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2.8 Remote C(sp3)–H allyation of amides using organic photocatalyst.
Source: Modified from Wu et al. [31].
Scheme 2.9 Site‐selective remote C(sp3)–H heteroarylation of amides.
Source: Modified from Chen et al. [34].
Scheme 2.10 Visible‐light‐promoted C(sp3)–H amidation and chlorination of N‐chlorosulfonamides.
Source: Modified from Quin and Yu [35].
The generation of amidyl radicals through photoinduced SET reduction is not restricted to electrophores embedded into a N–O systems but can also be performed on N‐Cl derivatives. This was demonstrated by Yu and coworkers in the HLF‐type reactivity of N‐Cl–N‐Ts amines 40 by using a heteroleptic Ir(III) photocatalyst under white light irradiation (Scheme 2.10) [35]. In this case, after generation of a very electrophilic sulfamidyl radical, the 1,5‐HAT took place, and then the corresponding carbon radical was chlorinated, most likely, as part of a radical chain propagation. This protocol has also been used in the assembly of many pyrrolidines 41 and also in late‐stage functionalizations of some bioactive materials, demonstrating the strong functional group compatibility.
2.3.2 Oxidative Strategies
2.3.2.1 1,5‐HAT via Iminyl Radicals
Inspired by the pioneering work of Forrester [17–20], the Leonori and the Studer group took carboxylic acid‐containing oximes 42 and used them to generate functionalized imine and ketone derivatives 43–45 (Scheme 2.11) [36–38]. These processes were all based on a reductive quenching photoredox cycle and required basic conditions to trigger the SET oxidation of the carboxylate functionality (46). This event led to two β‐scissions extruding CO2 and acetone and forming the corresponding iminyl radical 47. This species then underwent 1,5‐HAT and the incipient carbon radical 48 was intercepted and diversified with several radical trapping agents (X–Y) such as N‐chlorosuccinimide (NCS; chlorination, 43), selectfluor (fluorination, 44), and Michael acceptors (Giese addition, 45). A final electron transfer between the reduced photocatalyst and the Y· intermediate, generated upon atom transfer/addition, led to an overall redox‐neutral process. This approach for remote ketone functionalization tolerated important functionalities such as protected amines, heteroaromatics, free alcohols, and ester groups among others. Interestingly, in the case of NCS, the intermediate NH imine was directly intercepted by NCS before hydrolysis, leading to the corresponding N–Cl imines that showed remarkable stability.
Scheme 2.11 Site‐specific intermolecular γ‐C(sp3)–H functionalization of ketones via iminyl radicals.
Source: Jiang and Studer [36], Morcillo et al. [37], and Davies et al. [38].
2.3.2.2 1,5‐HAT via Amidyl and Sulfamidyl Radicals
A related approach for nitrogen radical generation was then used by the Leonori group to introduce a range of functionalities at the γ‐position of amides and at the δ‐position of protected amines using carboxylic acid‐containing hydroxyamides 49 (Scheme 2.12) [37]. In analogy to their previous work on iminyl radicals, photoinduced oxidation of 49 under basic conditions enabled amidyl radical generation, followed by 1,5‐HAT and distal carbon radical functionalization. In this case, halogenating agents such as NCS and selectfluor allowed introduction of γ chlorine and fluorine atoms, while S‐containing phthalimides enabled direct thioetherification. More importantly, 2‐iodoxybenzoic acid (IBX) reagents were successful to achieve remote C—C bond formation and introduce CN as well as alkyne functionalities. This strategy enabled the selective modification of tertiary, secondary, and even primary centers and was also used for the late‐stage functionalization of small dipeptides.
A very powerful approach for distal functionalization of amides has been possible from the corresponding N–H substrates using photoinduced proton‐coupled electron transfer (PCET). As initially demonstrated by Knowles and coworkers, this activation mode bypasses the need to install a stoichiometric electrophore on the substrates and therefore streamlines the preparation of the desired reaction products. This strategy has been initially used to trigger cyclization reactions [39], and also used in interrupted HLF‐type reactivity as demonstrated by the groups of Knowles and Rovis (Scheme 2.13) [40, 41]. Following a reductive‐quenching photoredox cycle and in the presence of a suitable base, 50 was effectively oxidized by photoinduced PCET generating the amidyl radical 51. This species was exploited in a 1,5‐HAT transposition and the resulting carbon radical 52 reacted with a Michael acceptor (53), thus assembling a distal sp3–sp3 C—C bond. Owing to electron‐poor nature of the intermediate α‐ester radical 53, the photoredox cycle was closed by SET with the reduced Ir(II) photocatalyst that delivered the stabilized anion 54 that was protonated. The design of the amide substrates was critical to the feasibility and the overall success of the PCET as the carbonyl functionality must be able to acidify the N–H proton enough to encourage the deprotonation step. This somewhat controlled the nature of the amidyl radicals that could be generated. Nevertheless, this methodology displayed strong functional group tolerance as demonstrated by the number of Michael acceptors and functionalized amides that could be used.
Scheme 2.12 Nitrogen radical mediated remote functionalization of amides and amines.
Source: Modified from Morcillo et al. [37].
Scheme 2.13 Amide‐directed selective C—C bond formation at C(sp3)—H bonds.
Source: Choi et al. [40] and Chu and Rovis [41].
This PCET reactivity for amidyl radical generation and 1,5‐HAT has also been exploited by Tamber to achieve remote amide allylation using allyl chlorides and a Ni(0) cocatalyst (Scheme 2.14) [42].
A powerful expansion of this PCET strategy for amidyl