Sulfonylation selective

Pivalates. The selective pivaloylation of sucrose with pivaloyl (2,2-dimethylpropionyl) chloride has been thoroughly investigated (56). The reactivity of sucrose toward pivaloylation was shown to be significantly different from other sulfonic or carboxyflc acid chlorides. For example, reaction of sucrose with four molar equivalent of toluene-/)-sulfonyl chloride in pyridine revealed, based on product isolation, the reactivity order ofO-6 0-6 > 0-1 > 0-2 (57). In contrast, a reactivity order for the pivaloylation reaction, under similar reaction conditions, was observed to be 0-6 0-6 > 0-1 > 0-4. 

Since the ring nitrogen at 3 is now comparable in reactivity to the amine at 4, acylation with one equivalent of 88 gives a mixture of products. The desired product, sulfaisodimidine (109), can be obtained by acylation with an excess of the sulfonyl chloride (140) followed by alkaline hydrolysis. The rate of saponification of the sulfonamide group attached to the ring nitrogen is sufficiently greater to cause it to be lost selectively. 

Saito has recently reported high yields and enantioselectivities in aziridine synthesis through reactions between aryl- or vinyl-substituted N-sulfonyl imines and aryl bromides in the presence of base and mediated by a chiral sulfide 122 (Scheme 1.41) [66]. Aryl substituents with electron-withdrawing and -donating groups gave modest transxis selectivities (around 3 1) with high enantioselectiv-... 

Table 6 gives a selection of reactions of sulfonyl halides with different unsaturated systems. 

Although the yields of the above reactions are high and the procedure is simple186, there are some apparent disadvantages the selection of the sulfene substituents R1 and R2 is limited, depending on the availability of the sulfonyl chloride precursors the cycloaddition leads to a mixture of cis- and trans-substituted thietane dioxides the cycloaddition reaction is reversible202 and several further transformations are necessary if a dioxide without 3-lV-substituent is required. 

This subject has been associated with the development of the or and type scales almost from the start74 (see Section II.B), but the first paper in which sulfinyl and sulfonyl groups played a part appears to have been one by Taft and coworkers in 196367. The main object of this paper was to study the effect of solvent on the inductive order by 19F NMR measurements on a large number of mcta-substituted fluorobenzenes in a great variety of solvents. The relationship between the NMR shielding parameter and selected systems as equation 10 ... 

The ESR spectra of a large variety of sulfonyl radicals have been obtained photolytically in liquid phase over a wide range of temperature. Some selected data are summarized in Table 2. The magnitudes of hyperfine splittings and the observations of line broadening resulting from restricted rotation about the C—S bond have been used successfully in conjunction with INDO SCF MO calculations to elucidate both structure and conformational properties. Thus the spin distribution in these species is typical of (T-radicals with a pyramidal center at sulfur and in accord with the solid-state ESR data. 

TABLE 2. ESR spectra of a selected number of sulfonyl radicals at temperatures between 170 and 200 K... 

Sulfonic peracids (66) have also been applied recently to the preparation of acid sensitive oxiranes and for the epoxidation of allylic and homoallylic alcohols, as well as relatively unreactive a, p - unsaturated ketones. These reagents, prepared in situ from the corresponding sulfonyl imidazolides 65, promote the same sense of diastereoselectivity as the conventional peracids, but often to a higher degree. In particular, the epoxidation of certain A -3-ketosteroids (e.g., 67) with sulfonic peracids 66 resulted in the formation of oxirane products (e.g., 68) in remarkably high diastereomeric excess. This increased selectivity is most likely the result of the considerable steric requirements about the sulfur atom, which enhances non-bonded interactions believed to be operative in the diastereoselection mechanism <96TET2957>. 

Besides short ELPS, longer ELPs have also been conjugated to synthetic polymers. In one approach, Cu(I)-catalyzed azide-alkyne cycloaddition click chemistry was applied. For this purpose, ELPs were functionalized with azides or alkynes via incorporation of azidohomoalanine and homopropargyl glycine, respectively, using residue-specific replacement of methionine in ELP via bacterial expression [133]. More recently, an alternative way to site-selectively introduce azides into ELPs was developed. Here, an aqueous diazotransfer reaction was performed directly onto ELP[V5L2G3-90] using imidazole-1-sulfonyl azide [134]. 

Electronic effects of the sulfinyl and sulfonyl groups TABLE 1. Selected values of a, a, and ct" constants... 

The reactants can be prepared by chelation-controlled addition of organometallic reagents to a-(l-ethoxyethoxy)methyl ketones. Selective sulfonylation occurs at the... 

The readily available enantiopure acyclic hydroxy 2-sulfinyl butadiene 585 undergoes a highly face-selective Diels-Alder cycloaddition with PTAD to generate the densely functionalized cycloadduct 586 (Equation 84). The complete reversal of facial selectivity is observed when sulfonyl derivative 587 is treated with PTAD under identical conditions (Equation 85). These results demonstrate that the sulfinyl functionality is not just synthetically useful but also an extremely powerful element of stereocontrol for intermolecular Diels-Alder cycloadditions. On the other hand, the corresponding ( , )-hydroxy-2-sulfinyldienes treated with PTAD affords the cycloadducts in high yield but with moderate 7i-facial selectivity <1998CC409, 2005CEJ5136>. 

Representatives of the bridged sulfone system 70 have been subjected to ruthenium catalysed ring-closing metathesis reactions (Grubbs catalyst) and shown to afford, in low yields, a few selected cyclic dimers and trimers, of all the possibilities available. The diastereoselectivities observed were rationalised in terms of kinetic control involved with internal ruthenium/sulfonyl oxygen coordination . 

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