Mitsunobu reaction


The Mitsunobu reaction is an organic reaction that converts an alcohol into a variety of functional groups, such as an ester, using triphenylphosphine and an azodicarboxylate such as diethyl azodicarboxylate or diisopropyl azodicarboxylate. Although DEAD and DIAD are most commonly used, there are a variety of other azodicarboxylates available which facilitate an easier workup and/or purification and in some cases, facilitate the use of more basic nucleophiles. It was discovered by Oyo Mitsunobu. Typical protocol is to add the phosphine and azodicarboxylate together at -10C, typically in THF of toluene, until a white precipitate forms. This white, cloudy suspension is the ylide. Then a solution of the nucleophile and alcohol are added together and reaction can, and in many cases is, heated to reflux. The alcohol reacts with the phosphine to create a good leaving group then undergoes an inversion of stereochemistry in classic SN2 fashion as the nucleophile displaces it. A common side-product is produced when the azodicarboxylate displaces the leaving group instead of the desired nucleophile.This happens if the nucleophile is not acidic enough or is not nucleophilic enough due to steric or electronic constraints. A variation of this reaction utilizing a nitrogen nucleophile is known as a Fukuyama-Mitsunobu.
Several reviews have been published.

Reaction mechanism

The reaction mechanism of the Mitsunobu reaction is fairly complex. The identity of intermediates and the roles they play has been the subject of debate.
Initially, the triphenyl phosphine makes a nucleophilic attack upon diethyl azodicarboxylate producing a betaine intermediate 3, which deprotonates the carboxylic acid to form the ion pair 5. DEAD itself deprotonates the alcohol forming an alkoxide that can form the key oxyphosphonium ion 8. The ratio and interconversion of intermediates 811 depend on the carboxylic acid pKa and the solvent polarity. Although several phosphorus intermediates are present, the attack of the carboxylate anion upon intermediate 8 is the only productive pathway forming the desired product 12 and triphenylphosphine oxide.
Hughes et al. have found that the formation of the ion pair 5 is very fast. The formation of the oxyphosphonium intermediate 8 is slow and facilitated by the alkoxide. Therefore, the overall rate of reaction is controlled by carboxylate basicity and solvation.

Order of addition of reagents

The order of addition of the reagents of the Mitsunobu reaction can be important. Typically, one dissolves the alcohol, the carboxylic acid, and triphenylphosphine in tetrahydrofuran or other suitable solvent, cool to 0 °C using an ice-bath, slowly add the DEAD dissolved in THF, then stir at room temperature for several hours. If this is unsuccessful, then preforming the betaine may give better results. To preform the betaine, add DEAD to triphenylphosphine in tetrahydrofuran at 0 °C, followed by the addition of the alcohol and finally the acid.

Variations

Other nucleophilic functional groups

Many other functional groups can serve as nucleophiles besides carboxylic acids. For the reaction to be successful, the nucleophile must have a pKa less than 15.
NucleophileProduct
hydrazoic acidalkyl azide
imidesubstituted imide
phenolalkyl aryl ether
sulfonamidesubstituted sulfonamide
arylsulfonylhydrazinealkyldiazene or alkane

Modifications

Several modifications to the original reagent combination have been developed in order to simplify the separation of the product and avoid production of so much chemical waste. One variation of the Mitsunobu reaction uses resin-bound triphenylphoshine and uses di-tert-butylazodicarboxylate instead of DEAD. The oxidized triphenylphosphine resin can be removed by filtration, and the di-tert-butylazodicarboxylate byproduct is removed by treatment with trifluoroacetic acid. Bruce H. Lipshutz has developed an alternative to DEAD, di-azodicarboxylate where the hydrazine by-product can be easily removed by filtration and recycled back to DCAD.
A modification has also been reported in which DEAD can be used in catalytic versus stoichiometric quantities, however this procedure requires the use of stoichiometric benzene to oxidise the hydrazine by-product back to DEAD.
Denton and co-workers have reported a redox-neutral variant of the Mitsunobu reaction which employs a phosphorus catalyst to activate the substrate, ensuring inversion in the nucleophilic attack, and uses a Dean-Stark trap to remove the water by-product.

Phosphorane reagents

Tsunoda et al. have shown that one can combine the triphenylphosphine and the diethyl azodicarboxylate into one reagent: a phosphorane ylide. Both trimethylphosphorane and tributylphosphorane have proven particularly effective.
The ylide acts as both the reducing agent and the base. The byproducts are acetonitrile and the trialkylphosphine oxide.

Uses

The Mitsunobu reaction has been applied in the synthesis of aryl ethers:
With these particular reactants the conversion with DEAD fails because the hydroxyl group is only weakly acidic. Instead the related 1,1'-dipiperidine is used of which the betaine intermediate is a stronger base. The phosphine is a polymer-supported triphenylphosphine.
The reaction has been used to synthesize quinine, colchicine, sarain, morphine, stigmatellin, eudistomin, oseltamivir, strychnine, and nupharamine.