Chelation control

Noyori "Open" Transition State for non-Chelation Control Aldols... 

Chelation Control Model- "Anti-Cram" selectivity... 

Ketone 13 possesses the requisite structural features for an a-chelation-controlled carbonyl addition reaction.9-11 Treatment of 13 with 3-methyl-3-butenylmagnesium bromide leads, through the intermediacy of a five-membered chelate, to the formation of intermediate 12 together with a small amount of the C-12 epimer. The degree of stereoselectivity (ca. 50 1 in favor of the desired compound 12) exhibited in this substrate-stereocontrolled addition reaction is exceptional. It is instructive to note that sequential treatment of lactone 14 with 3-methyl-3-butenylmagnesium bromide and tert-butyldimethylsilyl chloride, followed by exposure of the resultant ketone to methylmagnesium bromide, produces the C-12 epimer of intermediate 12 with the same 50 1 stereoselectivity. 

Although it may not be obvious, putative intermediate 12 could conceivably be fashioned in one step from lactol 13. Of course, 13 can be regarded as a latent aldehyde that should be amenable to an a-chelation-controlled carbonyl addition reaction21 with ethyl-magnesium bromide. This event could secure the formation of the indicated stereocenter in intermediate 12. It seems reasonable to suppose that the sequential action of aqueous acid and 1,1-... 

The completion of the synthesis of the polyol glycoside subunit 7 requires construction of the fully substituted stereocenter at C-10 and a stereocontrolled dihydroxylation of the C3-C4 geminally-disub-stituted olefin (see Scheme 10). The action of methyllithium on Af-methoxy-Af-methylamide 50) furnishes a methyl ketone which is subsequently converted into intermediate 10 through oxidative removal of the /j-methoxybenzyl protecting group with DDQ. Intermediate 10 is produced in an overall yield of 83 % from 50) , and is a suitable substrate for an a-chelation-controlled carbonyl addition reaction.18 When intermediate 10 is exposed to three equivalents of... 

With an oxygen-bearing stereocenter in proximity to the C-16 ketone carbonyl in 155, the prospects for achieving a diastereose-lective ketone reduction seemed favorable. From the work of Mori and Suzuki, it was known that similarly constituted ketones are amenable to /i-chelation-controlled reductions with lithium alumi-... 

CC-1065 394 CeCl3-7H20 618 chelate effect 680 P-chelation-control 607 f. chelidonine 158... 

Exclusive trims attack of the nucleophile is also observed with 2,3-epoxycyclopentanones 1559. In contrast to 2-alkyl- and 2-methoxy-substituted cyclopentanones, preferential trans attack to 2,3-epoxycyclopenlanones occurs with alkyl, ethenyl, and ethynyl nucleophiles. Thus, there is no assistance by the epoxidic oxygen for cis attack. Due to the geometry of the molecule, chelation-controlled cis attack is not possible39 60. 

The addition of dibutylcupratc to the a-substituted /1-formyl esters 1 preferentially affords, via chelation control, the cw-disubstituted y-lactone 241. These results are in agreement with those found with a-unsubstituted /1-esters39-41 (vide supra), assuming a seven-membered chelate as transition state of the addition reaction. The diastercosclectivity is somewhat lower with esters 1 as the stereogenic center is one carbon atom further removed from the reaction center and therefore the steric influence of the substituent R1 is less pronounced. 

Addition to a-Hydroxy or a-Alkoxy Carbonyl Compounds Chelation-Controlled 1,2-Asymmetric Induction... 

The addition of vinylmagnesium bromide to methyl (S)-3-benzyloxy-4-oxobutanoate (5) in tetrahydrofuran proceeded with a slight preference for the nonchelation-controlled reaction product (40 60)5°. A reversal of the diastereoselectivity (80 20) could be observed when the Grignard reagent, as a solution in tetrahydrofuran, was added to a dichloromethane solution of the aldehyde which had been precomplexed with one equivalent of magnesium bromide. The almost exclusive formation of the chelation-controlled reaction product 6 was achieved when tetrahydrofuran was completely substituted by dichloromethane the presence of tetrahydrofuran interferes with the formation of the chelate complex, which is a prerequisite for high chelation-controlled diastereoselection. 

Addition of alkynes to a-alkoxy aldehydes is most favorably performed with the corresponding zinc reagents (Table 12)46. As with Grignard reagents, the chelation-controlled addition of zinc alkynes proceeds with higher diastereoselectivity when diethyl ether rather than tetrahydrofuran is used as reaction solvent. 

No difference in diastereoselectivity was observed when phenyllithium and phenylmagnesium bromide were added to tetrahydrofurfural (15, R = H) in both cases there was a moderate preference for the chelation-controlled reaction product. The same trend holds for tetrahydro-5,5-dimethylfurfural (15, R = CH3), however, with a lower level of stereoselectivity58. 

The lower diastereoselectivity found with aldehyde 15 (R = CH3) can be explained by the steric influence of the two methyl substituents in close vicinity to the stereogenic center, which probably diminishes the ability of the ether oxygen to coordinate. In contrast, a significant difference in the diastereoselectivity was found in the additions of phenyllithium and phenylmagnesium bromide to isopropylidene glyceraldehyde (17)58 (see also Section 1.3.1.3.6.). Presumably the diastereo-sclcctivity of the phenyllithium addition is determined by the ratio of chelation-controlled to nonchelation-controlled attack of the nucleophile, whereas in the case of phenylmagnesium bromide additional chelation with the / -ether oxygen may occur. Formation of the -chelate 19 stabilizes the Felkin-Anh transition state and therefore increases the proportion of the anZz -diastereomeric addition product. 

A synthetically useful diastereoselectivity (90% dc) was observed with the addition of methyl-magnesium bromide to a-epoxy aldehyde 25 in the presence of titanium(IV) chloride60. After treatment of the crude product with sodium hydride, the yy -epoxy alcohol 26 was obtained in 40% yield. The yyn-product corresponds to a chelation-controlled attack of 25 by the nucleophile. Isolation of compound 28, however, reveals that the addition reaction proceeds via a regioselective ring-opening of the epoxide, which affords the titanium-complexed chloro-hydrin 27. Chelation-controlled attack of 27 by the nucleophile leads to the -syn-diastereomer 28, which is converted to the epoxy alcohol 26 by treatment with sodium hydride. 

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