A-Tosylations

The reaction of the vinylcyclopropanedicarboxylate 301 with amines affords an allylic amine via the 7r-allylpalladium complex 302[50]. Similarly, three-membered ring A -tosyl-2-(l,3-butadienyl)aziridine (303) and the four-mem-bered ring azetidine 304 can be rearranged to the five- and six-membered ring unsaturated cyclic amines[183]. 

An advantage that sulfonate esters have over alkyl halides is that their prepara tion from alcohols does not involve any of the bonds to carbon The alcohol oxygen becomes the oxygen that connects the alkyl group to the sulfonyl group Thus the configuration of a sulfonate ester is exactly the same as that of the alcohol from which It was prepared If we wish to study the stereochemistry of nucleophilic substitution m an optically active substrate for example we know that a tosylate ester will have the same configuration and the same optical purity as the alcohol from which it was prepared... 

Electrolysis, Me4N Cl , 5°, 65-98% yield. " Acylation of a tosylated amine with BOC or benzoyl reduces the potential required for electrolytic cleavage so that these aryltosyl groups can be selectively removed in the presence of a simple tosylamide. °... 

Another interesting question concerns the rate at which each tosylate undergoes elimination. A tosylate sample contains molecules with several different conformations. The size of each conformer population depends on conformer energy, and the more reactive tosylate will probably be the one with the largest population of reactive conformers, i.e., molecules whose geometries allow anti elimination. Which tosylate, cis or trans, will have a larger population of reactive conformers Explain how you reached this conclusion. 

Mesylates and tosylates may be used as variants of the 0-sulfate ester. For instance, 55% of aziridine 7 was obtained from base-mediated cyclization of amino mesylate 6. In comparison, the classic Wenker protocol only gave 3% of 7. In another instance, A-tosyl amino alcohol 8 was tosylated to give 9, which was transformed to aziridine 10 in 64% yield, along with 29% of the P-elimination product due to the presence of the ester moiety. Likewise, aziridine 12 was assembled from tosylate 11 in two steps and 60% yield. ... 

Azaloxan (12) is an antidepressant agent. Its synthesis can be accomplished starting with the reaction of catechol (7) and 3,4-dibromobutyronitrile (obtained by addition of bromine to the olefin) to give l,4-benzodioxan-2-ylacetonitrile (8). A series of functional group transformations ensues [hydrolysis to the acid (9), reduction to the alcohol (10) and conversion to a tosylate (11)] culminating in an SN-2 displacement reaction on tosylate 11 with l-(4-piperidinyl)-2-imidazolidi-none to give azaloxan (12) [3]. 

Although this particular series of reactions involves nucleophilic substitution of an alkyl p-toluenesulfonate (called a tosylate) rather than an alkyl halide, exactly the same type of reaction is involved as that studied by Walden. For all practical purposes, the entire tosylate group acts as if it were simply a halogen substituent. In fact, when you see a tosylate substituent in a molecule, do a mental substitution and tell yourself that you re dealing with an alkyl halide. 

Alternatively, an alcohol can be made more reactive toward nucleophilic substitution by treating it with p ra-toluenesulfonyl chloride to form a tosylate. As noted on several previous occasions, tosylates are even more reactive than halides in nucleophilic substitutions. Note that tosylate formation does not change the configuration of the oxygen-bearing carbon because the C-0 bond is not broken. 

One of the most important reasons for using tosylates in S j2 reactions is stereochemical. The S]s]2 reaction of an alcohol via an alkyl halide proceeds with hvo inversions of configuration—one to make the halide from the alcohol and one to substitute the halide—and yields a product with the same stereochemistry as the starting alcohol. The SN2 reaction of an alcohol via a tosylate, however, proceeds with only one inversion and yields a product of opposite stereochemistry to the starting alcohol. Figure 17.5 shows a series of reactions on the R enantiomer of 2-octanol that illustrates these stereochemical relationships. 

The earliest method developed for the preparation of nonracemic aziridine-2-car-boxylates was the cyclization of naturally occurring (3-hydroxy-a-amino acid derivatives (serine or threonine) [4]. The (3-hydroxy group is normally activated as a tosyl or mesyl group, which is ideal for an intramolecular SN2 displacement. The cyclization has been developed in both one-pot and stepwise fashion [4—9]. As an example, serine ester 3 (Scheme 3.2) was treated with tosyl chloride in the presence of triethylamine to afford aziridine-2-carboxylate 4 in 71% yield [9]. Cyclization of a-hydroxy- 3-amino esters to aziridine-2-carboxylates under similar conditions has also been described [10]. 

It should be noted that the sense of asymmetric induction in the lithiation/ rearrangement of aziridines 274, 276, and 279 by treatment with s-butyllithium/ (-)-sparteine is opposite to that observed for the corresponding epoxides (i.e. removal of the proton occurs at the (S)-stereocenter) [102], If one accepts the proposed model to explain the selective abstraction of the proton at the (R) -stereo-center of an epoxide (Figure 5.1), then, from the large difference in steric bulk (and Lewis basicity) between an oxygen atom and a tosyl-protected nitrogen atom, it is obvious that this model cannot be applied to the analogous aziridines. 

The ruthenium(II) aqua ion reacts with nitrogen at room temperature under high pressure (200 bar) forming yellow-brown [Ru(H20)5N2]2+, isolated as a tosylate salt, showing i/(N=N) at 2141cm-1 in its IR spectrum [59]. 

Oxo-3,4-dihydro-2-quinoxalinecarbohydrazide (122) gave 3-acetoxy-A -acetyl-2-quinoxalinecarbohydrazide (121) (neat AC2O, 95°C, 2 h 84%)" " or 3-oxo-A -tosyl-3,4-dihydro-2-quinoxalinecarbohydrazide (123) (TsCl, pyridine, reflux, 2 h %). ... 

Eschenmoser and co-workers have provided strong evidence that the transition state in an Sn2 reaction must be linear. Base treatment of methyl a-tosyl-o-toluenesulfonate (4) gives the o-(l-tosylethyl)benzenesulfonate ion (6). The role of... 

Aziridines have been opened by organometallic reagents to give amines. Although less reactive than epoxides, it is also possible to open aziridines with organometallic reagents. Isopropylmagnesium chloride reacts with A-tosyl 2-... 

An alternative preparation of aziridines reacts an alkene with iodine and chloramine-T (see p. 1056) generating the corresponding A-tosyl aziridine. Bromamine-T (TsNBr Na ) has been used in a similar manner." Diazoalkanes react with imines to give aziridines." Another useful reagent is NsN=IPh, which reacts with alkenes in the presence of rhodium compounds or Cu(OTf)2 to give N—Ns aziridines. Manganese salen catalysts have also been used with this reagent. ... 

Ring-opening reactions with 3-alkylaziridine esters 36 take a similar course. The reactions are in practically all cases regio- and stereospecific with attack at C-3. An important difference is that the aziridine ring needs to be activated by an electron-withdrawing substituent, such as a tosyl or a benzyloxycarbonyl group. In addition, for benzenethiol, indole, and DMF, catalysis with BF3 was necessary (Scheme 22) [31]. 

It was found, furthermore, that the substituent on the sulfonamide group of the chiral hgand strongly influenced the enantiofacial selectivity. Hence, ligand 81 bearing a tosyl substituent delivered the endo-(2il)-cycloadduct, whereas a trifluoromethanesulfonamide group afforded its enantiomer. The authors proposed that the latter substituent should increase the Lewis acid-... 

After we have converted the OH into a tosylate, then we can do our technique (using a strong, sterically hindered base to eliminate, followed by anti-Markovnikov addition of H and OH) ... 

A third way to perform a substitution reaction is to convert the OH group into a tosylate, and then do an Sn2 reaction ... 

Scheme 26 Synthesis of 2-aikyl-4-halo-1 -tosyl-1,2,5,6-tetrahydropyridines from A-tosyl homopropargyl amine and aldehydes using FeX3 as promotor...

On the other hand, one of the first chiral sulfur-containing ligands employed in the asymmetric transfer hydrogenation of ketones was introduced by Noyori el al Thus, the use of A-tosyl-l,2-diphenylethylenediamine (TsDPEN) in combination with ruthenium for the reduction of various aromatic ketones in the presence of i-PrOH as the hydrogen donor, allowed the corresponding alcohols to be obtained in both excellent yields and enantioselectivities, as... 

Scheme 10.7 1,3-Dipolar cycloadditions of nitrones with 1,1-diethoxypropene catalysed by oxazaborolidines derived A-tosyl-L-a-amino acids.

Sulfonate esters also can be prepared under Mitsunobu conditions. Use of zinc tosylate in place of the carboxylic acid gives a tosylate of inverted configuration. 

It has been known that aromatic heterocycles such as furan, thiophene, and pyrrole undergo Diels-Alder reactions despite their aromaticity and hence expected inertness. Furans have been especially used efficiently as dienes due to their electron-rich properties. Thiophenes and pyrroles are less reactive as dienes than furans. But pyrroles with A-elecIron-withdrawing substituents are efficient dienes. There exists a limited number of examples of five-membered, aromatic heterocycles acting as dienophiles in Diels-Alder reactions. Some nitro heteroaromatics serve as dienophiles in the Diels-Alder reactions. Heating a mixture of l-(phenylsulfonyl)-3-nitropyrrole and isoprene at 175 °C followed by oxidation results in the formation of indoles (see Eq. 8.22).35a A-Tosyl-3-nitroindole undergoes high-yielding Diels-Alder reactions with... 

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