In many of their reactions organozincs appear as intermediates. Absent additional activation, diorganozinc compounds are generally too nonpolar to react with
carbonyl compounds, but do attack unpolarized C-C multiple bonds. Organozinc compounds can be used in
allylation, or other coupling reactions (such as Negishi coupling): One of the major drawbacks of diorganozinc alkylations is that only one of the two alkyl substituents is transferred. This problem can be solved by using
trimethylsilylmethyl- (Me3SiCH2-), which is stabilized through
negative hyperconjugation in silicon and does not transfer: \begin{array}{l} {}\\ \ce{{R2Zn} + (TMSM)2Zn}\ \overset\ce{THF}\ce{>} \ \ce{2R(TMSM)Zn}\\ {}\\ \ce{{RZnI} + (TMSM)Li ->[\ce{THF}][-80^\circ\!\ce C] {R(TMSM)Zn} + LiI}\\ {} \end{array}
Reformatsky reaction This organic reaction can be employed to convert α-haloester and
ketone or
aldehyde to a β-hydroxyester. Acid is needed to protonate the resulting
alkoxide during work up. The initial step is an oxidative addition of zinc metal into the carbon-halogen bond, thus forming a carbon-zinc enolate. This C-Zn
enolate can then rearrange to the Oxygen-Zinc enolate via coordination. Once this is formed the other carbonyl containing starting material will coordinate in the manner shown below and give the product after protonation. The benefits of the
Reformatsky reaction over the conventional
aldol reaction protocols is the following: • Allows for exceedingly derivatized ketone substrates • The ester
enolate intermediate can be formed in the presence of enolizable moieties • Well suited for
intramolecular reactions Below shows the six-membered transition state of the Zimmerman–Traxler model (Chelation Control, see
Aldol reaction), in which R3 is smaller than R4. The Reformatsky reaction has been employed in numerous total syntheses such as the synthesis of C(16),C(18)-bis-epi-cytochalasin D: The Reformatsky reaction even allows for with zinc homo-enolates. A modification of the Reformatsky reaction is the
Blaise reaction. The reaction is mechanistically related to the
Tebbe reaction and can be catalyzed by various
Lewis acids (e.g.
TiCl4 or
Al2Me6). The reaction is used to introduce
deuterium into molecules for
isotopic labeling or as an alternative to the
Wittig reaction.
Negishi coupling This powerful carbon-carbon bond forming
cross-coupling reactions combines an organic halide and an organozinc halide reagent in the presence of a nickel or
palladium catalyst. The organic halide reactant can be
alkenyl,
aryl,
allyl, or
propargyl. Alkylzinc coupling with alkyl halides such as bromides and chlorides have also been reported with active catalysts such as Pd-PEPPSI precatalysts, which strongly resist beta-hydride elimination (a common occurrence with alkyl substituents). Either diorganic species or organozinc halides can be used as coupling partners during the transmetallation step in this reaction. Despite the low reactivity of organozinc reagents on organic electrophiles, these reagents are among the most powerful metal nucleophiles toward palladium. Alkylzinc species require the presence of at least a stoichiometric amount of halide ions in solution to form a "zincate" species of the form RZnX32−, before it can undergo transmetalation to the palladium centre. This behavior contrasts greatly with the case of aryl zinc species. A key step in the
catalytic cycle is a
transmetalation in which a zinc halide exchanges its organic substituent for another halogen with the metal center. An elegant example of
Negishi coupling is Furstner's synthesis of amphidinolide T1:
Fukuyama coupling Fukuyama coupling is a palladium-catalyzed reaction involving the coupling of an aryl, alkyl, allyl, or α,β- unsaturated
thioester compound. This thioester compound can be coupled to a wide range of organozinc reagents in order to reveal the corresponding ketone product. This protocol is useful due to its sensitivity to functional groups such as
ketone,
acetate, aromatic halides, and even aldehydes. The chemoselectivity observed indicates ketone formation is more facile than oxidative addition of palladium into these other moieties. A further example of this coupling method is the synthesis of (+)-
biotin. In this case, the Fukuyama coupling takes place with the thiolactone:
Barbier reaction The
Barbier reaction involves
nucleophilic addition of a carbanion equivalent to a carbonyl. The conversion is similar to the Grignard reaction. The organozinc reagent is generated via an oxidative addition into the alkyl halide. The reaction produces a primary, secondary, or tertiary alcohol via a
1,2-addition. The Barbier reaction is advantageous because it is a one-pot process: the organozinc reagent is generated in the presence of the carbonyl substrate. Organozinc reagents are also less water sensitive, thus this reaction can be conducted in water. Similar to the Grignard reaction, a
Schlenk equilibrium applies, in which the more reactive dialkylzinc can be formed.
Zinc acetylides The formation of the zinc
acetylide proceeds via the intermediacy of a dialkynyl zinc (functional group exchange). Catalytic processes have been developed such as Merck's
ephedrine process. Propargylic alcohols can be synthesized from zinc acetylides. These versatile intermediates can then be used for a wide range of chemical transformations such as
cross-coupling reactions,
hydrogenation, and
pericyclic reactions. In the absence of ligands, the
reaction is slow and inefficient. In the presence of
chiral ligands, the reaction is fast and gives high conversion.
Ryoji Noyori determined that a monozinc-ligand complex is the active species.
Diastereoselectivity for addition of organozinc reagents into
aldehydes can be predicted by the following model by Noyori and
David A. Evans: • The α-
stereocenter of the ligand dictates observed
stereochemistry of the propargylic alcohols • The
steric effects between the
aldehyde substituent and the ligand are less important but still dictate the favored conformation Zinc-acetylides are used in the
HIV-1 reverse transcriptase inhibitor
Efavirenz as well as in Merck's
ephedrine derivatives . ==Organozincates==