Synthesis cycloaddition

Asymmetric synthesis has achieved a position as one of the most important areas of modem organic chemistry. Dnring the past 20 years the number of publications in this area has been vast. On the pallet of organic reactions that are used in asymmetric synthesis, cycloadditions possess a prominent position, since they are some of the most efficient methods for creating new chiral centers with control of stereochemistry (1-4). The ability to introduce more than one new chiral center in a single step with control of both relative and absolute stereochemistry makes cycloaddition reactions highly attractive key reactions for stereoselective synthesis. 

Two approaches, based on furan, have found wide application in carbohydrate synthesis. Cycloaddition reactions of furan with 2-substituted acrylonitrile or acrolein lead to oxabicycloheptanes which, in tnm, can be transformed to monosaccharides. On the other hand, furfuryl alcohols can be converted—either by the Clauson-Kaas reaction or by mild oxidation—into 5,6-dihydro-4-pyrones, suitable for easy functionalization to sugars. 

Hetero-Diels-Alder reactions have been extensively used in organic synthesis. Cycloadditions of imines 184 with maleimide 185 (Scheme 34) generated pyrazo-lopyridines 186 [71]. These compounds were further elaborated as shown in Scheme 34 to provide pyrazolopyridopyridazines 187 which were potent and selective PDE5 inhibitors [72]. Compound 188 was selected for further evaluation. This compound had superior selectivity towards other PDE isoenzymes and was found to be efficacious in an anesthetized rabbit model of erectile function. 

Synthesis. - Cycloadditions. The azadiene (26) behaves as a dienophile with cyclopentadiene but as a diene with acyclic 1,3-dienes and with cyclohexa-... 

Synthesis. - Cycloadditions. A bis-heteroannelation approach to ( )-ligularone (90) from (89) has been reported. Other intramolecular cycloadditions include the conversions of (91) into (92) and the intramolecular addition to the benzyne (93), which is the key to the synthesis of ( )-mansonone (94). ... 

Synthesis - Cycloadditions - Diels-Alder addition of ethynyl p-tolylsulphone... 

Synthesis - Cycloadditions - Novel intramolecular oxidopyrylium ylide cycloadditions have been reported (e.g. (86) (87)88 and (88) (89) 8. ... 

Addition of an unsymmetrical diene to an unsymmetrical dienophile can take place in two ways to give two structurally isomeric products. It is found in practice, however, that formation of one of the regioisomers is strongly favoured and that this can be predicted prior to reaction. Obviously, this is crucial if the Diels-Alder reaction is to be used successfully in synthesis. Cycloaddition of 1 -substituted butadienes with dienophiles such as a,p-unsaturated carbonyl compounds gives rise to... 

Kametani et al have achieved a very neat synthesis of euxylophoricine A (20) by application of their retro-mass-spectral synthesis. Cycloaddition of 3,4-dihydro-j8-carboline with the iminoketen (21b), prepared in situ by decomposition of the sulphinamide anhydride (21a), gave euxylophoricine A (20) directly. Euxylophoricine C (22) was prepared by an exactly analogous route (Scheme 4). 

Conjugated dienes are the object of continuous attention in organic chemistry. These compounds are encountered in numerous natural products and find applications in many fundamental methodologies in synthesis (cycloaddition, metathesis, ene-reaction, oxidoreduction, or reductive aldolization for instance) (Eig. 1). In addition. 

Koldobskii, A.B. (2011) Trifluoroacetyl- andethoxyoxalylhaloacetylenes synthesis, cycloaddition reactions, and the methods of functionalization of the cycloadducts. Doctorate dissertation, Moscow. 

ACIEE 1984, 23,876 ACJEE 1977, 16, 10 Organic Reactions 1984, 32, 1 W. Carruthers Cycloadditions Reactions in Organic Synthesis (Pergamon Press, Oxford) 1990... 

Within the cubane synthesis the initially produced cyclobutadiene moiety (see p. 329) is only stable as an iron(O) complex (M. Avram, 1964 G.F. Emerson, 1965 M.P. Cava, 1967). When this complex is destroyed by oxidation with cerium(lV) in the presence of a dienophilic quinone derivative, the cycloaddition takes place immediately. Irradiation leads to a further cyclobutane ring closure. The cubane synthesis also exemplifies another general approach to cyclobutane derivatives. This starts with cyclopentanone or cyclohexane-dione derivatives which are brominated and treated with strong base. A Favorskii rearrangement then leads to ring contraction (J.C. Barborak, 1966). 

A few typical examples indicate the large variety of five-membered heterocycles, which can be synthesized efficiently by [2 + 3]-cycloadditions. [2 + 2]-Cycloadditions are useful in the synthesis of certain four-membered heterocycles (H. Ulrich, 1967), e.g. of 8-lactams (J.R. 

The two-bond disconnection (re/ro-cycloaddition) approach also often works very well if the target molecule contains three-, four-, or five-membered rings (see section 1.13 and 2.5). The following tricyclic aziridine can be transformed by one step into a monocyclic amine (W. Nagata, 1968). In synthesis one would have to convert the amine into a nitrene, which-would add spontcaneously to a C—C double bond in the vicinity. 

Thermal and photochemical electrocyclic reactions are particularly useful in the synthesis of alkaloids (W. Oppolzer, 1973,1978 B K. Wiesner, 1968). A high degree of regio- and stereoselectivity can be reached, if cyclic olefin or enamine components are used in ene reactions or photochemical [2 + 2]cycloadditions. 

A key intermediate, 163, which possesses all but one chiral center of (+ )-brefeldin, has been prepared by the enantiocontrolled cycloaddition of the chiral fi,/3-unsaturated ester 162 to 154[107], Synthesis of phyllocladane skeleton 165 has been carried out by the Pd-catalyzed cycloaddition of the unsaturated diester 164 and cobalt-catalyzed cycloaddition of alkynes as key reactions[108]. Intramolecular cycloaddition to the vinylsulfone in 166 proceeds smoothly to give a mixture of the trans and cis isomers in a ratio of 2.4 1[109], Diastereocontrolled cycloaddition of the hindered vinylsulfone 167 affords a single stereoisomeric adduct, 168, which is used for the synthesis of the spirocarbocyclic ring of ginkgolide[l 10],... 

Chapters 9, 10 and 11 describe methods for substitution directly on the ring with successive attention to Nl, C2 and C3. Chapters 12 and 13 are devoted to substituent modification as C3. Chapter 12 is a general discussion of these methods, while Chapter 13 covers the important special cases of the synthesis of 2-aminoethyl (tryptaminc) and 2-aminopropanoic acid (tryptophan) side-chains. Chapter 14 deals with methods for effecting carbo cyclic substitution. Chapter 15 describes synthetically important oxidation and reduction reactions which are characteristic of indoles. Chapter 16 illustrates methods for elaboration of indoles via cycloaddition reactions. 

This category corresponds to the construction of the carbocyclic ring by 2 + 4 cycloaddition with pyrrole-2,3-quinodimethane intermediates. Such reactions can be particularly useful in the synthesis of 5,6-disubstituted indoles. Although there are a few cases where a pyrrolequinodimethane intermediate is generated, the most useful procedures involve more stable surrogates. Both 1,5-di-hydropyrano[3,4-b]pyrrol-5(lf/)-ones[l] and l,6-dihyropyrano[4,3-b]pyrrol-6-(in)-ones[2] can serve as pyrrole-2,3-quinodimethane equivalents. The adducts undergo elimination of CO2. 

This reaction is called the Smmons-Smith reaction and is one of the few methods avail able for the synthesis of cyclopropanes Mechanistically the Simmons-Smith reaction seems to proceed by a single step cycloaddition of a methylene (CH2) unit from lodomethylzmc iodide to the alkene... 

Cyclo ddltion. Ketenes are ideal components ia [2 + 2] cycloadditions for additions to the opposite sides of a TT-system as shown ia the cyclobutane product (2) ia Figure 1. Electron-rich double bonds react readily with ketenes, even at room temperature and without catalysts. In conjugated systems, ketenes add ia a [2 + 2] fashion. This is illustrated ia the reaction foUowiag, where the preferential orientation of L (large substituent) and S (small substituent) is seen (40). This reaction has been used ia the synthesis of tropolone [533-75-5]. 

The synthesis of natural products containing the quinonoid stmcture has led to intensive and extensive study of the classic diene synthesis (77). The Diels-Alder cycloaddition of quinonoid dienophiles has been reported for a wide range of dienes (78—80). Reaction of (2) with cyclopentadiene yields (79) [1200-89-1] and (80) [5439-22-5]. The analogous 1,3-cyclohexadiene adducts have been the subject of C-nmr and x-ray studies, which indicate the endo—anti—endo stereostmcture (81). 

The current paradigm for B syntheses came from the first report in 1957 of a synthesis of pyridines by cycloaddition reactions of oxazoles (36) (Fig. 5). This was adapted for production of pyridoxine shordy thereafter. Intensive research by Ajinomoto, BASF, Daiichi, Merck, Roche, Takeda, and other companies has resulted in numerous pubHcations and patents describing variations. These routes are convergent, shorter, and of reasonably high throughput. 

Although not of industrial importance, many organometallic approaches have been developed (38). A one-pot synthesis of vitamin has been described and is based on the anionic [4 + 2] cycloaddition of three-substituted isoben2ofuranones to l-phytyl-l-(phenylsulfonyl)propene. Owing to the rather mild chemical conditions, the (H)-stereochemistry is retained (39). 

Other approaches to (36) make use of (37, R = CH ) and reaction with a tributylstannyl allene (60) or 3-siloxypentadiene (61). A chemicoen2ymatic synthesis for both thienamycia (2) and 1 -methyl analogues starts from the chiral monoester (38), derived by enzymatic hydrolysis of the dimethyl ester, and proceeding by way of the P-lactam (39, R = H or CH ) (62,63). (3)-Methyl-3-hydroxy-2-methylpropanoate [80657-57-4] (40), C H qO, has also been used as starting material for (36) (64), whereas 1,3-dipolar cycloaddition of a chiral nitrone with a crotonate ester affords the oxa2ohdine (41) which again can be converted to a suitable P-lactam precursor (65). 

The only recorded synthesis of this type from a pyridazine involves the [4 + 2] cycloaddition of the lactim ether (374) with l,2,4,5-tetrazine-3,6-dicarboxylic ester, which proceeds with loss of nitrogen and methanol from the intermediate adduct to give the pyrido[2,3-t/]pyridazine (375) (77AP936). 

---