Alcohol tosylates formation

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. 

General Discussion. The tosylation of alcohols is one of the most prevalent reactions in organic chemistry. Optimized conditions for this reaction include the use of a 1 1.5 2 ratio of alcohol/tosyl chloride/pytidine in chloroform (eq 1). This procedure avoids formation of unwanted pytidinium salts inherent to... 

Recall that the goal was to arrive at aminoketone 56. The projected Mannich reaction requires that the amino group be on the concave face surface of the m-decalin ring system. Notice that the alcohol stereochemistry in 67 is set such that an 8 2 reaction at the carbinol center would establish the required stereochemistry in 56 [We will see another approach to establishing this stereochemistry shortly]. Tosylate formation followed by acetal hydrolysis provided 68, but treatment of this material with azide failed to give any of the desired 8 2 product. Treatment of 68 with methylamine, however, gave 56 in excellent yield. Given the results with azide, it is probable that this displacement occurs with intramolecular delivery the nucleophile via involvement of an N,W-acetal (69). The final Mannich reaction proceeded as anticipated to provide luciduline (55). 

The mono- and dianions of [ C2]acetylene, readily accessible by deprotonation with n-BuLi (1 equivalent) and MeLi (2.5 equivalents), respectively, can be trapped with monomeric formaldehyde to give [2,3- C2]propargyl alcohol in 40% yield and 2-[2,3- C2]butyne-l,4-diol in 72% yield. Both compounds may serve as valuable intermediates for the preparation of additional low-molecular weight building blocks and intermediates. [2,3- C2]propargyl alcohol, for example, can be reduced with aqueous CrCl2 to [2,3- C2]allyl alcohol, which was shown to be activated through tosylate formation toward nucleophilic displacement of the hydroxy function to produce radio-... 

Tosylate Formation with Inversion of Configuration. Alkyl tosylates can be formed directly from secondary alcohol functionality with retention of carbon stereochemistry by treatment withp-Toluenesulfonyl Chloride and Pyridine. However, conversion of an alcohol to the corresponding tosylate of opposite stereochemistry typically requires a minimum of three steps. For example, inversion of the stereocenter with benzoic acid under Mitsunobu reaction conditions, hydrolysis of the resulting ester, and finally conventional tosylation of the alcohol, provides an attractive route for this transformation. A similar route, the inversion of a secondary alcohol directly with p-TsOH, Diethyl Azodicarboxylate (DEAD), and Triphenylphosphine, does not produce the desired tosylate product. ... 

The desired transformation can be achieved via reduction of the carboxylic acid, followed by substitution. Direct conversion of the resultant alcohol may be accomplished using PBr3, or one can utilize a two-step method involving 1) tosylate formation using TsCl and pyridine followed by, 2) Sn2 displacement using sodium bromide in DMSO ... 

This group is prepared by the reaction of the anion of 9-hydroxyanthracene and the tosylate of an alcohol. Since the formation of this group requires an S 2 displacement on the alcohol to be protected, it is best suited for primaiy alcohols. It is cleaved by a novel singlet oxygen reaction followed by reduction of the endo-peroxide with hydrogen and Raney nickel. 

Dimethyl sulfoxide (DMSO) has been used to effect the elimination of sulfonates at elevated temperatures (see, for example, ref. 237). Benzene-sulfonates are recommended. The elimination of a variety of sulfonates proceeds readily in this medium in the presence of potassium /-butoxide. A -Compounds have been formed at 100°, but heating is not necessary. The effects of temperature change, orientation of the hydroxy group and changes in the sulfonate employed have been examined. The principal side reaction appears to be formation of the original alcohol (uninverted), particularly with equatorial mesylates at low temperatures it is minimized with axial tosylates. 

In contrast to phosphorus esters, sulfur esters are usually cleaved at the carbon-oxygen bond with carbon-fluorine bond formation Cleavage of esteri nf methanesulfonic acid, p-toluenesidfonic acid, and especially trifluoromethane-sulfonic acid (tnflic acid) by fluoride ion is the most widely used method for the conversion of hydroxy compounds to fluoro derivatives Potassium fluoride, triethylamine trihydrofluoride, and tetrabutylammonium fluoride are common sources of the fluoride ion For the cleavage of a variety of alkyl mesylates and tosylates with potassium fluoride, polyethylene glycol 400 is a solvent of choice, the yields are limited by solvolysis of the leaving group by the solvent, but this phenomenon is controlled by bulky substituents, either in the sulfonic acid part or in the alcohol part of the ester [42] (equation 29)... 

During attempted acetonide formation of an amino alcohol derivative, smooth tosyl cleavage was observed. The reaction is general for those cases having a carboxyl group, as in the following example, but fails for simple amino alcohol derivatives that lack this functionality. ... 

O-isopropylidene derivative (57) must exist in pyridine solution in a conformation which favors anhydro-ring formation rather than elimination. Considerable degradation occurred when the 5-iodo derivative (63) was treated with silver fluoride in pyridine (36). The products, which were isolated in small yield, were identified as thymine and l-[2-(5-methylfuryl)]-thymine (65). This same compound (65) was formed in high yield when the 5 -mesylate 64 was treated with potassium tert-hx Xy -ate in dimethyl sulfoxide (16). The formation of 65 from 63 or 64 clearly involves the rearrangement of an intermediate 2, 4 -diene. In a different approach to the problem of introducing terminal unsaturation into pento-furanoid nucleosides, Robins and co-workers (32,37) have employed mild base catalyzed E2 elimination reactions. Thus, treatment of the 5 -tosylate (59) with potassium tert-butylate in tert-butyl alcohol afforded a high yield of the 4 -ene (60) (37). This reaction may proceed via the 2,5 ... 

By studying the NMR spectra of the products, Jensen and co-workers were able to establish that the alkylation of (the presumed) [Co (DMG)2py] in methanol by cyclohexene oxide and by various substituted cyclohexyl bromides and tosylates occurred primarily with inversion of configuration at carbon i.e., by an 8 2 mechanism. A small amount of a second isomer, which must have been formed by another minor pathway, was observed in one case (95). Both the alkylation of [Co (DMG)2py] by asymmetric epoxides 129, 142) and the reduction of epoxides to alcohols by cobalt cyanide complexes 105, 103) show preferential formation of one isomer. In addition, the ratio of ketone to alcohol obtained in the reaction of epoxides with [Co(CN)5H] increases with pH and this has been ascribed to differing reactions with the hydride (reduction to alcohol) and Co(I) (isomerization to ketone) 103) (see also Section VII,C). 

Addition of alcohols to lactones results in the formation of orthoacid or orthoester derivatives. Thus, reaction of lactone 95a with potassium cyanide in ethanol led to displacement of the tosyl group by cyanide and addition of ethanol to the lactone carbonyl group, to give the orthoacid derivative 95b, which was isolated as its acetate 95c. Mild deacylation of 95c led back to 95b, but under more vigorous reaction conditions the open-chain methyl aldon-ate was obtained (90). 

Tipson devoted most of his years in Levene s laboratory accomplishing seminal work on the components of nucleic acids. To determine the ring forms of the ribose component of the ribonucleosides he applied Haworth s methylation technique and established the furanoid structure for the sugar in adenosine, guanosine, uridine, and thymidine. He showed that formation of a monotrityl ether is not a reliable proof for the presence of a primary alcohol group in a nucleoside, whereas a tosyl ester that is readily displaced by iodide affords clear evidence that the ester is at the 5-position of the pentofuranose. Acetonation of ribonucleosides was shown to give the 2, 3 -C -isopropyl-idene derivatives, which were to become extensively used in nucleoside and nucleotide chemistry, and were utilized by Tipson in the first chemical preparation of a ribonucleotide, inosinic acid. 

Consistent with this mechanism is the fact that the reaction takes place with inversion of configuration at the reaction centre (Johnson and Nidy, 1975). For alkyl tosylates similar results have been reported (San Fillippo et al., 1975). The formation of alcohols under these conditions has been ascribed to secondary reactions (Chern et al., 1978 Johnson et al., 1978). Under certain conditions alcohols are even the only isolated products (Corey et al., 1975). 

A detailed study of the formation of n-octyl ethers under solidrliquid two-phase conditions in the absence of an added solvent has been reported [10], Potassium alkoxides tend to produce higher yields of the ethers than do the corresponding sodium derivatives, but octene is the major product in the reaction of 1-bromooctane with potassium t-butoxide. High temperatures also tend to promote the preferential formation of octene and slightly higher yields of the ethers are obtained using n-octyl tosylate in preference to n-octyl bromide. p-Fluorinated acetals have been prepared either under basic catalytic liquidrliquid or solidrliquid conditions from the fluori-nated alcohol and dichloromethane [11] with displacement of the fluorine atoms. 

Formation of allylic alcohols is favored by supporting electrolytes with tosylate anions. Scheme 7, [11], Under these conditions, only small amounts of ketone were produced. It has been suggested that the role of the tosylate is as a nucleophile that traps the carbocation. Elimination from this intermediate then leads to the allylic alcohol. This explanation is supported by isolation of the... 

Section 7.8). Other classes of derivatives are thus most conveniently prepared from the sulfonyl chloride. Reaction with an alcohol leads to formation of a sulfonate ester. Two common sulfonyl chloride reagents employed to make sulfonate esters from alcohols arep-toluenesulfonyl chloride, known as tosyl chloride, and methanesulfonyl chloride, known as mesyl chloride (see Section 6.1.4). Note the nomenclature tosyl and mesyl for these groups, which may be abbreviated to Ts and Ms respectively. 

Trifluoromethanesulfonates of alkyl and allylic alcohols can be prepared by reaction with trifluoromethanesulfonic anhydride in halogenated solvents in the presence of pyridine.3 Because the preparation of sulfonate esters does not disturb the C—O bond, problems of rearrangement or racemization do not arise in the ester formation step. However, sensitive sulfonate esters, such as allylic systems, may be subject to reversible ionization reactions, so that appropriate precautions must be taken to ensure structural and stereochemical integrity. Tertiary alkyl tosylates are not as easily prepared nor as stable as those from primary and secondary alcohols. Under the standard conditions, tertiary alcohols are likely to be converted to the corresponding alkene. 

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