Functionalization of C(sp
            <sup>3</sup>
            )–H bonds using a transient directing group

Zhang, Fanglin; Hong, Kai; Li, Tuanjie; Park, Hojoon; Yu, Jin‐Quan

doi:10.1126/science.aad7893

Cited by 624 publications

(362 citation statements)

References 31 publications

(26 reference statements)

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“…Interestingly, the opposite absolute configuration of these two products was observed, indicating the involvement of two distinct reaction pathways. The configuration of 3a is consistent with our previous arylation reaction 28 , suggesting that fluorination proceeds through a classic inner-sphere reductive elimination process with retention of stereochemistry, while 2a is formed through an S N 2-type mechanism to achieve inversion of stereochemistry. To further support this mechanistic hypothesis, we conducted a series of experiments to rule out the possibility of 2a and 3a forming through an identical mechanism from two different diastereomeric palladacycles.…”

Section: Resultssupporting

confidence: 88%

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Controlling Pd(iv) reductive elimination pathways enables Pd(ii)-catalysed enantioselective C(sp3)−H fluorination

et al. 2018

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The development of a Pd(II)-catalyzed enantioselective fluorination of C(sp3)–H bonds would offer a new approach to making chiral organofluorines. However, such a strategy is particularly challenging because of the difficulty in differentiating prochiral C(sp3)–H bonds through Pd(II)-insertion, as well as the sluggish reductive elimination involving Pd–F bonds. Here, we report the development of a Pd(II)-catalyzed enantioselective C(sp3)–H fluorination using a chiral transient directing group strategy. In this work, a bulky, amino amide transient directing group was developed to control the stereochemistry of C–H insertion step and selectively promote C(sp3)–F reductive elimination pathway from Pd(IV)–F intermediate. Stereochemical analysis revealed that while the desired C(sp3)–F formation proceeds via an inner-sphere pathway with retention of configuration, the undesired C(sp3)–O formation occurs through an SN2-type mechanism. The elucidation of the dual mechanism allows us to rationalize the profound ligand effect on controlling reductive elimination selectivity from high-valent Pd species.

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Section: Resultssupporting

confidence: 88%

“…We have recently developed a Pd(II)-catalyzed enantioselective C(sp 3 )–H arylation using a chiral amino acid transient directing group 28 . This finding led us to investigate the feasibility of developing a new chiral transient directing group to enable an enantioselective C(sp 3 )–H fluorination.…”

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Controlling Pd(iv) reductive elimination pathways enables Pd(ii)-catalysed enantioselective C(sp3)−H fluorination

et al. 2018

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“…6b). On the basis of the above observed results and the previous reports 25,37 , a plausible catalytic cycle of this reaction is proposed (Fig. 6).…”

Section: Discussionsupporting

confidence: 75%

“…Furthermore, the primary amines with a cyclic alkyl group reacted smoothly in this catalytic system (2j and 2k). Although many successful examples for functionalizing unactivated secondary sp 3 C−H bonds have been reported with the installation of a mono-or bidentate directing group on the substrates [5][6][7][8][9][10][11][12][13][14][15] , direct functionalization of these bonds remains a great challenge with carbonyl compounds using a transient directing group 37 and free aliphatic amines 23,30,31 , presumably due to the inherent steric hindrance. In this catalytic system, substrate 1l with cyclic methylene C−H bonds provided the γ-arylated product 2l in 23% yield, while arylation of noncyclic secondary C−H bonds was not realized.…”

Section: Resultsmentioning

confidence: 99%

Site-selective C–H arylation of primary aliphatic amines enabled by a catalytic transient directing group

2016

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Abstract. Transition metal-catalyzed direct C−H bond functionalization of aliphatic amines is of great importance in organic and medicinal chemistry research. While several methods have been developed for the direct sp 3 C−H functionalization of secondary and tertiary aliphatic amines, site-selective functionalization of primary aliphatic amines remains a challenge. Here we report the direct highly siteselective arylation of primary alkylamines via a palladium-catalyzed C−H bond functionalization process on unactivated sp 3 carbons with catalytic glyoxylic acid as a novel, inexpensive, and transient directing group. With this approach, a wide array of γ-arylated primary alkylamines, important structural motifs in organic and medicinal chemistry, were prepared without any protection or deprotection steps.Aliphatic amines are ubiquitously present in pharmaceuticals with a wide range of biological activities 1,2 .

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“…However, a number of problems are persistently associated with the chemical oxidation of aliphatic C-H bonds in alkylphenols: (i) the requirement of protection/deprotection of the phenolic hydroxyl group under reaction conditions that are distinct from those for oxidation complicates the synthetic process; (ii) it is difficult to delicately control the extent of oxidations (i.e., alcohol vs. aldehyde/ketone vs. carboxylic acid); (iii) the oxidation of an aromatic C-H bond may sometimes occur when using strong oxidants; (iv) the regio-and stereoselective oxidation of an unactivated sp 3 C-H bond (in alkylphenols) remains a central challenge despite recent advances in combined use of specialized directing groups with transition metal catalysts (9)(10)(11) and in biomimetic supramolecular assemblies (12)(13)(14); and (v) chemical oxidants could be associated with significant environmental concerns (2,3). Given these issues, oxidative enzymes with inherent catalytic selectivity and reduced environmental impact may be developed into alternative catalysts for selective oxidation of organic compounds including alkylphenols (15)(16)(17)(18).…”

mentioning

confidence: 99%

Selective oxidation of aliphatic C–H bonds in alkylphenols by a chemomimetic biocatalytic system

Dong

Zhang

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Selective oxidation of aliphatic C-H bonds in alkylphenols serves significant roles not only in generation of functionalized intermediates that can be used to synthesize diverse downstream chemical products, but also in biological degradation of these environmentally hazardous compounds. Chemo-, regio-, and stereoselectivity; controllability; and environmental impact represent the major challenges for chemical oxidation of alkylphenols. Here, we report the development of a unique chemomimetic biocatalytic system originated from the Gram-positive bacterium Corynebacterium glutamicum. The system consisting of CreHI (for installation of a phosphate directing/ anchoring group), CreJEF/CreG/CreC (for oxidation of alkylphenols), and CreD (for directing/anchoring group offloading) is able to selectively oxidize the aliphatic C-H bonds of p-and m-alkylated phenols in a controllable manner. Moreover, the crystal structures of the central P450 biocatalyst CreJ in complex with two representative substrates provide significant structural insights into its substrate flexibility and reaction selectivity.alkylphenol | selective oxidation | chemomimetic biocatalysis | cytochrome P450 enzymes | Corynebacterium glutamicum A lkylphenols, p-, m-, and o-alkylated phenols, e.g., 1-10, (Fig. 1A) are among the most important synthetic precursors for manufacturing a vast variety of chemical products including detergents, polymers, lubricants, antioxidants, emulsifiers, pesticides, and pharmaceuticals (1). Alkylphenols are also priority environmental pollutants because they are toxic, xenoestrogenic, or carcinogenic to wildlife and humans (2, 3). The selective oxidation of the aliphatic C-H bonds in alkylphenols serves significant roles not only in generation of functionalized intermediates for synthesizing more downstream products (4), but also in biological degradation of these environmentally hazardous compounds (5). In particular, some oxidized alkylphenols are direct structural motifs in drugs (e.g., metoprolol) (6) and bioactive ingredients of medicinal plants (Fig. 1B).Chemically, these oxidative transformations have been practiced for a long time by using superoxides, organocatalyst, high valence transition metals, or strong oxidants such as nitric acid, chromic acid, and potassium permanganate (4,7,8). However, a number of problems are persistently associated with the chemical oxidation of aliphatic C-H bonds in alkylphenols: (i) the requirement of protection/deprotection of the phenolic hydroxyl group under reaction conditions that are distinct from those for oxidation complicates the synthetic process; (ii) it is difficult to delicately control the extent of oxidations (i.e., alcohol vs. aldehyde/ketone vs. carboxylic acid); (iii) the oxidation of an aromatic C-H bond may sometimes occur when using strong oxidants; (iv) the regio-and stereoselective oxidation of an unactivated sp 3 C-H bond (in alkylphenols) remains a central challenge despite recent advances in combined use of specialized directing groups with transition met...

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Functionalization of C(sp ³ )–H bonds using a transient directing group

Cited by 624 publications

References 31 publications

Controlling Pd(iv) reductive elimination pathways enables Pd(ii)-catalysed enantioselective C(sp3)−H fluorination

Controlling Pd(iv) reductive elimination pathways enables Pd(ii)-catalysed enantioselective C(sp3)−H fluorination

Site-selective C–H arylation of primary aliphatic amines enabled by a catalytic transient directing group

Selective oxidation of aliphatic C–H bonds in alkylphenols by a chemomimetic biocatalytic system

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Functionalization of C(sp 3 )–H bonds using a transient directing group

Cited by 624 publications

References 31 publications

Controlling Pd(iv) reductive elimination pathways enables Pd(ii)-catalysed enantioselective C(sp3)−H fluorination

Controlling Pd(iv) reductive elimination pathways enables Pd(ii)-catalysed enantioselective C(sp3)−H fluorination

Site-selective C–H arylation of primary aliphatic amines enabled by a catalytic transient directing group

Selective oxidation of aliphatic C–H bonds in alkylphenols by a chemomimetic biocatalytic system

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Functionalization of C(sp ³ )–H bonds using a transient directing group