureas. Ureas are undesirable because they serve as a source for secondary product formation which adversely affects isocyanate stabiUty and performance. By-products, such as biurets (23) and triurets (24), are formed via the reaction of the labile hydrogens of the urea with excess isocyanate. Isocyanurates (25, R = phenyl, toluyl) may subsequendy be formed from the urea oligomers via ring closure. 

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. 

Epoxide formation from chlorohydrins is marked by an increase in rate with alkyl substitution (28) as shown in Figure 1. This phenomenon has been explained on the basis that steric crowding ia the chlorohydrin is somewhat reheved as the epoxide is formed, so that the greatest rehef of strain results from ring closure of the most crowded chlorohydrin (28). 

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). 

A novel type of ring closure is the reaction of 6-amino-5-dichloroacetylaminopyrimidines (285) with sulfur and morpholine under the conditions of a Kindler reaction (B-64MI21605). 7-Morpholinopteridin-6-ones (287) are formed, either via thiooxamide derivatives (286) or via corresponding 7,8-dihydropteridines (284 equation 102). Chloral hydrate also reacts with 2-substituted 5,6-diaminopyrimidin-4-ones to form pteridin-6-ones (56JCS3311, 64JCS565) by a so far unknown mechanism. 

Other C—C fused systems are also available by utilization of 1,4-dicarbonyl-type systems. The substituted pyrimidinethione (59) on treatment with polyphosphoric acid readily formed the thiazolo[5,4-d]pyrimidine system (60) without any of the alternative ring closure product (65JOC1916). 

The direction of ring closure can often be influenced by the nature of the dehydrogenation agent. The substituted thiosemicarbazone (223) with AI2O3 in chloroform formed the... 

Substitution of the nitrogen atom in (289) and subsequent ring closure of (293) under acid cyclodehydration conditions gave the mesoionic system anhydro-5-hydroxythiazoIium hydroxide (294). These reactions are analogous to the cyclodehydration of the A-nitrosogly-cines (295) with acetic anhydride to give the sydnones (296) (see Chapter 4.21). 

Although some of the oxidative ring closures described above, e.g. reactions with lead tetraacetate (Section 4.03.4.1.2), may actually involve radical intermediates, little use has been made of this reaction type in the synthesis of five-membered rings with two or more heteroatoms. Radical intermediates involved in photochemical transformations are described in Section 4.03.9. Free radical substitutions are described in the various monograph chapters. 

Gross rate comparisons indicate that these ring closures proceed considerably faster than analogous substitution reactions not leading to three-membered rings (64AG(E)333). 

Ring closure of more highly substituted cyclohexadienes also follows the Woodward-Hoffmarm rules and, indeed, provided the initial examples of the dichotomy between thermal and photochemical processes that led to development of the concepts underlying the Woodward-Hofimann rules. ... 

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