The term organocatalysis describes the acceleration of chemical reactions through the addition of a substoichiometric quantity of an organic compound. The interest in this field has increased spectacularly in the last few years as result of both the novelty of the concept and, more importantly, the fact that the efficiency and selectivity of many organocatalytic reactions meet the standards of established organic reactions. Organocatalytic reactions are becoming powerful tools in the construction of complex molecular skeletons.[1,2]
 Special issue of Adv. Synth. Catal. 2004, 346, Nr. 9-10.
Chirality on the go: Step-growth polymerization between prochiral bis-anhydrides and diols is triggered by a cinchona alkaloid-based organocatalyst, affording new chiral polyesters in good yields with high enantioselectivities (see scheme). The enantioselectivity of the asymmetric polymerization was measured by chiral HPLC analysis of chiral bis-lactones obtained by a controlled depolymerization of the polyesters.
The first application of infrared multiphoton dissociation (IRMPD) spectroscopy to study noncovalent interactions in organocatalysis is reported. Valuable insight into the interactions associated with MacMillan-catalyst-derived α,β-unsaturated iminium ions can be derived in the absence of solvent or counterions. A preliminary structure–catalysis correlation is also disclosed.
A short circuit: An asymmetric Torgov cyclization, catalyzed by a novel, highly Brønsted acidic dinitro-substituted disulfonimide, is described. The reaction delivers the Torgov diene and various analogues with excellent yields and enantioselectivity. The method was applied in a very short synthesis of (+)-estrone.
Metal-free click: A variety of commercially available aldehydes was used in the metal-free organo-click reaction with aryl azides to obtain 1,4-disubstituted 1,2,3-triazoles. The method constitutes an alternative to previously known metal-catalyzed azide–alkyne cycloaddition reactions (AAC), such as CuAAC, RuAAC, and IrAAC. DBU=1,8-diazabicyclo[5.4.0]undec-7-ene; DMSO=dimethyl sulfoxide.
Biologically important and synthetically challenging spirocyclopentaneoxindole derivatives containing four consecutive stereocenters, including one spiro quaternary center, are constructed with excellent enantio- and diastereomeric purities by an organocatalytic iminium–enamine cascade sequence between 3-substituted bifunctional oxindoles and α,β-unsaturated aldehydes under mild conditions.
First class construction: The first catalytic asymmetric construction of a new class of bispirooxindole scaffold containing a tetrahydro-β-carboline moiety has been established through chiral phosphoric acid-catalyzed three-component cascade Michael/Pictet–Spengler reactions of isatin-derived 3-indolylmethanols, isatins, and amino-ester, which afforded structurally complex and diverse bispirooxindoles with two stereogenic centers in excellent stereoselectivities (see scheme; 1,1,2,2-TCE=1,1,2,2-tetrachloroethane; all >95:5 d.r., up to 98:2 e.r.).
Relay tactics: The stereocontrolled assembly of the potent antibiotic (−)-platensimycin in 21 steps and 3.8 % yield from eugenol is described (see scheme; TBAF: tetrabutylammonium fluoride; Ts: toluene-4-sulfonyl). Highlights are 1) a rapid oxidative esterification of an acyl aromatic, 2) a reliable dialkylation protocol to form platensic acid, 3) a π-facial conjugate reduction of a dienone, 4) a TBAF-promoted alkylative dearomatization of a free phenol, and 5) a Friedel–Crafts closure of a free lactol.
Breaking symmetry: Achiral bislactones (1) undergo desymmetrization by reaction with alcohol in the presence of chiral imidodiphosphoric acids. The monoacids 2, having an all-carbon stereogenic center, were obtained in good to excellent yields and enantioselectivities. Concise total syntheses of (−)-rhazinilam and (−)-leucomidine B were subsequently developed using 2 as a common starting material.
Chiral ionic liquids derived from natural amino acids are shown to be efficient solvents or additives for direct asymmetric aldol reactions. A match/mismatch effect between the configuration of the chiral ionic liquid and that of proline has been observed, with a higher enantioselectivity obtained for the (S)-proline/CIL 2 complex.
An organocascade reaction enabling the transformation of enals into α-fluoro- and α,α-difluoro-β-amino aldehydes in a single flask is described. This organocascade reaction combines carbon–nitrogen and carbon–fluorine bond-forming reactions. It is thus a new approach to fluorinated β-amino acid precursors, and generates products not accessible by existing one-pot methods.
Two birds with one stone: The pyrrolidine–camphorsulfonamide-based catalyst 1 a catalyzes the enantioselective conjugate addition of nitroalkanes to α,β-unsaturated aldehydes in the presence of 5 equivalents of water in iPrOH to give the corresponding chiral Michael adducts in good yields and high enantioselectivities (up to 99 % ee) with catalyst loading as low as 1 mol %.
Organocatalysis with MOFs: A practical synthesis route to chiral metal–organic frameworks is proposed that relies on an acid–base interaction between an acid linker and a chiral primary amino acid derived diamine organocatalyst. High ee values for the aldol condensation of linear ketones and aromatic aldehydes are reported.
Now it’s bismuth time! The asymmetric intermolecular α-alkylation of aldehydes with α-bromocarbonyl compounds can be achieved under visible-light irradiation by combining the second-generation MacMillan catalyst and an inexpensive, nontoxic, and commercially available Bi2O3 powder. This reaction also proceeded with high efficiency when the reaction vial was exposed to the morning sunlight in Tarragona, Spain.
A great couple: Fullerene and 2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO) moieties combined in molecular assemblies give rise to excellent catalysts for the oxidation of a wide range of alcohols. These hybrids are easily recycled and maintain their activity after seven cycles.
Off the beaten path: Studies of an unusual inversion of the sense of enantioselectivity for the selenylation of aldehydes catalyzed by a diphenylprolinol ether catalyst provides support for a mechanistic concept beyond the simple steric model developed for enamine catalysis in these systems. A general role for downstream intermediates in selectivity outcomes in organocatalysis is discussed. TMS=trimethylsilyl.
Be there or be square: An efficient approach for the enantioselective synthesis of kojic acid derivatives is developed. Under the catalysis of a chiral bifunctional squaramide incorporated into the (1R,2R)-1,2-diphenylethane-1,2-diamine scaffold, the Michael addition of allomaltol to a great number of β,γ-unsaturated α-ketoesters proceeds smoothly.
Fully functionalized 1,2,3-triazoles were obtained by a metal-free three-component reaction. Simple and readily available building blocks were employed in this organocatalytic transformation, which gave the desired products in good yield and with high regioselectivity. Most of the synthesized triazoles were previously inaccessible.
Deracemization does the trick: The catalytic chiral resolution of tropos biarylphosphineoxides is combined with their high stereoinduction in asymmetric double-aldol-additions. The transient diastereomeric interaction of the modified biarylphosphineoxide was maximized by molecular design, which leads to an unusually high deracemization during HPLC.
This review provides an overview of recent advances in catalytic enantioselective protonation of preformed enol derivatives and catalytically generated enolates or equivalents through various cascade reaction sequences giving access to a large range of enantioenriched compounds containing tertiary stereocentres.
Out with the old: The design and synthesis of new chiral phosphines, as well as their application in catalytic asymmetric reactions, have recently drawn a lot of attention. This review summarizes the advances in the field of enantioselective phosphine organocatalysis within the last couple of years.
Ready to attack! The combination of Lewis acid organocatalysis and internal hydrogen-bond assistance was used to develop a new type of highly active disulfonimide catalyst. The increased Lewis acidity was documented by activity comparisons and theoretical investigations. The potential of the hydrogen-bond-assisted disulfonimide catalyst was demonstrated by its application in an enantioselective transformation.
A doubly positive development: N,N'-Disubstituted cinchona alkaloids were found to be highly efficient phase-transfer catalysts for the assembly of stereogenic quaternary centers. In comparison to traditional cinchona-alkaloid phase-transfer catalysts they afforded substantial improvements in enantioselectivity and reactivity in intramolecular spirocyclization reactions at catalyst loadings as low as 0.3 mol % under mild conditions (see example).
The enantioselective direct Mannich-type reaction of ketimines with α-isocyanoacetates has been developed. Excellent yields and enantioselectivities were observed for the reaction of various ketimines and α-isocyanoacetates using cinchona alkaloid/Cu(OTf)2 and a base. Both enantiomers of the products could be obtained by using pseudoenantiomeric chiral catalysts. This process offers an efficient route for the synthesis of α,β-diamino acids.
Taking steps: A stepwise organocatalytic Michael addition/aldol sequence is described involving secondary-amine-catalyzed regioselective addition of azidoacetone to cinnamaldehyde derivatives followed by intramolecular aldolization. Application of this route to aminocyclitols is demonstrated by a short, asymmetric synthesis of the anticancer natural product (+)-trans-dihydrolycoricidine.
The novel chiral iodoarene can be used as an efficient catalyst for the synthesis of diamines. Quaternary stereocenters can be easily generated with this metal-free, organocatalytic protocol (Cbz=benzyloxycarbonyl).
Key structural parameters involved in the anion-binding process and the catalytic activity of the new family of C-H-bond-based, anion-binding bis-triazole catalysts BisTri were evaluated. These studies enabled the in silico design and identification of a new efficient BisTri catalyst (see scheme; R1=3,5-(CF3)2C6H3, R2=CN) for the alkylation reaction with an N-trityl pyridium salt as ionic electrophile.
Breaking the mirror: In an asymmetric synthesis of tricyclic compounds containing a heterocyclic ring by the desymmetrization of cyclohexadienones, a large variety of substituents at different positions of the cyclohexadienone were tolerated, and the size of the heterocyclic ring could be varied. DFT calculations showed that the reaction proceeds through an asynchronous [4+2] cycloaddition (see scheme).
You can have it both ways! A stereodivergent asymmetric Lewis base catalyzed Michael addition/lactonization of enone acids into substituted dihydrobenzofuran and tetrahydrofuran derivatives is reported, giving products with high d.r. and ee (see scheme).
The natural strategy: Carboxylic acids were activated with chiral phosphoric acid catalysts and the mechanism of epoxide hydrolase served as a model for the asymmetric hydrolysis of meso-epoxides. This method was coupled with the Prilezhaev oxidation and the subsequent hydrolysis of the ester moiety to provide the first highly enantioselective anti-dihydroxylation of simple olefins.
Stereoisomer made to order: Diastereodivergence is realized through controlling the stereoselectivity of the individual steps of a tandem Michael/Michael reaction. Up to 8 of the 16 possible stereoisomers have been successfully obtained in high enantio- and diastereoselectivities using modularly designed organocatalysts for the tandem reaction and an ensuing epimerization. QDT=quinidine thiourea, QNT=quinine thiourea.
Unprecedented heights: Although the triplet state of pyridones (which is populated through sensitizer 1) lies more than 250 kJ mol−1 above the ground state, the enantioselective control of an intermolecular [2+2] photocycloaddition has been achieved for the first time, using only low catalyst loadings.
Pick your type: In the past several decades, highly useful epoxidation protocols have been developed with a variety of activation modes using a wide range of asymmetric organocatalysts. This review documents the rapid and expansive development in this area, thus providing a clear overview of the various catalyst types available for asymmetric organocatalytic epoxidations, as well as their mechanisms and applications.
Re-evaluating PDA: Polydopamine (PDA) is easily available by oxidation of dopamine and is widely used for persistent coatings of various materials. It is hitherto considered to be inert in many interesting biomedical and other applications. However, results revealed here show that PDA is not an innocent polymer and can act as an organocatalyst in direct aldol reactions under mild conditions (see scheme).
Combining supramolecular chemistry with CO2 conversion into cyclic carbonates has led to efficient and robust encaged organocatalysts. The remarkable properties of azaphosphatranes toward this reaction were not only retained but magnified by encapsulation in a supramolecular hemicryptophane structure. These results also support the proposed mechanism involving dual activation of both the epoxide and CO2 at a single azaphosphatrane molecule.
Annulation without hesitation: N-alkoxybenzamides convert into isoquinolones smoothly and rapidly under organocatalytic conditions. The annulation of unsymmetrical diarylacetylenes proceeds with a high regioselectivity. The transformation is based on the hypervalent-iodine mediated generation of nitrenium ions.
Asymmetric 1,2-addition reactions of α-ketoesters to isatins and imines by using acid–base bifunctional 6'-OH cinchona alkaloid catalysts, followed by cyclization and enolization of the resulting adduct, gives spiroisotetronic acids and 5-1H-pyrrol-2-ones, respectively, in excellent optical purities (see scheme; Tr=trityl, Ts=p-toluenesulfonyl). FT-IR analysis suggests that a hydrogen-bonding interaction between the 6'-OH of the cinchona catalyst and an isatin carbonyl group might be crucial for activity and stereocontrol.
All amped up: Boronate ureas amplify the acidity of protic heteroatoms for metal-free, catalytic O-H and S-H insertions by α-diazocarbonyls. The enhanced activity of difluoroboronate ureas is essential for successful insertion reactions; conventional (thio)ureas do not catalyze the desired transformations. This new strategy for metal-free insertions provides access to a broad array of α-acyloxy esters and α-mercaptoesters in high yield (see scheme).
Activation by dimerization: There is still no general activation mode for carboxylic acids in organocatalysis. The formation of heterodimers between chiral phosphoric acid diesters and carboxylic acids can be used to activate and direct reactivity of the latter in asymmetric reactions. This novel principle has been applied to the ring-opening desymmetrization and kinetic resolution of aziridines leading to valuable amino alcohols.
Active duty: Chiral triaryl phosphates promote the enantioselective iodolactonization of 4-substituted 4-pentenoic acids to give the corresponding iodolactones in high yields with high enantioselectivity (see scheme). N-Chlorophthalimide (NCP) is employed as a Lewis acidic activator and oxidant of I2 for the present iodolactonization. In combination with 1.5 equivalents of NCP, only 0.5 equivalents of I2 are sufficient for generating the iodinating reagent.
The power of two: A highly enantio- and regioselective aminocatalytic and Lewis acid catalyzed α-hydroxyamination of β-keto esters and 1,3-diketones with N-hydroxycarbamates is realized in “one-pot” under aerobic conditions. The powerful dual catalysis strategy opens opportunities for developing new efficient organic transformations. Cbz=Benzyloxycarbonyl, Boc=tert-butoxycarbonyl.
Trifluoromethylated all-carbon quaternary stereogenic nitroalkanes have been synthesized in good yields and with good to excellent enantioselectivities by organocatalysed asymmetric Michael addition of malonates to nitroalkenes containing a trifluoromethyl and indole motif. This protocol provides an efficient access to optically enriched γ-amino acids and β-disubstituted γ-butyrolactams.
Methylated β-cyclodextrins catalyze the synthesis of N-substituted pyrroles in biphasic media from amines and 1,4-diketones.
Concerted action: Allylic alcohols were directly used in the title reaction under mild conditions. The reaction smoothly proceeds by the concerted action of a Pd catalyst, a pyrrolidine co-catalyst, and a hydrogen-bonding solvent, and does not require any additional reagents. A computational study suggested that methanol plays a crucial role in the formation of the π-allylpalladium complex by lowering the activation barrier.
Under construction: A single-step enantioselective access to multicyclic oxoquinoline-type heterocycles is possible. The process takes advantage of the unique reaction patterns of esters under N-heterocyclic carbene (NHC) catalysis. It involves activation of the β-carbon atom of an ester as the key step with a subsequent chemoselective cascade reaction with amino enone substrates. Ts=4-toluenesulfonyl.
Asymmetric transfer hydrogenation of aromatic and aliphatic ketimines derived from ethyl ketone derivatives was examined by the combined use of a chiral phosphoric-acid catalyst and a hydrogen donor. The hydrogen donor had a remarkable effect on the enantioselectivity: excellent enantioselectivity was achieved when benzothiazoline was used as the hydrogen donor (see scheme, TRIP=3,3'-bis(2,4,6-triisopropylphenyl)-1,1'-binaphthyl-2,2'-diylhydrogenphosphate).
Orthogonal reactivities: Anthraquinone derivatives catalyze the thermal C3- alkylation of indoles with benzylamines in sequence with a visible-light-driven photooxidation/1,2-shift reaction to provide new fluorescent 2,2-disubstituted indoline-3-one derivatives. Quinones function as H2 shuttles in the indole C3-alkylation with amines and the subsequent photooxidation of the intermediate 3-arylmethyl-1H-indoles is remarkably selective.
Going through a phase: Catalytic asymmetric synthesis of unsymmetrical triarylmethanes, with a chiral all-carbon quaternary center, was achieved by using a chiral bifunctional quaternary phosphonium bromide catalyst in the SNAr reaction of 3-aryloxindoles. The reactions proceeded under phase-transfer conditions. Boc=tert-butoxycarbonyl.
Since initial reports of organocatalysis through hydrogen bonding interactions, a number of strategies have emerged to allow access to enhanced hydrogen-bond donor (HBD) organocatalysts. These strategies range from augmentation of existing HBDs to the design and synthesis of new HBD catalysts. The effects of recent dual HBD designs on catalyst performance are described.
Get straight to the point! The elusive and direct organocatalytic β-functionalization of saturated carbonyl compounds has been tackled by oxidative enamine catalysis, oxidative NHC catalysis and merging of photoredox catalysis with organocatalysis. This new activation mode expanded the horizons of chemical synthesis and offers new insight for organic transformations and complex molecule synthesis.
This review describes an approach to enantiopure products based on the enantioselective generation, through biocatalysis or organocatalysis, of chiral substrates for a multicomponent reaction (MCR). If the chiral substrates are able to control the newly formed stereogenic centers, this strategy allows fast and diversity-oriented entry to complex chiral substrates.
The Perfect Storm! Water facilitates catalyst turnover in enamine organocatalysis, and it is generated during enamine formation. A synergy between Lewis acids and organocatalysts allows for the development of new, selective, and innovative processes, but water-compatible Lewis acids must be employed that are capable of surviving and maintaining activity in the presence of water.
You say goodbye, I say halo: Derivatives of cinchona alkaloids are an important class of organocatalysts. Their applications in asymmetric halofunctionalization of alkenes and alkynes are summarized in this Focus Review. A wide range of nucleophiles, halogenation reagents, and substituted alkenes, alkynes, or enynes can participate in these reactions to afford diverse chiral building blocks.
BINSA, done that: The Brønsted acidity of catalysts is considered to be associated with their catalytic activity. Therefore, chiral 1,1'-binaphthyl-2,2-disulfonic acid (BINSA) has recently received much attention as a strong chiral Brønsted acid catalyst. This Focus Review summarizes the latest achievements in chiral BINSA chemistry from the perspective of their synthesis and their catalytic use in asymmetric organocatalysis.
Less is more: Metal-free systems, including frustrated Lewis pairs (FLPs), have been shown to bind CO2. By reducing the Lewis acidity and basicity of the ambiphilic system, it is possible to generate active catalysts for the deoxygenative hydroboration of carbon dioxide to methanol derivatives with conversion rates comparable to those of transition-metal-based catalysts (see scheme).
Esters—what else! A new strategy in NHC organocatalysis allows the α-, β- and γ-activation of saturated and unsaturated esters. The resulting acyl azolium intermediates efficiently participate in domino reactions with suitable substrates to generate synthetically valuable carbo- and heterocycles with very good diastereo- and excellent enantioselectivities.
All about iodine: Chiral hypervalent iodine chemistry has been steadily increasing in importance in recent years. This Minieview catalogues enantioselective transformations triggered by chiral hypervalent iodine(III/V) reagents, in stoichiometric or catalytic quantities, highlighting the different reactivities in terms of yield and enantioselectivity. Moreover, the synthesis of the most remarkable and successful catalysts has been illustrated in detail.
Control freaks: Chiral amine catalysts prove to be highly proficient mediators in the asymmetric, polyconjugate addition of C-, N-, and S-based nucleophiles to acyclic dienals and cyclic dienones. For high 1,6-selectivities, the stereo spatial matching of the molecular orbitals and ionic charges of the reacting species are key. But can we widen the scope and how far can we go with remote, iminium-stereocontrol?
Smells like team spirit: N-acylimium ions are important reactive intermediates for the enantioselective synthesis of nitrogen-containing compounds. This review summarizes the enantioselective reactions of N-acyliminium ions with two different chiral organocatalysts, thioureas (A) and BINOL-derived phosphoric acid derivatives (B).
Second to none: Secondary amines are well-known enamine and iminium catalysts that can also be used as Lewis bases for the activation of electron-deficient olefins. In this Focus Review, a series of systematic studies on activation of nitroolefins with secondary amines as Lewis bases that give different multicomponent condensation products are described. Asymmetric syntheses of heterocycles based on this strategy are also presented.
A large number of organocatalytic processes are already well established in organic synthesis. Nevertheless, the number of publications in this field is still on the increase; new important results are produced constantly. This review gives a detailed overview of the latest developments and main streams in organocatalyzed asymmetric C-C bond formation of the last three years. It is intended to outline the most important current findings focused on especially new synthetic methodologies.
From pine resin to catalyst: The easily available rosin diterpene abietic acid has been transformed into a unique class of bifunctional thiourea catalysts that can also incorporate further substituents, thereby enabling either Lewis base or enamine activation modes. Their application in a wide range of stereoselective transformations has revealed the positive effect of this chiral and rigid skeleton on the catalytic performance of these hybrid thioureas.
Being the alpha: Despite the synthetic utility of chiral alkyl chlorides, catalytic methods for achieving enantioselective chlorination were only developed a decade ago. This Focus Review discusses the catalytic enantioselective α-chlorination of carbonyl compounds, as well as some stereospecific substitution reactions of the resulting optically active chlorides.
Phosphines and hydrogen bonding are good collaborators! Air-stable α-amino acids or dipeptide derived chiral phosphines bearing hydrogen-bond-donating and silicon-based bulky groups are powerful and versatile catalysts for a range of enantioselective processes, including [3+2] and [4+2] cycloadditions, allylic alkylations, Morita–Baylis–Hillman reactions, and Michael addition reactions. They represent a class of novel, economical, and practical chiral phosphine-based organocatalysts.
Valiant catalysis: Hoveyda et al. have developed a set of catalysts derived from valine for enantioselective syntheses. Reagents are inexpensive, allyl additions are scalable, harsh conditions are avoided, and reactions can be performed with 0.25 mol % catalyst in under 6 h at room temperature. The efficiency, economy, selectivity, and simplicity of the transformations and the range of boron reagents look to have sustained impact on future progress in amine and alcohol syntheses.
When one catalyst meets another: Since chiral Brønsted acids catalysts were discovered more than a decade ago, they have become prevalent in organocatalysis. Researchers have recently used cooperative catalysis to improve existing transformations and discover new reactions. This Focus Review summarizes the achievements made in the field of asymmetric cascade/multicomponent reactions with the help of cooperative catalysis from chiral Brønsted acids.
The inexpensive and readily available ex-chiral-pool building block (–)-isosteviol provides unique geometric features such as the rigid and concave arrangement of its functional groups. Consequently, this valuable architecture has found significant applications in various fields of organic chemistry.
Strategic move: Isatin as a core structure has inspired the development of useful catalytic strategies to give access to interesting molecular architectures with biological activity.
Ready, amine, fire! Amine catalysis is a useful and well-studied method for constructing a wide variety of chiral scaffolds in asymmetric synthesis. However, organocatalysis with amines that is not centered on asymmetric transformations is also developing at a rapid rate. In this Focus Review, reports on amine catalyzed non-asymmetric transformations are examined.
From all natural to bioactive: This review shows that organocatalytic methods based on the use of nucleophilic phosphorus catalysts have been successfully applied as key steps in the formal or total synthesis of complex natural products. These methods also afford suitable tools for the constitution of either focused or diversity-oriented-synthesis inspired libraries of small molecules for biological screening.
The heat is on: A new [3+2] cycloaddition/cycloreversion strategy allows for catalytic and thermally allowed carbonyl–olefin metathesis (see scheme). This strategy opens opportunities for new developments in the field of carbonyl–olefin metathesis, which traditionally relied on stoichiometric amounts of transition-metal reagents or photochemical promotion.
Work in process: The variations in the synthetic applications of phase-transfer reactions between 2006 and the middle of 2012 have been summarized to show the recent progress made in this field. The reactions have been applied to the synthesis of biologically active natural products and the large-scale preparation of drugs. The conceptually new catalyst design, reaction system, and reaction mode are also described.
Cascading down: Reaction of an aldehyde with an NHC provides the corresponding Breslow intermediate A, which can be readily oxidized with various organic and inorganic oxidants to give the acylazolium ion B (see scheme). Intermediate B can react with various nucleophiles either at the 2 or 4-position. With enals as starting aldehydes, elegant cascade processes have been developed using oxidative carbene catalysis.
Strap in with organocatalysis: Organocatalysis can often give rise to unprecedented selectivities by encapsulation of the catalytic active site in an analogous manner as enzymes. Catalyst encapsulation can be considered as a powerful strategy for achieving unique transformations in a very efficient way.
Two views: The mechanism of the conjugate addition of linear aldehydes to nitro olefins has been investigated by two research groups. In spite of extensive experimental data, important questions remain unanswered (see scheme; TMS=trimethylsilyl, En=enamine).
What to do with vitamin B2: Flavins are ubiquitous cofactors for enzymes and have been explored extensively as organocatalysts. Recent developments in the synthesis and use of flavin derivatives are discussed in this Minireview.
Taking the Michael: Recent progress in asymmetric organocatalysis has led to the development of several asymmetric transformations that employ various substrates. Among these substrates, maleimides have emerged as excellent Michael acceptors, dienophiles, and dipolarophiles. In this Focus Review we highlight the advances in the asymmetric synthesis of succinimide derivatives.
Opposites attract: This simple realization is the basis for asymmetric counteranion-directed catalysis (ACDC). All reactions proceeding via cationic intermediates are accompanied by a counteranion. Inducing high enantioselectivities in these reactions merely by ion pairing with an enantiomerically pure counteranion has been achieved for the first time during recent years.