Domino enantioselective

The subsequent epoxidation of these in situ formed allylic tertiary alcohols yielded the corresponding syn-e oxy alcohols with high levels of diastereo- and enantioselectivity, thus providing a novel one-pot asymmetric synthesis of acyclic chiral epoxyalcohols via a domino vinylation epoxidation reaction (Scheme 4.17). ... 

For clarification, individual transformations of independent functionalities in one molecule - also forming several bonds under the same reaction conditions -are not classified as domino reactions. The enantioselective total synthesis of (-)-chlorothricolide 0-4, as performed by Roush and coworkers [8], is a good example of tandem and domino processes (Scheme 0.1). I n the reaction of the acyclic substrate 0-1 in the presence of the chiral dienophile 0-2, intra- and intermolecular Diels-Alder reactions take place to give 0-3 as the main product. Unfortunately, the two reaction sites are independent from each other and the transformation cannot therefore be classified as a domino process. Nonetheless, it is a beautiful tandem reaction that allows the establishment of seven asymmetric centers in a single operation. 

Scheme 0.7. Enantioselective Pd-catalyzed domino reaction for the synthesis of Vitamin E (0-24).

One of the first enantioselective transition metal-catalyzed domino reactions in natural product synthesis leading to vitamin E (0-23) was developed by Tietze and coworkers (Scheme 0.7) [18]. This transformation is based on a Pdn-catalyzed addition of a phenolic hydroxyl group to a C-C-double bond in 0-20 in the presence of the chiral ligand 0-24, followed by an intermolecular addition of the formed Pd-spe-cies to another double bond. 

Scheme 1.44. Enantioselective synthesis of (-)-gilbertine (1-190) by a cationic domino cyclization.

The selectivity of the aldol addition can be rationalized in terms of a Zimmer -man-Traxler transition-state model with TS-2-50 having the lowest energy and leading to dr-values of >95 5 for 2-51 and 2-52 [18]. The chiral copper complex, responsible for the enantioselective 1,4-addition of the dialkyl zinc derivative in the first anionic transformation, seems to have no influence on the aldol addition. To facilitate the ee-determination of the domino Michael/aldol products and to show that 2-51 and 2-52 are l -epimers, the mixture of the two compounds was oxidized to the corresponding diketones 2-53. 

Scheme 2.22. Enantioselective domino Michael/aldol process.

Krische and coworkers [44] developed a Rh-catalyzed asymmetric domino Michael/aldol reaction for the synthesis of substituted cyclopentanols and cyclohex-anols. In this process, three contiguous stereogenic centers, including a quaternary center, are formed with excellent diastereo- and enantioselectivity. Thus, using an enantiopure Rh-BINAP catalyst system and phenyl boronic acid, substrates 2-108 are converted into the correspondding cyclized products 2-109 in 69-88% yield and with 94 and 95% ee, respectively (Scheme 2.24). 

For the enantioselective synthesis of chiral chromanes such as 2-213, a chiral Lewis acid complex, formed in situ from Mg(OTf)2 and 2-212, is assumed to catalyze the domino transformation of the phenols 2-210 and the p,y-unsalurated a-ke-toesters 2-211 (Scheme 2.50). 2-213 was obtained in excellent diastereoselectivity, but only in mediocre enantioselectivity. 

In a recently published report by MacMillan s group [121] on the enantioselective synthesis of pyrroloindoline and furanoindoline natural products such as (-)-flustramine B 2-219 [122], enantiopure amines 2-215 were used as organocatalysts to promote a domino Michael addition/cyclization sequence (Scheme 2.51). As substrates, the substituted tryptamine 2-214 and a, 3-unsaturated aldehydes were used. Reaction of 2-214 and acrolein in the presence of 2-215 probably leads to the intermediate 2-216, which cyclizes to give the pyrroloindole moiety 2-217 with subsequent hydrolysis of the enamine moiety and reconstitution of the imidazolid-inone catalyst. After reduction of the aldehyde functionality in 2-217 with NaBH4 the flustramine precursor 2-218 was isolated in very good 90 % ee and 78 % yield. 

Yamamoto s group recently published a highly enantioselective chiral amine-catalyzed domino O-nitroso aldol/Michael reaction of 2-268 and 2-269 (Scheme 2.63) [141]. As products, the formal Diels-Alder adducts 2-271 were obtained with >98% 66, which is probably due to the selective attack of an enamine, temporarily formed from amine 2-270 and enone 2-268, onto the nitroso functionality. 

The domino process can be catalyzed by a Cu-complex with (S.S)-tBu-bis(oxazo-line) to give 2-616 with excellent enantioselectivity (97-98% ee) [320b,c]. The use of 5 A molecular sieves turned out to be obligatory. Wada and coworkers also reported on a related transetherification/l,3-dipolar cycloaddition procedure to give access to trans-fused bicyclic y-lactones [321]. 

Scheme 3.20. Mn(OAc)3-mediated chiral auxiliary-assisted enantioselective domino radical cyclization in the total synthesis of (+)-triptocallol (3-79).

Scheme 3.33. Lewis acid-promoted free radical domino cyclization reaction and enantioselective approach.

The first example of an intermolecular radical addihon/intermolecular trapping domino reactions of an acyclic system in a stereocontrolled fashion to build stereo-genic centers at the a- and 3-carbons was described by Sibi and coworkers [59]. Enantioselective addition of in-sitw-prepared alkyl radical to crotonate or cinnamate,... 

Scheme 3.36. Enantioselective intermolecular domino radical addition procedure.

Several Pd-catalyzed domino processes start with a Tsuji-Trost reaction, a pal-ladation of alkynes or allenes [5], a carbonylation [6], an amination [7] or a Pd(II)-cat-alyzed Wacker-type reaction [8]. A novel illustrious example of this procedure is the efficient enantioselective synthesis of vitamin E [9]. 

Scheme 6/1.23. Enantioselective domino Heck/allylation process.

Martin and coworkers [93] described a highly efficient enantioselective total synthesis ofmanzamine A (6/1-177) with a concise domino Stille/Diels-Alder reaction to construct the tricyclic ABC ring core in 6/1-177 as the key step. Reaction of 6/1-178 with vinyl tributylstannane in the presence of (Ph3P)4Pd afforded the triene... 

Recently, it has been shown by Hodgson and coworkers [195] that this domino reaction can indeed be performed in an enantioselective manner. Thus, treatment of 6/2-31 using the BINOL-phosphate Rh2-complex 6/2-34 at -15 °C gave (+)-6/2-33, probably via 6/2-32, in 66% yield and 90% ee (Scheme 6/2.6). Several other substrates and chiral catalysts have also been employed, though with lower selectivity. 

Scheme 6/2.6. Enantioselective domino carbene-formation/1,3-dipolar cycloaddition.

Another example of this useful domino process is the enantioselective synthesis of the quinozilidine alkaloid (-)-lasubine II [234]. Condensed tricyclic compounds as 6/3-28 can also be prepared from norbomene derivatives 6/3-27 in excellent yield, as shown by Funel and coworkers (Scheme 6/3.6) [235]. 

Finally, Katsuki and coworkers [271] described an enantioselective Ru-catalyzed domino reaction, which includes a sulfamidation of an aryl allyl sulfide 6/3-111 using the chiral Ru(salen)-complex 6/3-115, followed by a 2,3-sigmatropic rearrangement of the formed 6/3-112 to give N-allyl-N-arylthiotoluenesulfonamides 6/3-113. On hydrolysis, 6/3-113 yielded N-allyltoluenesulfonamides 6/3-114 (Scheme 6/3.33). The enantioselectivity ranged from 78 to 83% ee. 

Scheme 6/4.29. Enantioselective domino ring-opening/ring-closing metathesis with a Mo-catalyst.

A combination of an enzymatic kinetic resolution and an intramolecular Diels-Alder has recently been described by Kita and coworkers [23]. In the first step of this domino process, the racemic alcohols ( )-8-55 are esterified in the presence of a Candida antarctica lipase (CALB) by using the functionalized alkenyl ester 8-56 to give (R)-8-57, which in the subsequent Diels-Alder reaction led to 8-58 in high enantioselectivity of 95 and 91 % ee, respectively and 81 % yield (Scheme 8.15). In-... 

This chapter aims to provide an overview of the current state of the art in homogeneous catalytic hydrogenation of C=0 and C=N bonds. Diastereoselec-tive or enantioselective processes are discussed elsewhere. The chapter is divided into sections detailing the hydrogenation of aldehydes, the hydrogenation of ketones, domino-hydroformylation-reduction, reductive amination, domino hydroformylation-reductive amination, and ester, acid and anhydride hydrogenation. 

Keyword Carbocycles a Cascade Reactions a Cycloadditions a Combinatorial Chemistry a Domino Reactions a Enantioselective Transformations a Ene Reactions a Eieterocydes a Natural products a Preservation of Resources and Environment a Sigmatropic Rearrangements a Tandem Reactions a Transition Metal-Catalyzed Transformations... 

Certain examples are known for asymmetric induction in domino reactions using either chiral substrates or educts with removable chiral auxiliaries. In contrast, only a few enantioselective domino reactions have been developed so far. The first example was described by us using a titanium complex of glucose diacetonide with 88% ee.[101 Quite... 

A novd example of a catalytic enantioselective domino process1201 is the inter-intramolecular nitro-aldol reaction described by Shibasaki et al which generates substituted indanones. As catalyst a praseodym-heterobimetallic complex with binaph-thol as chiral ligand is employed. Treatment of keto-aldehyde 41 with nitromethane in the presence of the catalyst 46 at -40 °C and successive warming to room temperature affords diredly the produd 42 in an overall yield of 41 % and 96 % ee after several recrystallizations (scheme 9). As intermediates the nitromethane adduct 43 and the hemiacetal 44 can be proposed. In a second aldol reaction 44 leads to 45 which isomerizes to the thermodynamically more stable epimer 42. 

Scheme 9. Enantioselective domino reaction for the formation of hydrindanones with heterobimetallic catalysts...

A domino-cyclopropanation/Cope rearrangement was used by Davies et al. for the enantioselective... 

A further enantioselective synthesis of (+)-T-4 (125), T-6 (128), T-7 (129) and T-8 (126) has been reported by Stragies and Blechert [198]. Key steps are a Pd-catalyzed domino allylation and a Ru-catalyzed metathesis ring rearrangement. Their strategy represents a general approach towards all naturally occurring tetraponerines and will be illustrated here by the description of the syntheses of (+)-T-4 (125) and (+)-T-8 (126) (Scheme 9). 

In extending this concept to transformations that formally deliver Diels-Alder products, a one-pot three-component Mannich/Michael reaction pathway was developed in which simple cyclic enones, formaldehyde, and aryl amines were treated with catalytic amounts of proline (2) to provide regio-, diastereo-, and enantioselective bicyclic compounds in high yields (Scheme ll.lOb). Multicomponent domino... 

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