Stereoselectivity intermolecular cycloadditions

The stereoselective intermolecular cycloaddition of azides to chiral cyclopenta-none enamines was reported, but both product yields and enantiomeric excesses (ee) were low (24) (Scheme 9.24). Ethyl azidoformate (115) and A-mesyl azido-formamimidate (116) underwent 1,3-dipolar cycloaddition with the monosubsti-tuted chiral enamine 114 to give products 117 and 118 in low yields with ee of 24 and 18%, respectively. Intermolecular cycloaddition of the A-mesyl azidoforma-mhnidate 116 with the disubstituted C2-symmetric chiral enamine 119 proceeded with good diastereoselectivity to give compound 120 in 18% yield. On cleavage of the enamine unit, compound 120 afforded 118 with low ee. 

Intermolecular Cycloaddition at the C=C Double Bond Addition at the C=C double bond is the main type of 1,3-cycloaddition reactions of nitrile oxides. The topic was treated in detail in Reference 157. Several reviews appeared, which are devoted to problems of regio- and stereoselectivity of cycloaddition reactions of nitrile oxides with alkenes. Two of them deal with both inter- and intramolecular reactions (158, 159). Important information on regio-and stereochemistry of intermolecular 1,3-dipolar cycloaddition of nitrile oxides to alkenes was summarized in Reference 160. 

Photocycloadditions with Cumulated Double Bonds. Wiesner discovered that the regioselectivity in intermolecular cycloadditions of allene to Q, 3-unsaturated ketones 8.50 gave the cyclobutane 8.51 with the central carbon of the allene bonded to the a position. The addition also took place with high stereoselectivity for attack on the lower face of the double bond in 8.50, surprisingly, because the lower face is the more hindered. The approach... 

Tetrahydrophthalic anhydride and the corresponding imide were found to be efficient partners in intermolecular [2 -I- 2] photochemical cycloaddition reactions with alkenols (e.g., e ,s-bulcn-2-cne-l,4-diol) and alkynols (Scheme 2.20). The corresponding cyclobutane adducts have been synthesized in high yields with levels of stereoselection (as high as 10 1) almost unprecedented in classical intermolecular cycloadditions. ... 

Stereoselectivity of l S-Dipolar Cydoaddition. The stereoselectivity of the intermolecular cycloaddition of an acyclic nitrone to an alkene is difficult to predict, and wotdd appear to be susceptible to minor structural changes in either component (13). The chiral 2,2-dimethyl-l,3-dioxolan-4-yl nitrone showed only modest astereoface selectivity in its addition to methyl crotonate (14). However, the more hindered tetramethyl-l,3-dioxolan-4-yl nitrone was more selective. 

Metal-assisted cycloaddition in formation of heterocycles 97CRV523. Stereoselective intermolecular [2- -2]-photocycloaddition reactions of unsaturated heterocycles with formation of fused systems 98S683. 

Substituted 1,2,3,4-tetrahydroquinolines (e.g., 61) are formed with high regio- and stereoselectivity in high yield by intermolecular [A+2] cycloadditions of cationic 2-aza-butadienes and various dienophiles <95CC2137,96SL34>. 

A regio- and stereospecific INOC reaction of unsymmetrical silaketals 114, synthesized in one pot from unsaturated alcohols, nitro ethanol, and dichloro-silanes, via the nitrile oxide 115 to isoxazolines 116 has been described (Scheme 14) [37a]. The intermolecular version of the cycloaddition, under similar conditions, proceeds with poor regio and stereoselectivity. 

So far, only those domino Knoevenagel/hetero-Diels-Alder reactions have been discussed where the cycloaddition takes place at an intramolecular mode however, the reaction can also be performed as a three-component transformation by applying an intermolecular Diels-Alder reaction. In this process again as the first step a Knoevenagel reaction of an aldehyde or a ketone with a 1,3-dicarbonyl compound occurs. However, the second step is now an intermolecular hetero-Diels-Alder reaction of the formed 1 -oxa-1,3 -butadiene with a dienophile in the reaction mixture. The scope of this type of reaction, and especially the possibility of obtaining highly diversified molecules, is even higher than in the case of the two-component transformation. The stereoselectivity of the cycloaddition step is found to be less pronounced, however. 

Diastereoselective intermolecular nitrile oxide—olefin cycloaddition has been used in an enantioselective synthesis of the C(7)-C(24) segment 433 of the 24-membered natural lactone, macrolactin A 434 (471, 472). Two (carbonyl)iron moieties are instrumental for the stereoselective preparation of the C(8)-C(ii) E,Z-diene and the C(i5) and C(24) sp3 stereocenters. Also it is important to note that the (carbonyl)iron complexation serves to protect the C(8)-C(ii) and C(i6)-C(i9) diene groups during the reductive hydrolysis of an isoxazoline ring. 

In intramolecular [3+ 2]-cycloaddition reactions, silyl nitronates also lead to substantially higher stereoselectivity than intermolecular reactions (see, e.g., Scheme 3.178) (193). 

In a related paper, Scheldt and co-workers described a stereoselective formal [3 + 3] cycloaddition catalyzed by imidazolinylidine catalyst 256 Eq. 25 [130]. Ultimately this is an intermolecular addition of the homoenolate intermediate to an azomethine ylide followed by intramolecular acylation and presumably follows the same mechanistic path as described previously. Pyridazinones are obtained as single diastereomers in good to high yield from a number of aldehydes. Unfortunately no reaction occurs with the presence of electron-withdrawing groups on the aryl ring of the enal. 

Bicyclopropylidene (1) does not undergo an intermolecular Diels-Alder reaction with furan and 2-methoxyfuran even under high pressure. Intramolecular cycloadditions of compounds 160 with a furan tethered to bicyclopropylidene, however, were easily brought about under high pressure (10 kbar) and gave cycloadducts 161 stereoselectively in yields ranging from 32 to 95% (Scheme 35) [58]. 

Note that Pearson has extended the classical anionic [3 + 2] cycloadditions to allow the generation of nonstabilized 2-azaallyl anions, and has successfully applied this methodology to the held of alkaloid total synthesis. A key discovery was that (2-azaallyl)stannanes are capable of undergoing tin-lithium exchange to generate the nonstabilized anions (63-76), which can be trapped either intramole-cularly or intermolecularly with unactivated alkenes to produce pyrrolidines, often in a stereoselective fashion. Thus, a variety of 2-azaallyl anions are accessible by his method. A few examples of Pearson s contributions are illustrated in Scheme 11.3 (70,76). 

---