Photoinduced C(sp3)–H sulfination empowers the direct and chemoselective introduction of the sulfonyl group

Direct installation of the sulfinate group by the functionalization of unreactive aliphatic C–H bonds can provide access to most classes of organosulfur compounds, because of the central position of sulfinates as sulfonyl group linchpins. Despite the importance of the sulfonyl group in synthesis, medicine, and materials science, a direct C(sp³)–H sulfination reaction that can convert abundant aliphatic C–H bonds to sulfinates has remained elusive, due to the reactivity of sulfinates that are incompatible with typical oxidation-driven C–H functionalization approaches. We report herein a photoinduced C(sp³)–H sulfination reaction that is mediated by sodium metabisulfite and enables access to a variety of sulfinates. The reaction proceeds with high chemoselectivity and moderate to good regioselectivity, affording only monosulfination products and can be used for a solvent-controlled regiodivergent distal C(sp³)–H functionalization.

The photoinduced C–H sulfination of abundant aliphatic C–H bonds provides direct access to all major classes of organosulfur compounds via the intermediacy of synthetically versatile sulfinate salts.     

Temperature-modulated selective C(sp3)–H or C(sp2)–H arylation through palladium catalysis

Transition metal-catalysed C–H bond functionalisations have been extensively developed in organic and medicinal chemistry. Among these catalytic approaches, the selective activation of C(sp³)–H and C(sp²)–H bonds is particularly appealing for its remarkable synthetic versatility, yet it remains highly challenging. Herein, we demonstrate the first example of temperature-dependent selective C–H functionalisation of unactivated C(sp³)–H or C(sp²)–H bonds at remote positions through palladium catalysis using 7-pyridyl-pyrazolo[1,5-a]pyrimidine as a new directing group. At 120 °C, C(sp³)–H arylation was triggered by the chelation of a rare [6,5]-fused palladacycle, whereas at 140 °C, C(sp²)–H arylation proceeded instead through the formation of a 16-membered tetramer containing four 7-pyridyl-pyrazolo[1,5-a]pyrimidine–palladium chelation units. The subsequent mechanistic study revealed that both C–H activations shared a common 6-membered palladacycle intermediate, which was then directly transformed to either the [6,5]-fused palladacycle for C(sp³)–H activation at 120 °C or the tetramer for C(sp²)–H arylation at 140 °C with catalytic amounts of Pd(OAc)₂ and AcOH. Raising the temperature from 120 °C to 140 °C can also convert the [6,5]-fused palladacycle to the tetramer with the above-mentioned catalysts, hence completing the C(sp²)–H arylation ultimately.

Unprecedented 16-membered tetramer or [6,5]-fused palladacycle, mutually shadowboxing-like transformed from the shared common intermediate, accomplishes the Pd-catalysed temperature-dependent selective arylation of C(sp²)–H or C(sp³)–H.     

Photoactive electron donor–acceptor complex platform for Ni-mediated C(sp3)–C(sp2) bond formation

A dual photochemical/nickel-mediated decarboxylative strategy for the assembly of C(sp³)–C(sp²) linkages is disclosed. Under light irradiation at 390 nm, commercially available and inexpensive Hantzsch ester (HE) functions as a potent organic photoreductant to deliver catalytically active Ni(0) species through single-electron transfer (SET) manifolds. As part of its dual role, the Hantzsch ester effects a decarboxylative-based radical generation through electron donor–acceptor (EDA) complex activation. This homogeneous, net-reductive platform bypasses the need for exogenous photocatalysts, stoichiometric metal reductants, and additives. Under this cross-electrophile paradigm, the coupling of diverse C(sp³)-centered radical architectures (including primary, secondary, stabilized benzylic, α-oxy, and α-amino systems) with (hetero)aryl bromides has been accomplished. The protocol proceeds under mild reaction conditions in the presence of sensitive functional groups and pharmaceutically relevant cores.

This works demonstrates the implementation of an electron donor–acceptor (EDA) complex platform toward Ni-catalyzed C(sp³)–C(sp²) bond formation, circumventing the need for exogenous photocatalysts, additives, and stoichiometric metal reductants.     

Silacyclization through palladium-catalyzed intermolecular silicon-based C(sp2)–C(sp3) cross-coupling

Silicon-based cross-coupling has been recognized as one of the most reliable alternatives for constructing carbon–carbon bonds. However, the employment of such reaction as an efficient ring expansion strategy for silacycle synthesis is comparatively little known. Herein, we develop the first intermolecular silacyclization strategy involving Pd-catalyzed silicon-based C(sp²)–C(sp³) cross-coupling. This method allows the modular assembly of a vast array of structurally novel and interesting sila-benzo[b]oxepines with good functional group tolerance. The key to success for this reaction is that silicon atoms have a stronger affinity for oxygen nucleophiles than carbon nucleophiles, and silacyclobutanes (SCBs) have inherent ring-strain-release Lewis acidity.

Herein, we develop the first silacyclization between 2-halophenols and SCBs, which allows the modular assembly of sila-benzo[b]oxepines with good functional group tolerance and can be applied for the late-stage modification of biologically active molecules.     

Merging C(sp3)–H activation with DNA-encoding

DNA-encoded library (DEL) technology has the potential to dramatically expedite hit identification in drug discovery owing to its ability to perform protein affinity selection with millions or billions of molecules in a few experiments. To expand the molecular diversity of DEL, it is critical to develop different types of DNA-encoded transformations that produce billions of molecules with distinct molecular scaffolds. Sequential functionalization of multiple C–H bonds provides a unique avenue for creating diversity and complexity from simple starting materials. However, the use of water as solvent, the presence of DNA, and the extremely low concentration of DNA-encoded coupling partners (0.001 M) have hampered the development of DNA-encoded C(sp³)–H activation reactions. Herein, we report the realization of palladium-catalyzed C(sp³)–H arylation of aliphatic carboxylic acids, amides and ketones with DNA-encoded aryl iodides in water. Notably, the present method enables the use of alternative sets of monofunctional building blocks, providing a linchpin to facilitate further setup for DELs. Furthermore, the C–H arylation chemistry enabled the on-DNA synthesis of structurally-diverse scaffolds containing enriched C(sp³) character, chiral centers, cyclopropane, cyclobutane, and heterocycles.

DNA-compatible C(sp³)–H activation reactions of aliphatic carboxylic acids, amides, and ketones were developed for efficient access to DEL synthesis.     

Ni(0)-promoted activation of Csp2–H and Csp2–O bonds

A dinickel(0)–N₂ complex, stabilized with a rigid acridane-based PNP pincer ligand, was studied for its ability to activate C(sp²)–H and C(sp²)–O bonds. Stabilized by a Ni–μ–N₂–Na⁺ interaction, it activates C–H bonds of unfunctionalized arenes, affording nickel–aryl and nickel–hydride products. Concomitantly, two sodium cations get reduced to Na(0), which was identified and quantified by several methods. Our experimental results, including product analysis and kinetic measurements, strongly suggest that this C(sp²)–H activation does not follow the typical oxidative addition mechanism occurring at a low-valent single metal centre. Instead, via a bimolecular pathway, two powerfully reducing nickel ions cooperatively activate an arene C–H bond and concomitantly reduce two Lewis acidic alkali metals under ambient conditions. As a novel synthetic protocol, nickel(ii)–aryl species were directly synthesized from nickel(ii) precursors in benzene or toluene with excess Na under ambient conditions. Furthermore, when the dinickel(0)–N₂ complex is accessed via reduction of the nickel(ii)–phenyl species, the resulting phenyl anion deprotonates a C–H bond of glyme or 15-crown-5 leading to C–O bond cleavage, which produces vinyl ether. The dinickel(0)–N₂ species then cleaves the C(sp²)–O bond of vinyl ether to produce a nickel(ii)–vinyl complex. These results may provide a new strategy for the activation of C–H and C–O bonds mediated by a low valent nickel ion supported by a structurally rigidified ligand scaffold.

A structurally rigidified nickel(0) complex was found to be capable of cleaving both C(sp²)–H and C(sp²)–O bonds.     

Exploring benzylic gem-C(sp3)–boron–silicon and boron–tin centers as a synthetic platform

A stepwise build-up of multi-substituted C_sp³ carbon centers is an attractive, conceptually simple, but often synthetically challenging type of disconnection. To this end, this report describes how gem-α,α-dimetalloid-substituted benzylic reagents bearing boron/silicon or boron/tin substituent sets are an excellent stepping stone towards diverse substitution patterns. These gem-dimetalloids were readily accessed, either by known carbenoid insertion into C–B bonds or by the newly developed scalable deprotonation/metallation approach. Highly chemoselective transformations of either the C–Si (or C–Sn) or the C–B bonds in the newly formed gem-C_sp³ centers have been achieved through a set of approaches, with a particular focus on exploiting the synthetically versatile polarity reversal in organometalloids by λ³-aryliodanes. Of particular note is the metal-free arylation of the C–Si (or C–Sn) bonds in such gem-dimetalloids via the iodane-guided C–H coupling approach. DFT calculations show that this transfer of the (α-Bpin)benzyl group proceeds via unusual [5,5]-sigmatropic rearrangement and is driven by the high-energy iodine(iii) center. As a complementary tool, the gem-dimetalloid C–B bond is shown to undergo a potent and chemoselective Suzuki–Miyaura arylation with diverse Ar–Cl, thanks to the development of the reactive gem-α,α-silyl/BF₃K building blocks.

This work explores divergent reactivity of the benzylic gem-boron–silicon and boron–tin double nucleophiles, including the arylation of the C–B bond with Ar–Cl, along with a complementary oxidative λ³-iodane-guided arylation of the C–Si/Sn moiety.     

Correction: Iridium-catalyzed enantioselective olefinic C(sp2)–H allylic alkylation

The first iridium-catalyzed enantioselective olefinic C(sp²)–H allylic alkylation is developed in cooperation with Lewis base catalysis. This reaction, catalyzed by cinchonidine and an in situ generated cyclometalated Ir(i)/phosphoramidite complex, makes use of the latent enolate character of an α,β-unsaturated carbonyl compound, namely coumalate ester, to introduce an allyl group at its α-position in a branched-selective manner in moderate to good yield with good to excellent enantioselectivities (up to 98 : 2 er).

The first iridium-catalyzed enantioselective allylic alkylation of an olefinic C(sp²)–H bond – that of an α,β-unsaturated carbonyl compound, is developed in cooperation with Lewis base catalysis.     

Palladium-catalyzed benzylic C(sp3)–H carbonylative arylation of azaarylmethyl amines with aryl bromides

A highly selective palladium-catalyzed carbonylative arylation of weakly acidic benzylic C(sp³)–H bonds of azaarylmethylamines with aryl bromides under 1 atm of CO gas has been achieved. This work represents the first examples of use of such weakly acidic pronucleophiles in this class of transformations. In the presence of a NIXANTPHOS-based palladium catalyst, this one-pot cascade process allows a range of azaarylmethylamines containing pyridyl, quinolinyl and pyrimidyl moieties and acyclic and cyclic amines to undergo efficient reactions with aryl bromides and CO to provide α-amino aryl-azaarylmethyl ketones in moderate to high yields with a broad substrate scope and good tolerance of functional groups. This reaction proceeds via in situ reversible deprotonation of the benzylic C–H bonds to give the active carbanions, thereby avoiding prefunctionalized organometallic reagents and generation of additional waste. Importantly, the operational simplicity, scalability and diversity of the products highlight the potential applicability of this protocol.

Introduced is a method for the deprotonative carbonylation of azaarylmethyl amines with aryl bromides. The reaction employs a Pd(NIXANTPHOS)-based catalyst and takes place under 1 atm CO.     

Carbon–carbon bond activation by B(OMe)3/B2pin2-mediated fragmentation borylation

Selective carbon–carbon bond activation is important in chemical industry and fundamental organic synthesis, but remains challenging. In this study, non-polar unstrained Csp²–Csp³ and Csp²–Csp² bond activation was achieved by B(OMe)₃/B₂pin₂-mediated fragmentation borylation. Various indole derivatives underwent C2-regioselective C–C bond activation to afford two C–B bonds under transition-metal-free conditions. Preliminary mechanistic investigations suggested that C–B bond formation and C–C bond cleavage probably occurred in a concerted process. This new reaction mode will stimulate the development of reactions based on inert C–C bond activation.

Non-polar unstrained Csp²–Csp³ and Csp²–Csp² bond activation was achieved via B(OMe)₃/B₂pin₂-mediated fragmentation borylation, in which C–C bond activation occurred regioselectively at the C2-position in various substituted indoles.     

Electrochemically selective double C(sp2)–X (X = S/Se,N) bond formation of isocyanides

The construction of C(sp²)–X (X = B, N, O, Si, P, S, Se, etc.) bonds has drawn growing attention since heteroatomic compounds play a prominent role from biological to pharmaceutical sciences. The current study demonstrates the C(sp²)–S/Se and C(sp²)–N bond formation of one carbon of isocyanides with thiophenols or disulfides or diselenides and azazoles simultaneously. The reported findings could provide access to novel multiple isothioureas, especially hitherto rarely reported selenoureas. The protocol showed good atom-economy and step-economy with only hydrogen evolution and theoretical calculations accounted for the stereoselectivity of the products. Importantly, the electrochemical reaction could exclusively occur at the isocyano part regardless of the presence of susceptible radical acceptors, such as a broad range of arenes and alkynyl moieties, even alkenyl moieties.

We have developed an efficient and sustainable electrochemical strategy for the double C(sp²)–X (S/Se, N) bond formation of isocyanides simultaneously. A series of novel isothio/selenoureas were obtained via a three-component cross-coupling.

The construction of C(sp²)–X (X = B, N, O, Si, P, S, Se, etc.) bonds has drawn increased attention from researchers since heteroatomic compounds play a prominent role in various fields.¹ Traditionally, the transition-metal-catalyzed cross-coupling of a nucleophile and an electrophile is an important method for the formation of C(sp²)–X bonds.² Obviously, the direct cross-coupling of C(sp²)–H/X–H is a time-, effort-, and resource-economical process to construct C(sp²)–X bonds as it avoids the pre-functionalization of substrates.³ Alternatively, radical chemistry provides greener and more mild strategies for the formation of C(sp²)–X bonds, and a variety of high added-value compounds can be afforded successfully.⁴ Despite the numerous advances, these reported reactions are limited as they involve only single C(sp²)–X bond formation. Access to double C(sp²)–X bonds formation of one carbon remains still a room for improvement stimultaneously.As an ideal connector, isocyanides could be inserted into metal–carbon and metal–heteroatom bonds to construct double C(sp²)–X bonds.⁵ On the other hand, isocyanides could transform into heteroatomic molecules with electrophiles, nucleophiles and radicals.⁶ Although many elegant studies have been reported, the above methods are largely limited by the pre-functionalization of the substrate, the toxicity of metals or tedious synthesis steps. From the point of synthetic efficiency and economy, exploiting a novel, efficient, and diverse radical strategy to access double C(sp²)–X bonds under mild conditions and with broad functional group tolerance is of paramount importance and in urgent demand.Radical transformation processes are ubiquitous throughout synthesis chemistry and provide new ideas for forging new bonds and novel molecules, especially valuable product motifs.⁷ As a complementary strategy to conventional radical-based reactions, electrochemistry, effectively transferring electrons from the electrode surface to the substance, has been developed into a powerful synthetic technique toward radical chemistry.⁸ This electrochemical strategy further stimulated a resurgence of interest in radical chemistry with good atom-economy and step-economy.⁹ Myriad electrochemical-induced radical reactions have been reported via single-electron oxidation/reduction with a plethora of radicals and radical acceptors. As reported, alkenes, alkynes, and cyano and aromatic compounds could be considered to be favorable radical acceptors in diverse transformations, such as cross-coupling, cyclization and difunctionalization reactions.¹⁰ However, the application of isocyanides as radical acceptors is limited in utility due to electrochemical tandem cyclization.¹¹ Therefore, on the basis of our research on electrochemical oxidative functionalization of isocyanides,¹² we continued to explore the properties of isocyanides as radical acceptors under electrochemical conditions.Initially, we commenced our investigations by using abundant and inexpensive phenyl disulfide (1), ethyl 2-isocyanoacetate (2) and 1H-benzo[d][1,2,3]triazole (3) as model substrates in a single operation via a three-component cross-coupling. After systematic optimization, the isothiourea 21 could been obtained in 90% isolated yield. To gain insights into the reaction process, we continued to carry out a series of control experiments as shown in Scheme 1. The control experiment demonstrated that electricity is indispensable. Under standard conditions, addition of 2.0 equivalents of 2,2,6,6-tetramethyl-1-piperidinyloxy (TEMPO) showed no traces of product. Similarly, the reaction was suppressed in the presence of butylated hydroxytoluene (BHT). The P(OEt)₃-trapping product could be detected by gas chromatography mass spectrometry (GCMS). Simultaneously, a S-centred radical signal (g = 2.0070, AN = 13.40 G, AH = 14.88 G) was quickly trapped by 5,5-dimethyl-1-pyrroline N-oxide (DMPO) via electron paramagnetic resonance (EPR) experiments. The reported results revealed that this reaction might proceed via S-radical pathways.Open in a separate windowScheme 1Control experiments.For deeper research of the priority of interaction for isocyanides vs. other radical acceptors with radicals, we sought to conduct robustness screening of a wide range of radical acceptors as shown in Scheme 2.¹³ The addition of an aryl olefin led to the complete shutdown of product formation (21) and the products of difunctionalization of alkenes were also not detected. To our delight, the alkenyl moiety did not affect the reaction efficiency under the electrochemical conditions. Unlike the aryl olefin, the addition of phenylacetylene did not inhibit product formation (21), delivering a yield of 93%. Similarly, ethyl 2-isocyanoacetate could be transformed into product (21) smoothly with 1-heptyne. The addition of mesitylene preserved the yield, while the yield decreased slightly with anisole. With the addition of furan and thiophene, an excellent yield of product (21) could still be obtained. Beside electron-donating arenes, we continued to add electron-withdrawing arenes to the reaction system. As expected, a satisfactory yield was obtained with 4-cyanopyridine. The results revealed that the electrochemical reaction exclusively occurred at the isocyano part regardless of the presence of electron-withdrawing arenes, electron-donating arenes and the alkynyl moiety, even the alkenyl moiety, which are also susceptible to radical conditions.Open in a separate windowScheme 2Competitive experiments of isocyanides vs. other radical acceptors with radicals. Conditions: 1 (0.15 mmol), 2 (0.6 mmol), 3 (0.5 mmol), R. A. = radical acceptors (0.6 mmol), ⁿBu₄NBF₄ (0.5 mmol), MeCN (6 mL), cloth anode, Pt cathode, undivided cell, constant current = 10 mA, room temperature, N₂, 2.25 h. ¹HNMR yield, dibromomethane as an internal standard.In order to further investigate the compatibility, we firstly examined the substrate scope of alkyl disulfides for the synthesis of isothioureas with ethyl 2-isocyanoacetate (2) and 1H-benzo[d][1,2,3]triazole (3) as shown in Scheme 3. To our delight, the yields did not decrease significantly with the increase of the carbon chain from methyl to decyl in this transformation (4–7). Isopropyl, isobutyl, cyclopentyl and cyclohexyl were well tolerated with good to excellent yields (8–11). Substances, containing sensitive benzylic C–H bonds, were tolerated to access novel isothioureas in this electrochemical induced-radical process (12–14, 34). Afterwards, we continued to explore the applicability from alkyl disulfides to thiophenol and a series of molecule isothioureas were obtained successfully with satisfactory yield. Thiophenol, containing electron-neutral (F, Cl, Br, H), electron-withdrawing (OCF₃, CF₃, and CO₂Me) and electron-donating (Me, Et, ^tBu, OMe, and SMe) groups, could smoothly transform to realize this process with high stereoselectivity under mild conditions (15–26). The structure of Z-conformer (16) was confirmed by X-ray crystallographic analysis. In addition, this protocol was successfully applied to thiophenols bearing diverse groups at different positions with good yields, indicating that steric hindrance has no obvious effect (20, 27–31). With curiosity, we tried to evaluate the tolerance of diselenides to construct novel Se–C–N bonds simultaneously. Unexpectedly, regardless of alkyl diselenides (32–33), benzyl diselenide (34) or aryl diselenide (35), all were well tolerated under electrochemical conditions, providing a series of unprecedented isoselenoureas, which were inaccessible by conventional methods. The compatibility of sensitive functional groups provides an opportunity for further molecular modification. The sensitive functional architectures including but not limited to ester (36), benzyloxy (37), allyl and allyloxy as well as endene (38, 41–44), labile alkyl chloride (39) and alkyl bromide (40), propargyl (44), and thiophene (45), all remained intact, enriching the diversity of heteroatom compounds. The merit of this methodology was further demonstrated by elaboration of a wide gamut of functional molecules and drug molecules to diverse isothioureas. Natural products including l-menthol and geraniol (46–47), food additives including isopulegol and furfuryl alcohol (48–49), and pharmaceuticals including ibuprofen (50) were apt to give rise to the corresponding isothioureas in 50–78% yields.Open in a separate windowScheme 3Scope of thiophenols/disulfides/diselenides. Conditions: ^a disulfides/diselenides (0.15 mmol) or ^b thiophenols (0.3 mmol), isocyanides (0.6 mmol), 1H-benzotriazole (0.5 mmol), ⁿBu₄NBF₄ (0.5 mmol), MeCN (6 mL), cloth anode, Pt cathode, undivided cell, constant current = 10 mA, room temperature, N₂, 2.25 h. Isolated yield.After defining the scope of thiophenols and disulfides, we turned our attention to explore the substrate scope with respect to nucleophiles in Scheme 4. Benzotriazole, with mono-substitution or multi-substitution, could be efficiently converted to the corresponding skeletons in 55–75% yields (51–54). Under standard conditions, pyrazole also showed great reactivity with phenyl disulfide or ethyl disulfide (55–56). The introduction of a halogen group in pyrazolylcycle, especially a subtle C–I bond, was compatible with satisfactory results (57–59, 64–65). 4-Methyl-1H-pyrazole as a coupling partner also realized the aminosulfenylation of isocyanide, albeit less efficiently (62). Of note is that the yield was increased to 70% from 40% by replacing methyl with phenyl (63). In addition to benzotriazole and pyrazole derivatives, other triazoles and tetrazole were proved to be viable coupling partners as well, enabling access to the target products in synthetically useful yields (66–70). Subsequently, with this established-optimized condition, we set out to investigate substrates for isocyanide coupling partners. With methyl isocyanoacetate (71), a similar effect was observed in an electrochemical difunctionalization reaction. As expected, both tosylmethyl isocyanide and benzyl isocyanide were demonstrated to be competent substrates (72–73). Cyclohexyl isocyanide, as a representative of secondary isocyanides, converted into the corresponding product (74). Gratifyingly, isocyanides, regardless of the steric effect, could engage with thiophenols to give the corresponding adducts in good yields (75–76). Aryl isocyanides however afforded the desired products in low yields under standard reaction conditions (77–78).Open in a separate windowScheme 4Scope of azazoles. Conditions: ^a disulfides/diselenides (0.15 mmol) or ^b thiophenols (0.3 mmol), isocyanides (0.6 mmol), azazoles (0.5 mmol), ⁿBu₄NBF₄ (0.5 mmol), MeCN (6 mL), cloth anode, Pt cathode, undivided cell, constant current = 10 mA, room temperature, N₂, 2.25 h. Isolated yield.To evaluate the feasibility of this electrochemical protocol, we monitored the reaction on a 4.5 mmol scale as shown in Scheme 5. Under similar conditions, by prolonging the reaction time to 34 h, a good isolated yield of 72% was obtained, which provided an opportunity for further synthetic manipulations.Open in a separate windowScheme 5Gram-scale synthesis.In order to account for the stereoselectivity of products, theoretical calculations were performed. The result demonstrated that the free energy of the Z-conformer of the product 16 is 2.3 kcal mol⁻¹ smaller than that of the E-conformer.Based on a previously reported mechanistic study¹⁴ and these above observations, a synthetically possible mechanism for the electrochemical intermolecular difunctionalization reaction is depicted in Scheme 6. A sulfur radical was formed via single-electron-transfer (SET) reduction of the disulfide or SET oxidation of the thiophenol. Subsequently, the exclusive capture of the S-radical by the isocyano part yields the imine C-radical I. Further SET oxidation of this radical intermediate to the corresponding imine carbocation II, followed by nucleophilic trapping intermolecularly, affords the final isothioureas.Open in a separate windowScheme 6Proposed reaction mechanism.     

Visible light driven deuteration of formyl C–H and hydridic C(sp3)–H bonds in feedstock chemicals and pharmaceutical molecules

Deuterium labelled compounds are of significant importance in chemical mechanism investigations, mass spectrometric studies, diagnoses of drug metabolisms, and pharmaceutical discovery. Herein, we report an efficient hydrogen deuterium exchange reaction using deuterium oxide (D₂O) as the deuterium source, enabled by merging a tetra-n-butylammonium decatungstate (TBADT) hydrogen atom transfer photocatalyst and a thiol catalyst under light irradiation at 390 nm. This deuteration protocol is effective with formyl C–H bonds and a wide range of hydridic C(sp³)–H bonds (e.g. α-oxy, α-thioxy, α-amino, benzylic, and unactivated tertiary C(sp³)–H bonds). It has been successfully applied to the high incorporation of deuterium in 38 feedstock chemicals, 15 pharmaceutical compounds, and 6 drug precursors. Sequential deuteration between formyl C–H bonds of aldehydes and other activated hydridic C(sp³)–H bonds can be achieved in a selective manner.

A selective hydrogen deuterium exchange reaction with formyl C–H bonds and a wide range of hydridic C(sp³)–H bonds has been achieved by merging tetra-n-butylammonium decatungstate photocatalyst and a thiol catalyst under 390 nm light irradiation.     

Pd-catalyzed cross-electrophile Coupling/C–H alkylation reaction enabled by a mediator generated via C(sp3)–H activation

Transition-metal-catalyzed cross-electrophile C(sp²)–(sp³) coupling and C–H alkylation reactions represent two efficient methods for the incorporation of an alkyl group into aromatic rings. Herein, we report a Pd-catalyzed cascade cross-electrophile coupling and C–H alkylation reaction of 2-iodo-alkoxylarenes with alkyl chlorides. Methoxy and benzyloxy groups, which are ubiquitous functional groups and common protecting groups, were utilized as crucial mediators via primary or secondary C(sp³)–H activation. The reaction provides an innovative and convenient access for the synthesis of alkylated phenol derivatives, which are widely found in bioactive compounds and organic functional materials.

A cascade Pd-catalyzed cross-electrophile coupling and C–H alkylation reaction of 2-iodo-alkoxylarenes with alkyl chlorides has been developed by using an ortho-methoxy or benzyloxy group as a mediator via C(sp³)–H activation.     

Selective propargylic C(sp3)–H activation of methyl-substituted alkynes versus [2 + 2] cycloaddition at a titanium imido template

The reaction of the titanium imido complex 1b with 2-butyne leads to the formation of the titanium azadiene complex 2a at ambient temperature instead of yielding the archetypical [2 + 2] cycloaddition product (titanaazacyclobutene) which is usually obtained by combining titanium imido complexes and internal alkynes. The formation of 2a is presumably caused by an initial propargylic C(sp³)–H activation step and quantum chemical calculations suggest that the outcome of this unexpected reactivity is thermodynamically favored. The previously reported titanaazacyclobutene I (which is obtained by reacting 1b with 1-phenyl-1-propyne) undergoes a rearrangement reaction at elevated temperature to give the corresponding five-membered titanium azadiene complex 2b.

An unexpected reactivity between a titanium imido complex and internal alkynes was unveiled yielding titanaazacyclobutenes instead of the expected [2 + 2] cycloaddition products.     

Palladium-catalyzed direct asymmetric C–H bond functionalization enabled by the directing group strategy

In the past decade, selective C–C and C-heteroatom bond construction through palladium-catalyzed direct C–H bond functionalization has been extensively studied by employing a variety of directing groups. Within this category, direct asymmetric C(sp²)–H and C(sp³)–H activation for the construction of highly enantiomerically enriched skeletons still progressed at a slow pace. This minireview briefly introduces the major advances in the field for palladium-catalyzed direct asymmetric C–H bond functionalization via the directing group strategy.

This minireview introduces Pd-catalyzed direct asymmetric C–H functionalization reactions using a directing group strategy.     

Magnesium-mediated sp3 C–H activation in cascade cyclization of 1-arylethynyl-2-alkyl-o-carboranes: efficient synthesis of carborane-fused cyclopentanes

This work reports an unprecedented cascade cyclization of 1-arylethynyl-2-alkyl-o-carboranes promoted by magnesium-mediated sp³ C–H activation. Treatment of 1-arylethynyl-2-alkyl-o-carboranes with MeMgBr gives a series of carborane-fused cyclopentanes in very good yields. Deuterium labelling and control experiments suggest that HMgBr, resulting in situ from the nucleophilic substitution of cage B–H bonds with Grignard reagent, initiates the reaction, in which magnesium-promoted intramolecular sp³ C–H activation serves as a key step. This work not only offers a new route for the synthesis of carborane-fused cyclopentanes, but also sheds some light on Mg-mediated C–H activation and functionalization.

An unprecedented cascade cyclization of 1-arylethynyl-2-alkyl-o-carboranes with Grignard reagent for synthesizing carborane-fused cyclopentanes has been disclosed, in which magnesium-mediated intramolecular sp³ C–H activation serves as a key step.     

Benzylic C(sp3)–C(sp2) cross-coupling of indoles enabled by oxidative radical generation and nickel catalysis

A mechanistically unique functionalization strategy for a benzylic C(sp³)–H bond has been developed based on the facile oxidation event of indole substrates. This novel pathway was initiated by efficient radical generation at the benzylic position of the substrate, with subsequent transition metal catalysis to complete the overall transformation. Ultimately, an aryl or an acyl group could be effectively delivered from an aryl (pseudo)halide or an acid anhydride coupling partner, respectively. The developed method utilizes mild conditions and exhibits a wide substrate scope for both substituted indoles and C(sp²)-based reaction counterparts. Mechanistic studies have shown that competitive hydrogen atom transfer (HAT) processes, which are frequently encountered in conventional methods, are not involved in the product formation process of the developed strategy.

A mechanistically distinct Ni-catalysed benzylic functionalization of indoles is developed by the facile oxidation of arenes. The method exhibits a wide substrate scope and pronounced chemoselectivity that cannot be accessed via known protocols.     

Diverse strategies for transition metal catalyzed distal C(sp3)–H functionalizations

Transition metal catalyzed C(sp³)–H functionalization is a rapidly growing field. Despite severe challenges, distal C–H functionalizations of aliphatic molecules by overriding proximal positions have witnessed tremendous progress. While usage of stoichiometric directing groups played a crucial role, reactions with catalytic transient directing groups or methods without any directing groups are gaining more attention due to their practicality. Various innovative strategies, slowly but steadily, circumvented issues related to remote functionalizations of aliphatic molecules. A systematic compilation has been presented here to provide insights into the recent developments and future challenges in the field. The Present perspective is expected to open up a new dimension and provide an avenue for deep insights into the distal C(sp³)–H functionalizations that could be applied routinely in various pharmaceutical and agrochemical industries.

Transition metal catalyzed C(sp³)–H functionalization is a rapidly growing field.     

Synthesis of α-Quaternary β-Lactams via Copper-Catalyzed Enantioconvergent Radical C(sp3)−C(sp2) Cross-Coupling with Organoboronate Esters

The copper-catalyzed enantioconvergent radical C(sp³)−C(sp²) cross-coupling of tertiary α-bromo-β-lactams with organoboronate esters could provide the synthetically valuable α-quaternary β-lactams. The challenge arises mainly from the construction of sterically congested quaternary stereocenters between the tertiary alkyl radicals and chiral copper(II) species. Herein, we describe our success in achieving such transformations through the utilization of a copper/hemilabile N,N,N-ligand catalyst to forge the sterically congested chiral C(sp³)−C(sp²) bond via a single-electron reduction/transmetalation/bond formation catalytic cycle. The synthetic potential of this approach is shown in the straightforward conversion of the corresponding products into many valuable building blocks. We hope that the developed catalytic cycle would open up new vistas for more enantioconvergent cross-coupling reactions.     

The Emergence of Palladium-Catalyzed C(sp3)−H Functionalization of Free Carboxylic Acids

Palladium-catalyzed directing group assisted C−H bond activation has emerged as a powerful tool in synthetic organic chemistry. However, only recently, among various directing groups, widely available carboxylate moiety is recognized as a versatile candidate for the regioselective transformations. Notably, palladium-catalyzed carboxylate directed C(sp³)−H bond activation and diverse functionalization is highly challenging and has gained huge attention for its versatile applications. Mono- and bidentate ligands have proven to be useful for accelerating the C(sp³)−H bond activation step, which helps to control reactivity and selectivity (including enantioselectivity). In this Minireview, we discuss the recent progress made in palladium-catalyzed C(sp³)−H bond functionalization reactions for the construction of C−C and C−Heteroatom bonds with the direction of free carboxylic acid.