You-Quan
Zou
*,
Fabian M.
Hörmann
and
Thorsten
Bach
*
Department Chemie and Catalysis Research Center (CRC), Technische Universität München, Lichtenbergstraße 4, 85747 Garching, Germany. E-mail: youquan.zou@gmail.com; thorsten.bach@ch.tum.de; Web: http://www.oc1.ch.tum.de/home_en/
First published on 20th November 2017
Although enantioselective catalysis under thermal conditions has been well established over the last few decades, the enantioselective catalysis of photochemical reactions is still a challenging task resulting from the complex enantiotopic face differentiation in the photoexcited state. Recently, remarkable achievements have been reported by a synergistic combination of organocatalysis and photocatalysis, which have led to the expedient construction of a diverse range of enantioenriched molecules which are generally not easily accessible under thermal conditions. In this tutorial review, we summarize and highlight the most significant advances in iminium and enamine catalysis of enantioselective photochemical reactions, with an emphasis on catalytic modes and reaction types.
Key learning points(1) The concept of synergistic combination of iminium and enamine catalysis with photocatalysis.(2) The photogeneration of ortho-quinodimethanes, open-shell free radicals and iminium cations. (3) The single-electron-transfer (SET) mechanism in enantioselective photochemical reactions. (4) The direct excitation of iminium ions and enamines in enantioselective photochemical reactions. (5) The electron donor–acceptor (EDA) complex mechanism in enantioselective photochemical reactions. |
At the dawn of enantioselective photochemistry, circularly polarized light (CPL) was frequently used as the source of chirality.3 However, the use of CPL was limited to specific starting materials and the relatively low reaction efficiency largely stymied its application as a universal approach in enantioselective photochemistry. Additionally, asymmetric organocatalysis, a relatively large branch of enantioselective catalysis, started to blossom in the beginning of the 21st century, and it has developed into a flourishing research field. A large number of fine and useful enantioenriched chiral compounds with a well defined three-dimensional spatial arrangement have been constructed by means of organocatalytic protocols.4 The success of asymmetric organocatalysis is attributed to privileged enantiopure structures such as proline, cinchona alkaloids, BINOL (1,1′-bi-2-naphthol), and related compounds. These small molecules could be easily elaborated into different bespoke organocatalysts which have found a myriad of applications in asymmetric organocatalysis. Meanwhile, asymmetric organocatalysis also opens new avenues for chemists to approach the enantioselective catalysis of photochemical reactions. For instance, iminium and enamine catalysis using chiral amines, Brønsted acid catalysis employing chiral phosphoric acids, hydrogen bonding catalysis with chiral ureas and thioureas, N-heterocyclic carbene catalysis using chiral heteroazolium salts as well as phase-transfer catalysis with chiral ammonium salts have been successfully introduced into enantioselective photochemical reactions. In this context, iminium and enamine catalysis have recently grown in interest due to their high efficiency to activate aldehydes and ketones with excellent enantioselectivity, thus enabling the synthesis of diversely functionalized chiral carbonyl compounds.
Recently, some reviews have been written by us5 and other research groups6,7 in the field of enantioselective catalysis of photochemical reactions. However, to the best of our knowledge, there is still no specific and comprehensive review devoted to iminium and enamine catalysis in enantioselective photochemical reactions. Consequently, we herein provide a tutorial review to give a solid introduction to the field and highlight the recent breakthroughs in this area. Reactions which occur in heterogeneous conditions will be given less attention in this review. Organization of the data follows a subdivision according to catalytic modes (iminium or enamine catalysis) and reaction types. The emission wavelength or wavelength range of the irradiation is given in the schemes. The reaction temperatures are only specified if the reactions were not carried out at room temperature.
Scheme 2 Enantioselective β-benzylation of enals 10. ad.r. > 95/5. bd.r. = 56/44, the ee refers to the major diastereoisomer. cToluene employed as the solvent using 2 as the catalyst. |
In this transformation, chiral secondary amine 1 is condensed with enals 10 to iminium salts 13. Additionally, a light induced enolization of ortho-alkyl substituted benzophenones to (E)-enol 12 occurs. The latter undergoes nucleophilic addition to the chiral iminium salt 13 to deliver the Michael-type addition products rather than [4+2] cycloadducts. A density functional theory (DFT) computational study was carried out by the authors to shed some light on this unusual reactivity and the results indicated that this transformation proceeds through a water assisted proton shuttle mechanism.
Recently, the Ye group15 reported an enantioselective β-benzylation reaction of enones 14via a similar strategy. As shown in Scheme 3, 2-cyclohexenone reacts – upon UV irradiation (λ = 365 nm) – with a variety of 2-alkyl benzophenones 9 in the presence of 20 mol% of chiral amino acid ester 4 furnishing the β-benzylation products in moderate to good yields with excellent enantioselectivity (e.g., 15a–15d). Electron donating and electron withdrawing groups on the enolizable aromatic ring of benzophenones did not have a significant effect on the reaction efficiency. The substrate scope included a β-substituted cyclohexenone (product 15e), an acyclic α,β-unsaturated ketone (product 15f), and a seven-membered cyclic enone (product 15g). None of the desired product was observed, when 2-cyclopentenone was used as the substrate. Interestingly, the reaction of 2-cyclopentenone did proceed to give the addition product 15h in 99% ee when chiral amine 6 was employed as the catalyst.
Scheme 3 Enantioselective β-benzylation of enones 14. ad.r. > 95/5. b50 mol% benzoic acid was used instead of acetic acid. c6 was used as the chiral amine catalyst. HOAc = acetic acid. |
In biological systems, iminium ions have been found to absorb visible light and induce primary photochemical events. The reactivity of these ions in the excited state16 is dominated by electron transfer processes and has been extensively studied by the group of Mariano.17 Very recently, Melchiorre and co-workers disclosed the first asymmetric approach based on this reactivity enabling the enantioselective synthesis of β-alkylated aldehydes (Scheme 4).18 Crucial for the success was (a) the high redox potential of iminium ion 19 in the excited state and (b) the bathochromic shift in absorption which reaches to the visible light region when (E)-cinnamaldehyde (16) is condensed with chiral secondary amine 3 to iminium ion 19. Upon irradiation with visible light (λ = 420 nm), the iminium ion 19 populates the excited state, which is able to react with trimethylsilane 17 generating β-enaminyl radical 20 and silyl radical cation via a SET process. After solvent-assisted desilylation an intermolecular radical–radical coupling occurs and subsequent hydrolysis gives product 18 and amine 3 is regenerated. It is worth mentioning that no photocatalyst was needed in this reaction.
Scheme 5 Formation of products 21 by enantioselective trapping of benzodioxole-derived radicals with enones catalyzed by amine 5. TBABF4 = tetrabutylammonium tetrafluoroborate. |
This methodology represents a major breakthrough in the field of asymmetric radical chemistry, and it also highlights the application of iminium catalysis in enantioselective photochemical reactions. The carefully designed catalyst not only served as a chiral amine to control the enantioselectivity, but also functioned as an efficient electron-rich center to prevent the radical elimination (β-scission) of radical cation 22 to its iminum ion precursor and to reduce 22 to the key intermediate enamine 23. This strategy could also be extended to a visible-light-induced enantioselective trapping of α-amino radicals.20 By using 1 mol% Ir[dF(CF3)ppy]2(dtbbpy)PF6 (dF(CF3)ppy = 3,5-difluoro-2-[5-(trifluoromethyl)-2-pyridinyl]phenyl, dtbbpy = 4,4′-di-tert-butyl-2,2′-bipyridine) as the photocatalyst and ent-5 as the organocatalyst, a wide range of cyclic enones could be coupled with various tertiary amines with excellent stereocontrol (Scheme 6). Recently, detailed mechanistic studies regarding this radical conjugated addition reaction were carried out by the same group.21
Scheme 6 Enantioselective trapping of α-amino radicals with enones catalyzed by ent-5. Ir[III] = Ir[dF(CF3)ppy]2(dtbbpy)PF6. |
Additionally, an enantioselective photocatalytic Michael addition/oxyamination cascade of enals was discovered by Jang and co-workers.22 By using chiral secondary amine 2 along with N719/TiO2, a variety of α-oxyaminated β-alkylated aldehydes were produced in moderate to good yields with excellent enantio- and diastereoselectivities.
The benefit of enamine catalysis is the high enantiocontrol which can be achieved by employing chiral amines as catalysts. In this context, a vast majority of amines have been developed and successfully employed in enamine catalysis, rendering enantioenriched functionalized carbonyl compounds under thermal reaction conditions. In recent years, the enamine catalytic mode has also been extended to enantioselective photochemistry, and Fig. 2 depicts the structures of selected chiral amines used in photochemistry, such as chiral secondary amines 25–31 and primary amines 32–37.
Fig. 2 Structures of representative chiral amines 25–37 for enamine catalysis in enantioselective photochemical reactions. |
Recent work from the Yoon group shed some doubt on the proposed action of two synergistic catalytic cycles.26 It was found that the quantum yield for the formation of product 38a was Φ = 18, which indicates that the enantioselective α-alkylation reaction likely proceeds through a radical chain propagation mechanism. Chain propagation can occur if α-amino radical 41 is oxidized by the α-bromo carbonyl substrate but not by the excited photocatalyst. Ceroni, Cozzi and co-workers postulated a similar chain process when using Fe(bpy)3Br2 as the photocatalyst.27
Organic dyes, a class of environmentally friendly, cheap, readily available and easy to handle photocatalysts, have been successfully applied in photocatalysis.28 In 2011, Zeitler and co-workers realized an enantioselective α-alkylation reaction of aldehydes by using eosin Y as the photocatalyst.29 As exemplarily shown in Scheme 8, the reaction of octanal and diethyl 2-bromomalonate in the presence of 20 mol% of imidazolidinone 25a and 0.5 mol% of eosin Y gave the desired product in 85% yield with 88% ee. From a mechanistic point of view, the authors proposed that the photocatalyst eosin Y initially undergoes a rapid intersystem crossing (ISC) upon irradiation. Subsequently, the excited triplet state of eosin Y follows the same pathway as the excited state *Ru[II] to mediate the following steps. The Ferroud group found Rose Bengal was also suitable for this transformation.30 Both metal free methods gave comparable results to the ruthenium catalyzed process.
Scheme 8 Enantioselective α-alkylation of aldehydes catalyzed by chiral imidazolidinone 25a using eosin Y as the photocatalyst. |
Heterogeneous catalysts are often highly efficient and recyclable, and therefore would provide an alternative to the use of noble metal photocatalysts and organic dyes in photochemistry. In this regard, several heterogeneous photocatalysts such as PbBiO2Br, Bi2O3 as well as NbSe2 nanosheet supported PbBiO2Br have been used in the visible light-driven asymmetric α-alkylation of aldehydes by the König group,31 the Pericàs and Palomares groups,32 and the Fan group,33 respectively. Duan and co-workers demonstrated that chiral metal–organic frameworks (MOFs) of Zn-PYI1 and Zn-PYI1 also showed remarkable catalytic activity in the same transformation.34
The MacMillan group successfully expanded their dual catalysis platform to target enantioenriched α-trifluoromethylated and α-perfluoromethylated aldehydes.35 Using a combination of Ir(ppy)2(dtbbpy)PF6 and chiral secondary amine 25a, a wide range of aldehydes could be coupled with trifluoromethyl iodide furnishing the α-trifluoromethylation products in moderate to good yields with excellent enantioselectivity (Scheme 9). Functional groups such as ethers, esters, amines, carbamates (e.g., 42b) and aromatic rings (e.g., 42c) were tolerant under the optimized reaction conditions. Perfluoroalkyl iodides were also suitable in this enantioselective alkylation reaction, and various chiral α-perfluoromethylated aldehydes were synthesized under the same reaction conditions (e.g., 42d and 42e). To demonstrate the potential synthetic applications of this methodology, α-trifluoromethyl 3-phenylpropanal (42c) was readily converted to the corresponding α-trifluoromethyl-substituted acid, the respective β-trifluoromethyl-substituted amine, as well as to the β-trifluoromethyl-substituted alcohol without significant loss of enantiopurity. Notably, high enantioselectivities could only be achieved at −20 °C but not at ambient temperature.
Scheme 9 Enantioselective α-trifluoromethylation and α-perfluoromethylation of aldehydes catalyzed by chiral imidazolidinone 25a. Ir[III] = Ir(ppy)2(dtbbpy)PF6, Boc = tert-butyloxycarbonyl. |
Nitrile group containing compounds are a class of versatile building blocks in organic synthesis, which can be readily transformed into carbonyl, amine, imidate motifs, etc. Similarly, β-cyanoaldehydes can be readily converted into their corresponding lactone, pyrrolidine, lactam and cyanoalcohol derivatives. In light of the synthetic potential of nitrile compounds, the enantioselective synthesis of β-cyanoaldehydes is highly desirable. In 2015, MacMillan and co-workers reported the first example of enantioselective α-cyanoalkylation of aldehydes by means of their synergistic combination of photoredox catalysis and organocatalysis, providing rapid access to chiral β-cyanoaldehydes 43.36 As depicted in Scheme 10, under the optimal conditions, a large array of α-bromoacetonitriles reacted with aldehydes to give the desired products (e.g., 43a–43d) with excellent enantioselectivity. Interestingly, the product derived from 3-phenylpropanal could be smoothly converted to the corresponding alcohol, ether, lactone, aldehyde, ketone, amide, amine and lactam without erosion of stereochemical integrity. A four-step synthesis of the natural product (−)-bursehernin was also carried out using the aforementioned strategy.
Since all of the above-mentioned dual catalysis examples require the use of photocatalyst, the Melchiorre group developed a conceptually new approach for the enantioselective α-alkylation of aldehydes via an electron donor–acceptor (EDA) complex37 mechanism. As illustrated in Scheme 11, an enamine intermediate was first generated by condensing butyraldehyde (44) with the chiral secondary amine 31.38 Upon association of enamine with the electron-deficient 2-bromo-1-phenylethan-1-one (45), a transient photo-absorbing chiral EDA complex 47 was formed via an n → π* interaction in the ground state. Visible light irradiation of the colored EDA complex 47 initiated a SET process to give the contact radical ion pair 48, which is stabilized by coulombic attractive forces to preserve the original orientation. Subsequently, a positively charged intermediate pair was generated with the release of the bromide anion. Following radical–radical coupling and hydrolysis, the enantioenriched α-alkylated aldehyde was produced in the absence of any external photocatalyst.
It should be noted that a radical-chain propagation pathway cannot entirely ruled out at this stage. The success of this reaction is attributed to the formation of the colored EDA complex 47 which absorbs the visible light. This methodology tolerates a wide range of aldehydes and phenacyl bromides, even a thiophene containing bromide reacted with butanal to give the product 46c in 92% isolated yield with 87% ee. γ-Site selective alkylation of enals was also achieved by using chiral amine 2 as the organocatalyst (e.g., 46d).
The EDA complex strategy could also be applied to the enantioselective α-alkylation of cyclohexanone (49).39 Switching the light source to a 300 W xenon lamp (λ = 300–600 nm), cyclohexanone (49) was coupled with a broad array of phenacyl bromides in the presence of quinidine-derived chiral primary amine 36, which led to the α-alkylated cyclohexanones 50 with excellent enantioselectivity (Scheme 12). The work described here expanded the substrate scope of enantioselective amine-catalyzed α-alkylation reactions to cyclic ketones.
Scheme 12 Enantioselective α-alkylation of cyclohexanone (49) via an electron donor–acceptor (EDA) complex mechanism. |
At a later stage, Melchiorre and co-workers disclosed a direct photoexcitation strategy to achieve the enantioselective α-alkylation of aldehydes.40 By using bromomalonates as the reaction partners, no color change was observed when exposed to the enamine intermediate 52. This observation led the authors to propose a unique direct excitation pathway, where upon irradiation the enamine 52 populates its excited state 52* (Scheme 13). Then 52* acts as a photosensitizer to reduce the bromomalonate to the open-shell radical species, which in turn couples with the ground state enamine 52 followed by an oxidation via another bromomalonate and following hydrolysis the final products are generated. In the entire catalytic cycle, the excited 52* was sacrificed and a chain propagation mechanism was involved. To gain more insight into the mechanism of this transformation, detailed photophysical studies, nuclear magnetic resonance (NMR) spectroscopy as well as kinetic studies were recently conducted by the same group.41
Scheme 13 Enantioselective α-alkylation of aldehydes via the direct excitation of enamines 52. aReaction performed upon sunlight irradiation. TIPS = triisopropylsilyl. |
Furthermore, the above direct excitation protocol could be extended to the enantioselective α-(phenylsulfonyl)methylation of aldehydes by using ent-30 as the organocatalyst.42 Na2S2O3 was added to remove possible trace amounts of iodine in the reaction mixture and therefore improved the reaction efficiency. A (phenylsulfonyl)methyl or (methylsulfonyl)methyl group could readily be incorporated into various aldehyde components, and the chiral α-alkylated products were isolated as the corresponding alcohols after in situ reduction with NaBH4 in moderate to good yields with good enantioselectivity (Scheme 14). The reaction proceeds via an atom-transfer radical addition (ATRA) mechanism and the phenylsulfonyl moiety from the iodide substrates acted as a redox auxiliary group to facilitate the formation of the radical key intermediate.
Scheme 14 Enantioselective α-(phenylsulfonyl)- and α-(methylsulfonyl)methylation of aldehydes catalyzed by ent-30. |
As shown above, the alkylation reagents used in the enantioselective synthesis of α-alkylated carbonyl compounds are always pre-activated halides, which do not meet the atom economy ideals of modern organic synthesis. Consequently, the direct enantioselective α-alkylation of carbonyl compounds from simple and abundant synthetic building blocks is highly desirable. Recently, MacMillan and co-workers reported an elegant enantioselective α-alkylation of aldehydes with simple olefins by synergistically merging photoredox, enamine and hydrogen-atom transfer (HAT) catalysis.43 As described in Scheme 15, the N-tethered aldehydic olefin 54 is initially converted to the chiral enamine by condensation with organocatalyst 25b, which in turn is oxidized to the enaminyl radical 56 by the excited photocatalyst *Ir[III]. The enaminyl radical 56 rapidly adds to the olefin moiety to generate a nucleophilic radical 57 through an intramolecular radical–radical coupling. Subsequently, radical 57 participates in a HAT catalytic cycle mediated by 2,4,6-triisopropylbenzenethiol affording the key iminium ion following a hydrolysis to the desired product 55a. Concurrently, the thiyl radical arising from the HAT catalytic cycle reacts with the reduced photocatalyst Ir[II] to regenerate the ground state photocatalyst Ir[III] and the HAT thiol catalyst. N-Tethered, O-tethered and even alkyl tethered aldehydic olefins were all compatible with the optimised conditions, giving rise to chiral hetero- or carbocyclic ring systems (e.g., 55a–55e) in moderate to good yields with high enantiocontrol.
The authors found this tricatalytic strategy was also suitable for an intermolecular variant. Using 20 mol% of chiral amine ent-30 as the organocatalyst, 1 mol% of Ir(dmppy)2(dtbbpy)PF6 [dmppy = 2-(4-methylphenyl)-4-(methylpyridine)] as the photocatalyst and 10 mol% of 2,4,6-tri-tert-butyl benzenethiol as the HAT catalyst, a large number of aldehydes reacted with different styrenes, providing the α-alkylated aldehydes with excellent enantioselectivity (e.g., 58a–58d). Additionally, methylenecyclopentane was also subjected to these conditions outlined in Scheme 16, and product 58e was obtained in 90% ee.
The Luo group recognized that the chiral primary amine 32 was a robust catalyst for the enantioselective α-alkylation of β-ketocarbonyl compounds by merging photoredox catalysis and enamine catalysis.44 Under their optimized reaction conditions, a large array of acyclic ketoesters, cyclic ketoesters, and aliphatic 1,3-diketones were coupled to various phenylacyl bromides, and the enantioenriched compounds 59a–59d bearing an all-carbon quaternary stereogenic center were constructed in a highly concise fashion (Scheme 17). Surprisingly, when N-aryl substituted β-ketoamides were employed as the reactants, spiro-γ-lactams (e.g., 59e–59g) with two nonadjacent quaternary stereogenic centers were isolated as products of an α-alkylation/intramolecular ketalization cascade with excellent enantioselectivity and diastereoselectivity. The hydrogen bonding between the protonated chiral tertiary amine moiety and the keto moiety of β-ketocarbonyl compounds was crucial for the stereocontrol, which guided the well-defined orientation of the chiral complex 60 formed from enamine intermediate and the open-shell radical species.
Scheme 17 Enantioselective α-alkylation of β-ketocarbonyl compounds catalyzed by 32. Ru[II] = Ru(bpy)3Cl2·6H2O. ad.r. = 96/4. bd.r. = 94/6. cd.r. > 99/1. |
In contrast to MacMillan's dual catalysis, the EDA complex mechanism can operate without the need of any external photocatalyst and this reaction has found wide applications in the enantioselective α-benzylation of aldehydes.38 The coloured EDA complex 64 was observed by Melchiorre and co-workers when treating electron-deficient benzyl bromides such as 1-(bromomethyl)-2,4-dinitrobenzene (62) with the chiral enamine intermediate derived from the corresponding aldehydes and the secondary amine 31. The EDA complex 64 undergoes an intermolecular SET process to generate a chiral radical ion pair 65 which in turn triggers the following radical–radical coupling step. As shown in Scheme 19, several electron-deficient benzyl bromides reacted with a range of aldehydes to achieve the α-benzylation of aldehydes with good enantiocontrol. Interestingly, 2-phenylpropanal could also be employed in the reaction when using chiral amine 2 as the organocatalyst and the transformation forged an all-carbon quaternary stereogenic centre product 63d in 86% ee.
Scheme 19 Enantioselective α-benzylation of aldehydes catalyzed by 31via an electron donor–acceptor (EDA) complex mechanism. aChiral amine 2 was used as the organocatalyst. |
The majority of α-alkylations and α-benzylations of carbonyl compounds are largely based on aldehyde precursors, and the α-alkylation or benzylation of ketones is still largely unexplored. In 2014, Melchiorre and co-workers realized the direct enantioselective α-alkylation of cyclohexanone via an EDA complex mechanism.39 They demonstrated that this protocol was also suitable for the α-benzylation of cyclic ketones by simply switching the light source to a 23 W compact fluorescent light (CFL) bulb (Scheme 20). Various cyclic ketones such as cyclopentanone, cyclohexanone, cycloheptanone as well as N-Boc-piperidin-4-one could be benzylated with 1-(bromomethyl)-2,4-dinitrobenzene (62) as the reaction partner, generating the desired products (e.g.66a–66d) with moderate to good enantioselectivity.
Scheme 20 Enantioselective α-benzylation of cyclic ketones catalyzed by 36via an electron donor–acceptor (EDA) complex mechanism. aReaction performed on a 1 mmol scale. |
More recently, Wu, Luo and co-workers reported a unique tricatalytic system involving enamine catalysis, photocatalysis and transition metal catalysis to realize the enantioselective cross-dehydrogenative coupling (CDC) reaction between tetrahydroisoquinolines and ketones.46 By using 3 mol% of Ru(bpy)3Cl2·6H2O and 8 mol% of Co(dmgH)2Cl2 (dmgH = dimethylglyoximate), numerous cyclic and acyclic ketones were coupled with N-aryl tetrahydroisoquinolines and an enantioselective α-benzylation of ketones could be achieved by irradiation with visible light in the presence of 20 mol% of chiral amine 33 and 40 mol% of 3-nitrobenzoic acid (Scheme 21). The authors proposed an oxidative quenching mechanism in the photocatalytic cycle, where the excited photocatalyst Ru[II]* is first oxidized to Ru[III] by Co[III]. Subsequently, Ru[III] is suggested to oxidize the N-aryl tetrahydroisoquinoline to the iminium cation by SET and the release of an additional electron and a proton. By the aid of 3-nitrobenzoic acid, the reduced Co[II] captures the electron and the proton to regenerate Co[III]. In the enamine catalytic cycle, the ketone condenses with amine 33 to form a chiral enamine, which then intercepts the iminium cation via the transition state 68 to give the corresponding products. It is worth mentioning that 3-nitrobenzoic acid not only acts as an acid additive to promote the formation of the chiral enamine intermediate, but also plays an important role as a hydrogen acceptor undergoing an in situ hydrogenation step to 3-aminobenzoic acid.
A further application of the oxygenation methodology was achieved with ketones as the substrates and chiral amine 34 as the catalyst (Scheme 23).50 Cyclohexanone and C4-substituted cyclohexanones were readily oxidized, allowing for the synthesis of chiral α-hydroxylated cyclic ketones (e.g., 72a–72c). Furthermore, acyclic ketones such as octan-2-one could also be favourably employed for the enantioselective α-hydroxylation, albeit with lower ee (72d, 28% ee) by using 35 as the organocatalyst.
Scheme 23 Enantioselective α-hydroxylation of ketones catalyzed by 34. aReaction was performed in N-methylpyrrolidinone (NMP). b35 was used as the catalyst. |
Jang and co-workers developed an enantioselective photocatalytic α-oxyamination of aldehydes under heterogeneous conditions.51 In this case, commercially available TiO2 was introduced as the photocatalyst, and chiral amines 2 or ent-30 were employed as the chiral amine catalysts. Remarkably, a wide range of aldehydes were coupled with (2,2,6,6-tetramethylpiperidine-1-yl)oxyl (TEMPO) to deliver the desired α-oxyaminated aldehydes with moderate to good enantioselectivity (up to 78% ee).
An external photocatalyst was not employed in this amination reaction. The success of the transformation strongly depends on the leaving group 2,4-dinitrophenylsulfonyl (DNs) in the amination reagent 73. Mechanistically, the open-shell N-centered radical 75 is initially generated upon irradiation with visible light, which then rapidly adds to the electron-rich enamine 76 generated from the condensation of aldehyde and chiral amine 28. Oxidation of the resulting α-amino radical intermediate by the photoexcited amination reagent 73 forms the second equivalent of N-centered radical 75 accompanying the formation of the iminium ion. Hydrolysis of the iminium ion furnishes the final product and releases the chiral amine 28 to re-enter the catalytic cycle.
Scheme 25 Enantioselective β-arylation of cyclohexanone (49) catalyzed by 37. Ir[III] = Ir(ppy)3, DABCO = 1,4-diazabicyclo[2.2.2]octane, DMPU = 1,3-dimethyltetrahydropyrimidin-2(1H)-one. |
The authors postulated a possible mechanism to explain the formation of the β-arylated products. The initial step entailed an oxidative quenching of the photoexcited catalyst Ir[III] by 1,4-dicyanobenzene (77) giving rise to the arene radical anion 80. The authors hypothesized that the resulting Ir[IV] would oxidize the enamine intermediate following deprotonation to yield the β-enamine radical 79. Subsequently, intermolecular radical–radical coupling occurs allowing the formation of intermediate 81, which then undergoes rapid elimination of cyanide and hydrolysis to the desired products. Later, the above-mentioned strategy was also expanded to the β-alkylation of aldehydes.55
Despite the advances in the field, several challenges and research topics remain: (1) the enantioselective photochemical reactions illustrated above are mainly based on the α-functionalization of aldehydes and ketones and the β-functionalization of enals and enones. It would be desirable to extend these protocols to other reactions types. (2) The chiral amine toolbox is not yet as versatile as the toolbox for thermal iminium and enamine catalysis and the development of novel and robust chiral amines is highly required. (3) Although some experimental data have been obtained, further theoretical and spectroscopic studies are required, which will help to understand the detailed mechanisms and guide the design of novel methods. (4) Applying the concepts described in this review to the total synthesis of some biologically important natural products and pharmaceuticals would be attractive and further work is expected along these lines.
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