Mitsunobu reaction hydrazines

In summary the Mitsunobu reaction can be described as a condensation of an alcohol 1 and a nucleophile—NuH—11, where the reagent triphenylphosphine is oxidized to triphenylphosphine oxide and the azodicarboxylate reagent 12 is reduced to a hydrazine derivative 13 ... 

A facile synthesis of enantiopure tricyclic furyl derivatives employing 4-vinyl-2,3-dihydrofuran via Diels-Alder cycloaddition reaction was reported <02TL7983>. A new capture-ROMP-release procedure for chromatography-free purification of N-hydroxysuccinimide Mitsunobu reactions was reported by Hanson, who used a Mitsunobu reaction to capture a variety of alcohols onto a norbomenyl A-hydroxysuccinirmde monomer. Treatment of this monomer under ROM-polymerization then generated a water-soluble polymer that was readily separable from other by-products. Subsequent reaction with hydrazine was utilized to release the O-alkylhydroxylamines in good purity from the water-soluble polymer <020L1007>. 

The nature of the nucleophile is critical when considering the Mitsunobu reaction as a means of introducing amine functionalities. Because of the proton transfer components illustrated in the reaction mechanism, only acidic nitrogens can be introduced. The most common nitrogen nucleophiles include phthahmide, hydrazoic acid and zinc azide [62]. Once placed, phthahmides are easily converted to amines utihzing hydrazine [6]. Moreover, azides are easily reduced to amines under numerous conditions [32]. Schemes 6.32 and 6.33 illustrate the application of this chemistry to nucleosides [63] and pyranosides [64], respectively. 

Based on the Amaryllidaceae alkaloid galanthamine, a biomimetic solid-phase synthesis of 2527 compounds was reported by Shair and coworkers (Figure 11.13) The core scaffold, initially prepared in several steps, was diversified by means of four successive reactions Mitsunobu reaction of the phenolic moiety with five primary alcohols, Michael addition of the a, 3-unsatnrated cyclohexenone with thiols, iV-acylation or A -alkylation of the cyclic secondary amine, and treatment of the ketone with hydrazines and hydroxylamines. Further evaluation of library constituents for their ability to block protein trafficking in the secretory pathway of mammalian cells led to the discovery of sercramine as a potent inhibitor of the VSVG-GFP protein movement from the Golgi apparatus to the plasma m brane. 

Two different N-protected hydroxylamines have been used to accomplish the synthesis of these novel hydroxylamine-functionalized resins. fV-Hydroxy-phthalimide has been employed in two ways first, as a nucleophile to splace either a resin-bound chloride ion (30) or a resin-bound mesylate ion (31) Figure 8a) and second, to generate the active phosphonium species required to perform a Mitsunobu reaction on a hydroxyl-functionalized resin (32) (Figure 8b). In both cases, the resin-bound iV-hydroxyphthalimide ester that is generated is subsequently treated with hydrazine to afford resin-bound hydroxylamine. 

The commercially available diethyl azadicarboxylate like reagents are listed below. DEAD (4) and DIAD (5) are by far the most frequently used. The methyl (6), benzyl (7) and terr-butyl (8) analogs of the most commonly used reagents are also known, but used much less frequently. Bis-(2,2,2-trichloroethyl)azadicarboxylate, another commercially available compound, has also been reported, but applications thereof appear to be very limited. ADDP, l,r-(azodicarbonyl)-dipiperidine (10), was first reported by Tsunoda. This reagent appears be useful for more difficult Mitsunobu reactions related reagents in which the piperidine moiety has been replaced by morpholine or A-methyl piperazine are also known. These reagents and the reduced hydrazine products thereof can often be precipitated out by the addition of hexanes to Ae reaction mixture additionally, treatment with mild acid can be useful in the removal of the A-methyl piperidine reagent. 

A second non-selective addition of vinyl Grignard to 661 produces a mixture of alcohols 662 and 665. The hydroxyl center is inverted with phthalimide under Mitsunobu conditions, after which the phthaloyl group is cleaved with hydrazine and the resulting amine acylated to give 664 and 667 (separable by HPLC). Compound 667 is then debenzylated, the acetonide group is hydrolyzed, and the olefin is ozonolyzed to give 668 as a crystalline solid. Likewise, 664 is converted to 669. By a parallel sequence of reactions, 660 is transformed to 670 and 671. Ozonolysis as the last step is a critical feature of these syntheses, because the A-acetyl-hexosamines are generated very cleanly, and such compounds are notoriously difficult to purify. 

Another route to this cyclohexyl derivative involves the preparation of 6.183 via an olefmation reaction with a substituted phenylalinal derivative followed by reduction of the phenyl ring. The alcohol moiety in 6.183 was converted to the N-phthal-oyl derivative (6.184) by a Mitsunobu inversion.m Conjugate addition with a higher order silyl cuprate gave 6.185. The silyl moiety was converted to an alcohol (6.186) by treatment with tetrafluoroboric acid and then KF/m-chloroperoxy-benzoic acid. Removal of the phthalimidoyl group with hydrazine led to an amino-ester, which cyclized to lactam 5.757.11 Hydrolysis gave 4-amino-5-cyclohexyl-3-hydroxypentanoic acid (6.188) in 60% yield. 

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