Mitsunobu reaction inversion

In the olivanic acid series of carbapenems the ( )-acetamidoethenyl grouping can be isomerised to the (Z)-isomer (19) (22) and reaction with hypobromous acid provides a bromohydrin that fragments to give a thiol of type (20) when R = H, SO H, or COCH. The thiol is not isolated but can react to provide new alkyl or alkenyl C-2 substituents (28). In the case of the nonsulfated olivanic acids, inversion of the stereochemistry at the 8(3)-hydroxyl group by way of a Mitsunobu reaction affords an entry to the 8(R)-thienamycin series (29). An alternative method for introducing new sulfur substituents makes use of a displacement reaction of a carbapenem (3)-oxide with a thiol (30). Microbial deacylation of the acylamino group in PS-5 (5) has... 

The Mitsunobu reaction is usually used to introduce an ester with inversion of configuration. The use of this methodology on an anomeric hydroxyl was found to give only the /3-benzoate, whereas other methods gave mixtures of anomers. Improved yields are obtained in the Mitsunobu esterification when p-nitrobenzoic acid is used as the nucleophile/ Bis(dimethylamino) azodicarboxylate as an activating agent was... 

The Mitsunobu reaction is used to convert an alcohol and an acid into an ester by the formation of an activated alcohol (Ph3P, diethyl diazodicar-boxylate), which then undergoes displacement with inversion by the carboxylate. Although this reaction works very well, it suffers from the fact that large quantities of by-products are produced, which generally require removal by chromatography. 

The major application of the Mitsunobu reaction is the conversion of a chiral secondary alcohol 1 into an ester 3 with concomitant inversion of configuration at the secondary carbon center. In a second step the ester can be hydrolyzed to yield the inverted alcohol 4, which is enantiomeric to 1. By using appropriate nucleophiles, alcohols can be converted to other classes of compounds—e.g. azides, amines or ethers. 

Entry 10 illustrates the application of the Mitsunobu reaction to synthesis of a steroidal iodide and demonstrates that inversion occurs. Entry 11 shows the use of the isolated Ph3P-Br2 complex. The reaction in Entry 12 involves the preparation of a primary iodide using the Ph3P-I2-imidazole reagent combination. 

The Mitsunobu reaction offers a powerful stereochemical transformation. This reaction is very efficient for inverting the configuration of chiral secondary alcohols since a clean SN2 process is generally observed ( Mitsunobu inversion ). Considering the fact that Mitsunobu chemistry is typically carried out at or below room temperature, high-temperature Mitsunobu reactions performed under microwave con-... 

Epimerization of carbohydrate stractures to the corresponding epi-hydroxy stereoisomers is an efficient means to generate compounds with inverse coirfiguration that may otherwise be cumbersome to prepare. Several different synthetic methods have been developed, including protocols based on the Mitsunobu reaction,sequential oxidation/reduction... 

Treatment of y-nitro alcohols with diethyl azodicarboxylate DEAD and triphenylphos-phine affords nitrocyclopropanes with inversion of configuration at the a-carbon via the intramolecular Mitsunobu reaction involving carbon nucleophiles stabilized by the nitro group (equation 16)28. The reaction works best with nitro compounds (pA"a < 17) and is not applicable to the sulfonyl derivatives (pATa 25). 

The RRM precursor was synthesised in a multistep procedure from alcohol 33. The first allyl amino side chain was introduced by a Mitsunobu reaction with Ns protected allylamine with inversion of configuration. Attempts to introduce the second N-protected allylamine via an 7 -allyl Pd(0)-substitution failed. Changing the order of the substitution was also unsuccessful (Scheme 11). 

Dinsmore and Mercer further investigated this reaction using DBU as a base and n-Bu3P/DBAD (di-tert-butyl azodicarboxylate) as Mitsunobu s reactants, and found an unexpected steroselectivity in the Mitsunobu transformation [75b], In fact, the stereochemical course of the Mitsunobu reaction (Scheme 6.11) depended on whether the carbamic acid intermediate was N-substituted with hydrogen (retention) or with carbon (inversion). 

The reaction proceeds with clean inversion, which makes the Mitsunobu Reaction with secondary alcohols a powerful method for the inversion of stereogenic centres in natural product synthesis. 

Another example employed Mitsunobu reaction for the inversion reaction (Figure 10(b)).A single enantiomer of a (stereo)chemically labile allylic-homoallylic alcohol was obtained in 96% yield and 91% ee from the racemate through a lipase-catalyzed kinetic resolution coupled with in situ inversion under carefully controlled (Mitsunobu) conditions. Using this reaction, the algal fragrance component, (S)-dictyoprolene, was synthesized. 

Inversion of the stereocenter of (S)-l by the Mitsunobu reaction provides (R)-l. This bromonaphthalene is converted by the same sequence as above into the pery-lenequinone calphostin D (5). In this case the axial stereoselectivity in the dimerization step is opposite to that observed with (S)-l. 

Note that alkyl azides are potentially explosive. This and the simpler reaction conditions involved is one reason why the reaction described above is mainly carried out as a Mitsunobu reaction. In this method the alkanol is reacted with diethyl diazenedicarboxylate, triphenylphosphane and hydra-zoic acid in a one-pot reaction. The reaction also proceeds with inversion and affords the amine directly because the intermediate azide is reduced by excess triphenylphosphane in situ. 

Several examples of reactions of allyl alcohols under Mitsunobu reaction conditions using diethyl azodicarboxylate (DEAD) and triphenyl phosphine giving allyl amines are known. An example is the reaction of the steroid 5 with azide nucleophiles under Mitsunobu reaction conditions, giving the corresponding azide 6 in 63 % yield (Eq. (3)) [5]. The reaction is regioselective with inversion of the configuration and no SN2/ substitution is observed. 

If this is all correct, then the vital 5 2 step should lead to inversion as it always does in Sn2 reactions. This turns out to be one of the great strengths of the Mitsunobu reaction—it is a reliable way to replace OH by a nucleophile with inversion of configuration. The most dramatic example is probably the formation of esters from secondary alcohols with inversion. Normal ester formation leads to retention as the C-O bond of the alcohol is not broken. 

The Mitsunobu reaction is used to replace OH by another group with inversion of configuration. 

In the Mitsunobu reaction, the C-O bond of the alcohol is broken because the alcohol becomes the electrophile and the acid derivative must be a nucleophile so an acid is better than an acid chloride. The ester is formed with inversion. Note the fate of the oxygen atoms, ester formation from a secondary alcohol with inversion by the Mitsunobu reaction... 

The Mitsunobu reaction is one of the staple reactions for clean nucleophilic substitution with inversion of configuration. It came as a surprise, therefore, to find that a Mitsunobu reaction on atlyEic alcohol 143,1 [Scheme 8 143) using terf-butyl 2-(trimethylsilyl)ethylsulfonylcarbamate (143.2) as the nucleophile occurred with retention of configuration.320 The unusual stereochemistry was explained by a double inversion process in which neighbouring group participation first leads to the intermediate 1433. A subsequent second nucleophilic substitution by 1433 then gave the product 143.4 in 86% yield ... 

Alcohol inversion. Elimination competes with S, 2 substitution in the inversion of secondary alcohols by the Mitsunobu reaction or by reaction of mesylates with cesium propionate or cesium acetate. Elimination in the inversion of cyclopentyl and cyclohexyl alcohols can be largely suppressed by reaction of the mesylate with cesium acetate (excess) and a catalytic amount of l8-crown-6 in refluxing benzene. Even inversion of an ally lie alcohol can be effected in moderate yield under these conditions (equation I). ... 

Macrolactonization can also be achieved by the Mitsunobu reaction [44] with inversion of the configuration of the alcohol. The reaction principle and mechanism are demonstrated in Scheme 24. Addition of triphenylphosphine to diethyl azodicarboxylate (DEAD, 73) forms a quaternary phosphonium salt 74, which is protonated by hydroxy acid 11, followed by phosphorus transfer from nitrogen to oxygen yielding the alkoxyphosphonium salt 76 and diethyl hydrazinedicarboxy-late 75. Then, an intramolecular Sn2 displacement of the important intermediate 76 results in the formation of the lactone 15 and triphenylphosphine oxide. 

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