Diene systems, cyclization

When butadiene is treated with PdCU the l-chloromethyl-7r-allylpalladium complex 336 (X = Cl) is formed by the chloropalladation. In the presence of nucleophiles, the substituted 7r-methallylpalladium complex 336 (X = nucleophile) is formed(296-299]. In this way, the nucleophile can be introduced at the terminal carbon of conjugated diene systems. For example, a methoxy group is introduced at the terminal carbon of 3,7-dimethyl-I,3,6-octatriene to give 337 as expected, whereas myrcene (338) is converted into the tr-allyl complex 339 after the cyclization[288]. 

In the synthesis of morphine, bis-cyclization of the octahydroisoqtiinolinc precursor 171 by the intramolecular Heck reaction proceeds using palladium trifluoroacetate and 1,2,2,6,6-pentamethylpiperidine (PMP). The insertion of the diene system forms the rr-allylpalladium intermediate 172, which attacks the phenol intramolecularly to form the benzofuran ring (see Section 1.1.1.3). Based on this method, elegant total syntheses of (-)- and (+ )-dihydrocodei-none and (-)- and ( + )-morphine (173) have been achieved[141]. 

The intramolecular coupling of organostannanes is applied to macrolide synthesis. In the zearalenone synthesis, no cyclization was observed between arylstannane and alkenyl iodide. However, intramolecular coupling take.s place between the alkenylstannane and aryl iodide in 706. A similar cyclization is possible by the reaction of the alkenylstannane 707 with enol triflate[579]. The coupling was applied to the preparation of the bicyclic 1,3-diene system 708[580]. 

Depending on the substituents of l,6-enynes, their cyclization leads to 1.2-dialkylidene derivatives (or a 1.3-diene system). For example, cyclization of the 1,6-enyne 50 affords the 1.3-diene system 51[33-35]. Furthermore, the 1.6-enyne 53, which has a terminal alkene, undergoes cyclization with a shift of vinylic hydrogen to generate the 1,3-diene system 54. The carbapenem skeleton 56 has been synthesized based on the cyclization of the functionalized 1,6-enyne 55[36], Similarly, the cyclization of the 1,7-enyne 57 gives a si -mem-bered ring 58 with the 1,3-diene system. 

Myrcene with its conjugated diene system readily undergoes Diels-Alder reactions with a number of dienophiles. For example, reaction with 3-meth.5i-3-pentene-2-one with a catalytic amount of AlCl gives an intermediate monocyclic ketone, which when cyclized with 85% phosphoric acid produces the bicycHc ketone known as Iso E Super [54464-57-2] (49). The product is useful in providing sandalwood-like and cedarwood-like fragrance ingredients (91). 

Cyclizations of doubly unsaturated diazo compounds containing a thiophene ring within rather than at the end of the diene system to yield thicnodiazepines have also been reported. Thus, thermolysis of the sodium salt 7 gives the l//-thieno[3,2-r/]-2,3-diazepine 9. The intermediate 8 rearranges to the more stable product 9 by a symmetry allowed [1,5] shift of hydrogen.14,1... 

To explain the formation of non-crosslinked polymers from the diallyl quaternary ammonium system, Butler and Angelo proposed a chain growth mechanism which involved a series of intra- and inter-molecular propagation steps (15). This type of polymerization was subsequently shown to occur in a wide variety of symmetrical diene systems which cyclize to form five or six-membered ring structures. This mode of propagation of a non-conjugated diene with subsequent ring formation was later called cyclopolymerization. 

The chemical consequences of these MO changes is to activate the antiaromatic diene system for reaction. This activation is especially evident in Diels-Alder cyclizations, either with itself (Eq. 32) or with a variety of olefins and acetylenes.93... 

The use of 1,6-diene systems usually does not result in cyclization reactions with palladium ) salts. For example, with 1,6-heptadiene a /i-elimination takes place from the cqjr-intermediate to give diene 22 as the major product (equation 10)27. However, more recently Trost and Burgess21 have shown that with a 4,4-bis(phenylsulfonyl) derivative of 1,6-heptadiene (23) an insertion takes place to give a 5-membered ring product (24, equation 11). The final step of the latter reaction is oxidative cleavage of the palladium-carbon bond by CuCl2 to produce a carbon-chlorine bond. 

The use of organomagnesium reagents as terminal reductants in zirconocene-catalyzed diene reductive cyclization permits derivatization of the resulting bis(magnesiomethyl)cycloalkanes. However, the use of other stoichiometric reductants is likely to afford catalytic systems that exhibit complementary selectivity profiles. Molander reports the... 

With the aid of a Knoevenagel condensation and a Staudinger reaction, 2-azidocyclopent-l-ene 1-carbaldehydes (195) can be converted into suitable products for a cyclopenta[b]pyridine synthesis [89JCS(P1)1369], as shown in Scheme 72. In order to bring the ester carbonyl function and the imino-phosphorane group into close proximity suitable for cyclization reactions, the 1,3-diene system 196 should possess the s-cis conformation. Furthermore, the exocyclic double bond should show a cis conformation. To achieve... 

The 1,3-diene system formed by cyclization is useful for further modifications, typically Diels-Alder reactions. The 1,3-diene 51 reacts with maleimide to give 52[35], Similarly, the 1,3-diene 59 undergoes a Diels-Alder reaction, and this sequence was used for the syntheses of sterepolide (60)[37] and mer-ulidial[38]. 

Diene systems of the type 158 have been studied by O Shea and Sharp [96JCS(Pl)515].The oxiranes 157 were subjected to flash vacuum pyrolysis at 625°C, to yield some new hetero-fused dihydrobenzoxepines 159. This 1,7-electrocyclization of carbonyl ylides 158, irrespective of whether the heterocyclic ring under attack is electron rich or electron poor, parallels the cyclization of the analogous nitrile ylides (Scheme 48). 

The effect of electrons in the unsaturation in the ultimate and penultimate monomer groups on the ionicity of the catalysts has been shown by Wilke (133). His work shows that, when the catalyst contains triphenylphosphine, the added increasing nucleophilic effect of the double bonds converts the catalyst to an ethylene incorporating specie. After incorporation of the ethylene, cyclization and reduction of the metal occurs to produce cyclodecadiene and cydohexene. This effect is analogous to that shown earlier (88) of a diene system complexing with the catalyst modifying the ionicity to favor ethylene incorporation. 

Confalone and Ko have reported formation of the macrocyclic INOC product (104) in 30% yield from cyclization of an aryl-bridged nitrotriene containing a 17-atom intervening bridge.48 Cyclization to the conjugated diene system did not occur, presumably because of geometric constraints and the fact that the more accessible double bond is trisubstituted. Isoxazoline (104) is a potential maytansine precursor. 

As mentioned in Scheme 7.3, although thermal ene reaction of the 1,6-enyne 320 gives only 1,4-dienes 324, the 1,3-diene 325 is formed by the Pd-catalysed reaction. No thermal ene reaction is possible with 342, but the smooth Pd-catalysed cyclization affords the 1,3-diene system 343, which has a skeleton analogous to 325 in Scheme 7.3. Notably, the reaction proceeds with migration of vinylic hydrogen. The 1,3-diene system formed by the cyclization is useful for further modification, typically Diels-Alder reaction. The 1,3-diene 343 formed from 342 is converted to sterepolide (344) by Diels-Alder reaction [140]... 

Additions to l,3-dienes6 (12, 367-368 14, 249-250 15, 245). This reaction can be used to effect intramolecular cyclization of cyclic 1,3-dienes substituted by a suitable nitrogen nucleophile. Thus reaction of the amido diene 1 with lithium acetate catalyzed by Pd(OAc)2 (with benzoquinone as reoxidant) provides the ds-fused heterocycle cis-2, in which the acetoxy group is cis to the ring fusion, formed by an overall trans-1,4-oxyamidation of the diene system. Addition of a trace of LiCl improves the yield and results in an overall cis- 1,4-oxyamidation (equation I). Acetamides and carbamates can also be used in place of amides. 1,4-Chloroamidation can also be effected by use of 2 equiv. of LiCl. 

In order to explain the stereospecificity of the thermally induced cyclization of preisocalamendiol (315) to give dehydroisocalamendiol (316), Terada and Yamamura have carried out molecular mechanics calculations on the ground-state conformers and probable transition states of (315). The computed values of the steric energies of the possible transition states are in good agreement with the observed experimental facts. Other studies related to the conformational aspects of germacrane sesquiterpenoids include an examination of the NOE effects in the isofuranodiene (317), which shows the 1,5-diene system to be in a crossed... 

Hydrolysis of 2-alkoxy-3,4-dihydro-l,2-pytans with dilute hydrochloric acid furnishes a convenient synthesis of glutaraldehyde (R = H) and other l,5 dicarbonyl compounds. The starting materials are obtained by the 1,4-addition of vinyl ethers to a,/3-unsaturated carbonyl compounds. The wide selection of diene systems includes acrolein, crotonaldehyde, meth-acrolein, cinnamaldehyde, /3-furylacrolein, methyl vinyl ketone, benzal-acetone, and benzalacetophenone. Ethyl vinyl ether is preferred as the dienophile. The yields in the cyclization step are in the range of 25 87% and in the subsequent hydrolysis Step, 55 85%. ... 

Both disubstituted alkynes (Chapter 3.3, this volume) and isolated terminal double bonds may be reduced by alkali metals in NH3, but isolated double bonds are usually stable to these conditions. However, 16,17-secopregnanes (10 equation 8) afford mixtures of cyclization products (11) and (12) in 61% to 80% yield with Na naphthalenide-THF, Na-NHs-THF, Na-THF or Li-NHs-THF. With Na-NHa-THF-r-butyl alcohol, a 91% yield of a 72 28 mixture of (11) (12) (R = Me) is obtained. This type of radical cyclization of alkenes and alkynes under dissolving metal reduction conditions to form cyclopentanols in the absence of added proton donors is a general reaction, and in other cases it competes with reduction of the carbonyl group. Under the conditions of these reactions which involve brief reaction times, neither competitive reduction of a terminal double bond nor an alkyne was observed. However, al-lenic aldehydes and ketones (13) with Li-NHs-r-butyl alcohol afford no reduction products in which the diene system survives. ... 

The regioselectivity in diene addition reactions can also be influenced by ring strain effects in cyclization reactions. The regioselectivity is highly predictable in those cases, in which addition to the preferred diene center forms the preferred ring size. Thus, the cyclization of radical 15 proceeds readily to form the ct s-disubstituted cyclopentyhnethyl radical 16 with high selectivity. Similarly, cyclization of 17 affords exclusively bicyclic radical 18, in which the additional cyclopentane ring has been formed by addition to the terminal position of the butadiene subunit. This preference for 5-exo cyclizations onto dienes is not even dismpted by substiments at the C1 or C4 positions of the diene system, as seen for radical 19, which cyclizes to 20 (equation lO). This is in contrast to alkyl radical cyclizations to alkenes, in which major amounts of 6-endo cyclization is observed for 5-substituted systems. ... 

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