Copper‐Catalyzed Site‐Selective Intramolecular Amidation of Unactivated C(sp3)H Bonds

The intramolecular dehydrogenative amidation of aliphatic amides, directed by a bidentate ligand, was developed using a copper‐catalyzed sp³ C? H bond functionalization process. The reaction favors predominantly the C? H bonds of β‐methyl groups over the unactivated methylene C? H bonds. Moreover, a preference for activating sp³ C? H bonds of β‐methyl groups, via a five‐membered ring intermediate, over the aromatic sp² C? H bonds was also observed in the cyclometalation step. Additionally, sp³ C? H bonds of unactivated secondary sp³ C? H bonds could be functionalized by favoring the ring carbon atoms over the linear carbon atoms.     

Copper‐Catalyzed Site‐Selective Intramolecular Amidation of Unactivated C(sp3)?H Bonds

The intramolecular dehydrogenative amidation of aliphatic amides, directed by a bidentate ligand, was developed using a copper‐catalyzed sp³ C H bond functionalization process. The reaction favors predominantly the C H bonds of β‐methyl groups over the unactivated methylene C H bonds. Moreover, a preference for activating sp³ C H bonds of β‐methyl groups, via a five‐membered ring intermediate, over the aromatic sp² C H bonds was also observed in the cyclometalation step. Additionally, sp³ C H bonds of unactivated secondary sp³ C H bonds could be functionalized by favoring the ring carbon atoms over the linear carbon atoms.     

Copper‐Promoted Site‐Selective Acyloxylation of Unactivated C(sp3)H Bonds

The site‐selective acyloxylation of aliphatic amides was achieved via a copper‐promoted C(sp³)? H bond functionalization process directed by a bidentate ligand. The reaction showed a great preference for activating C? H bonds of β‐methyl groups over those of γ‐methyl and unactivated methylene groups.     

Site‐Selective δ‐C(sp3)−H Alkylation of Amino Acids and Peptides with Maleimides via a Six‐Membered Palladacycle

The site‐selective functionalization of unactivated C(sp³)?H bonds remains one of the greatest challenges in organic synthesis. Herein, we report on the site‐selective δ‐C(sp³)?H alkylation of amino acids and peptides with maleimides via a kinetically less favored six‐membered palladacycle in the presence of more accessible γ‐C(sp³)?H bonds. Experimental studies revealed that C?H bond cleavage occurs reversibly and preferentially at γ‐methyl over δ‐methyl C?H bonds while the subsequent alkylation proceeds exclusively at the six‐membered palladacycle that is generated by δ‐C?H activation. The selectivity can be explained by the Curtin–Hammett principle. The exceptional compatibility of this alkylation with various oligopeptides renders this procedure valuable for late‐stage peptide modifications. Notably, this process is also the first palladium(II)‐catalyzed Michael‐type alkylation reaction that proceeds through C(sp³)?H activation.     

Access to β‐Lactams by Enantioselective Palladium(0)‐Catalyzed C(sp3)H Alkylation

β‐Lactams are very important structural motifs because of their broad biological activities as well as their propensity to engage in ring‐opening reactions. Transition‐metal‐catalyzed C? H functionalizations have emerged as strategy enabling yet uncommon highly efficient disconnections. In contrast to the significant progress of Pd⁰‐catalyzed C? H functionalization for aryl–aryl couplings, related reactions involving the formation of saturated C(sp³)? C(sp³) bonds are elusive. Reported here is an asymmetric C? H functionalization approach to β‐lactams using readily accessible chloroacetamide substrates. Important aspects of this transformation are challenging C(sp³)? C(sp³) and strain‐building reductive eliminations to for the four‐membered ring. In general, the β‐lactams are formed in excellent yields and enantioselectivities using a bulky taddol phosphoramidite ligand in combination with adamantyl carboxylic acid as cocatalyst.     

Practical Synthesis of anti‐β‐Hydroxy‐α‐Amino Acids by PdII‐Catalyzed Sequential C(sp3)H Functionalization

An improved and practical procedure for the stereoselective synthesis of anti‐β‐hydroxy‐α‐amino acids (anti‐βhAAs), by palladium‐catalyzed sequential C(sp³)?H functionalization directed by 8‐aminoquinoline auxiliary, is described. followed by a previously established monoarylation and/or alkylation of the β‐methyl C(sp³)?H of alanine derivative, β‐acetoxylation of both alkylic and benzylic methylene C(sp³)?H bonds affords various anti‐β‐hydroxy‐α‐amino acid derivatives. As an example, the synthesis of β‐mercapto‐α‐amino acids, which are highly important to the extension of native chemical ligation chemistry beyond cysteine, is described. The synthetic potential of this protocol is further demonstrated by the synthesis of diverse β‐branched α‐amino acids. The observed diastereoselectivities are strongly influenced by electronic effects of aromatic AAs and steric effects of the linear side‐chain AAs, which could be explained by the competition of intramolecular C?OAc bond reductive elimination from Pd^IV intermediates vs. intermolecular attack by an external nucleophile (AcO^?) in an S_N2‐type process.     

Merging Photochemistry with Electrochemistry: Functional‐Group Tolerant Electrochemical Amination of C(sp3)−H Bonds

Direct amination of C(sp³)?H bonds is of broad interest in the realm of C?H functionalization because of the prevalence of nitrogen heterocycles and amines in pharmaceuticals and natural products. Reported here is a combined electrochemical/photochemical method for dehydrogenative C(sp³)?H/N?H coupling that exhibits good reactivity with both sp² and sp³ N?H bonds. The results show how use of iodide as an electrochemical mediator, in combination with light‐induced cleavage of intermediate N?I bonds, enables the electrochemical process to proceed at low electrode potentials. This approach significantly improves the functional‐group compatibility of electrochemical C?H amination, for example, tolerating electron‐rich aromatic groups that undergo deleterious side reactions in the presence of high electrode potentials.     

Functionalization of C‐H Bonds by Photoredox Catalysis

Visible‐light photoredox catalysis has been successfully used in the functionalization of inert C?H bonds including C(sp²)‐H bonds of arenes and C(sp³)‐H bonds of aliphatic compounds over the past decade. These transformations are typically promoted by the process of single‐electron‐transfer (SET) between substrates and photo‐excited photocatalyst upon visible light irradiation (household bulbs or LEDs). Compared with other synthetic strategies, such as the transition‐metal catalysis and traditional radical reactions, visible‐light photoredox approach has distinct advantages in terms of operational simplicity and practicability. Versatile direct functionalization of inert C(sp²)‐H and C(sp³)‐H bonds including alkylation, trifluoromethylation, arylation and amidation, has been achieved using this practical strategy.     

Complementary Strategies for Directed C(sp3)−H Functionalization: A Comparison of Transition‐Metal‐Catalyzed Activation,Hydrogen Atom Transfer,and Carbene/Nitrene Transfer

The functionalization of C(sp³)?H bonds streamlines chemical synthesis by allowing the use of simple molecules and providing novel synthetic disconnections. Intensive recent efforts in the development of new reactions based on C?H functionalization have led to its wider adoption across a range of research areas. This Review discusses the strengths and weaknesses of three main approaches: transition‐metal‐catalyzed C?H activation, 1,n‐hydrogen atom transfer, and transition‐metal‐catalyzed carbene/nitrene transfer, for the directed functionalization of unactivated C(sp³)?H bonds. For each strategy, the scope, the reactivity of different C?H bonds, the position of the reacting C?H bonds relative to the directing group, and stereochemical outcomes are illustrated with examples in the literature. The aim of this Review is to provide guidance for the use of C?H functionalization reactions and inspire future research in this area.     

Nickel‐Catalyzed Alkoxy–Alkyl Interconversion with Alkylborane Reagents through C−O Bond Activation of Aryl and Enol Ethers

A nickel‐catalyzed alkylation of polycyclic aromatic methyl ethers as well as methyl enol ethers with B‐alkyl 9‐BBN and trialkylborane reagents that involves the cleavage of stable C(sp²)?OMe bonds is described. The transformation has a wide substrate scope and good chemoselectivity profile while proceeding under mild reaction conditions; it provides a versatile way to form C(sp²)?C(sp³) bonds that does not suffer from β‐hydride elimination. Furthermore, a selective and sequential alkylation process by cleavage of inert C?O bonds is presented to demonstrate the advantage of this method.     

Sulfonamide‐Promoted Palladium(II)‐Catalyzed Alkylation of Unactivated Methylene C(sp3)H Bonds with Alkyl Iodides

The alkylation of unactivated β‐methylene C(sp³)? H bonds of α‐amino acid substrates with a broad range of alkyl iodides using Pd(OAc)₂ as the catalyst is described. The addition of NaOCN and 4‐Cl‐C₆H₄SO₂NH₂ was found to be crucial for the success of this transformation. The reaction is compatible with a diverse array of functional groups and proceeds with high diastereoselectivity. Furthermore, various β,β‐hetero‐dialkyl‐ and β‐alkyl‐β‐aryl‐α‐amino acids were prepared by sequential C(sp³)? H functionalization of an alanine‐derived substrate, thus providing a versatile strategy for the stereoselective synthesis of unnatural β‐disubstituted α‐amino acids.     

Copper‐Catalyzed C(sp3)−H Amidation: Sterically Driven Primary and Secondary C−H Site‐Selectivity

Undirected C(sp³)?H functionalization reactions often follow site‐selectivity patterns that mirror the corresponding C?H bond dissociation energies (BDEs). This often results in the functionalization of weaker tertiary C?H bonds in the presence of stronger secondary and primary bonds. An important, contemporary challenge is the development of catalyst systems capable of selectively functionalizing stronger primary and secondary C?H bonds over tertiary and benzylic C?H sites. Herein, we report a Cu catalyst that exhibits a high degree of primary and secondary over tertiary C?H bond selectivity in the amidation of linear and cyclic hydrocarbons with aroyl azides ArC(O)N₃. Mechanistic and DFT studies indicate that C?H amidation involves H‐atom abstraction from R‐H substrates by nitrene intermediates [Cu](κ²‐N,O‐NC(O)Ar) to provide carbon‐based radicals R^. and copper(II)amide intermediates [Cu^II]‐NHC(O)Ar that subsequently capture radicals R^. to form products R‐NHC(O)Ar. These studies reveal important catalyst features required to achieve primary and secondary C?H amidation selectivity in the absence of directing groups.     

Regioselective Vinylation of Remote Unactivated C(sp3)−H Bonds: Access to Complex Fluoroalkylated Alkenes

Regioselective incorporation of a particular functional group into aliphatic sites by direct activation of unreactive C?H bonds is of great synthetic value. Despite advances in radical‐mediated functionalization of C(sp³)?H bonds by a hydrogen‐atom transfer process, the site‐selective vinylation of remote C(sp³)?H bonds still remains underexplored. Reported herein is a new protocol for the regioselective vinylation of unactivated C(sp³)?H bonds. The remote C(sp³)?H activation is promoted by a C‐centered radical instead of the commonly used N and O radicals. The reaction possesses high product diversity and synthetic efficiency, furnishing a plethora of synthetically valuable E alkenes bearing tri‐/di‐/mono‐fluoromethyl and perfluoroalkyl groups.     

Silver‐Mediated Intermolecular 1,2‐Alkylarylation of Styrenes with α‐Carbonyl Alkyl Bromides and Indoles

A new iron‐facilitated silver‐mediated radical 1,2‐alkylarylation of styrenes with α‐carbonyl alkyl bromides and indoles is described, and two new C?C bonds were generated in a single step through a sequence of intermolecular C(sp³)?Br functionalization and C(sp²)?H functionalization across the alkenes. This method provides an efficient access to alkylated indoles with broad substrate scope and excellent selectivity.     

Nickel,Cobalt and Palladium Catalysed C−H Functionalization of Un‐Activated C(sp3)−H Bond

This review represents nickel, cobalt and palladium catalyzed C?H activation of sp³ carbon, with special emphasis on methyl C?H activation. The importance of directing group assistance and effect of ligand on β‐ or γ‐ C(sp³)?H activation is summarized in this review. The mechanistic study for Ni, Co and Pd catalyzed sp³ C?H bond functionalization also discussed in detail.     

Easily Accessible Auxiliary for Palladium‐Catalyzed Intramolecular Amination of C(sp2)H and C(sp3)H Bonds at δ‐ and ε‐Positions

An easily synthesized and accessible N,O‐bidentate auxiliary has been developed for selective C? H activation under palladium catalysis. The novel auxiliary showed its first powerful application in C? H functionalization of remote positions. Both C(sp²)? H and C(sp³)? H bonds at δ‐ and ε‐positions were effectively activated, thus giving tetrahydroquinolines, benzomorpholines, pyrrolidines, and indolines in moderate to excellent yields by palladium‐catalyzed intramolecular C? H amination.     

Ligand‐Promoted Borylation of C(sp3)H Bonds with Palladium(II) Catalysts

A quinoline‐based ligand effectively promotes the palladium‐catalyzed borylation of C(sp³)? H bonds. Primary β‐C(sp³)? H bonds in carboxylic acid derivatives as well as secondary C(sp³)? H bonds in a variety of carbocyclic rings, including cyclopropanes, cyclobutanes, cyclopentanes, cyclohexanes, and cycloheptanes, can thus be borylated. This directed borylation method complements existing iridium(I)‐ and rhodium(I)‐catalyzed C? H borylation reactions in terms of scope and operational conditions.     

Dehydrogenative N‐Incorporation: A Direct Approach to Quinoxaline N‐Oxides under Mild Conditions

An efficient method for the synthesis of quinoxaline N‐oxides proceeds by the dehydrogenative N‐incorporation of simple imines by C(sp²)? H and C(sp³)? H bond functionalization. The overall transformation involves the cleavage of three C? H bonds. The reaction is easily handled and proceeds under mild conditions. Simple and readily available tert‐butyl nitrite (TBN) was employed as the NO source.     

γ‐Functionalizations of Amines through Visible‐Light‐Mediated,Redox‐Neutral C−C Bond Cleavage

Cleavage of unstrained C−C bonds under mild, redox‐neutral conditions represents a challenging endeavor which is accomplished here in the context of a flexible, visible‐light‐mediated, γ‐functionalization of amines. In situ generated C‐centered radicals are harvested in the presence of Michael acceptors, thiols and alkyl halides to efficiently form new C(sp³)−C(sp³), C(sp³)−H and C(sp³)−Br bonds, respectively.     

Visible‐Light‐Mediated Remote Aliphatic C−H Functionalizations through a 1,5‐Hydrogen Transfer Cascade

A redox‐neutral, light‐mediated functionalization of unactivated C(sp³)−H bonds via iminyl radicals is presented here. A 1,5‐H transfer followed by the functionalization of a C(sp²)−H bond takes place in aqueous media producing a variety of elaborated fused ketones. Mechanistic investigations have revealed 1,5‐H transfer as the reversible, rate‐determining step in this transformation. Divergent scaffolds are also accessible via C(sp³)−N bond formation upon a careful choice of the reaction additives.