Over the past several decades, organometallic cross-coupling chemistry has developed into one of the most reliable approaches to assemble complex aromatic compounds from preoxidized starting materials. More recently, transition metal-catalyzed carbon-hydrogen activation has circumvented the need for preoxidized starting materials, but this approach is limited by a lack of practical amination protocols. Here, we present a blueprint for aromatic carbon-hydrogen functionalization via photoredox catalysis and describe the utility of this strategy for arene amination. An organic photoredox-based catalyst system, consisting of an acridinium photooxidant and a nitroxyl radical, promotes site-selective amination of a variety of simple and complex aromatics with heteroaromatic azoles of interest in pharmaceutical research. We also describe the atom-economical use of ammonia to form anilines, without the need for prefunctionalization of the aromatic component.
Redox
processes are at the heart of synthetic methods that rely
on either electrochemistry or photoredox catalysis, but how do electrochemistry
and photoredox catalysis compare? Both approaches provide access to
high energy intermediates (e.g., radicals) that enable bond formations
not constrained by the rules of ionic or 2 electron (e) mechanisms.
Instead, they enable 1e mechanisms capable of bypassing electronic
or steric limitations and protecting group requirements, thus enabling
synthetic chemists to disconnect molecules in new and different ways.
However, while providing access to similar intermediates, electrochemistry
and photoredox catalysis differ in several physical chemistry principles.
Understanding those differences can be key to designing new transformations
and forging new bond disconnections. This review aims to highlight
these differences and similarities between electrochemistry and photoredox
catalysis by comparing their underlying physical chemistry principles
and describing their impact on electrochemical and photochemical methods.
Nucleophilic aromatic substitution (SAr) is a direct method for arene functionalization; however, it can be hampered by low reactivity of arene substrates and their availability. Herein we describe a cation radical-accelerated nucleophilic aromatic substitution using methoxy- and benzyloxy-groups as nucleofuges. In particular, lignin-derived aromatics containing guaiacol and veratrole motifs were competent substrates for functionalization. We also demonstrate an example of site-selective substitutive oxygenation with trifluoroethanol to afford the desired trifluoromethylaryl ether.
Over the past decade, chemists have
embraced visible-light photoredox
catalysis due to its remarkable ability to activate small molecules.
Broadly, these methods employ metal complexes or organic dyes to convert
visible light into chemical energy. Unfortunately, the excitation
of widely utilized Ru and Ir chromophores is energetically wasteful
as ∼25% of light energy is lost thermally before being quenched
productively. Hence, photoredox methodologies require high-energy,
intense light to accommodate said catalytic inefficiency. Herein,
we report photocatalysts which cleanly convert near-infrared (NIR)
and deep red (DR) light into chemical energy with minimal energetic
waste. We leverage the strong spin–orbit coupling (SOC) of
Os(II) photosensitizers to directly access the excited triplet state
(T
1
) with NIR or DR irradiation from the ground state singlet
(S
0
). Through strategic catalyst design, we access a wide
range of photoredox, photopolymerization, and metallaphotoredox reactions
which usually require 15–50% higher excitation energy. Finally,
we demonstrate superior light penetration and scalability of NIR photoredox
catalysis through a mole-scale arene trifluoromethylation in a batch
reactor.
Positron emission tomography (PET) plays key roles in drug discovery and development, as well as medical imaging. However, there is a dearth of efficient and simple radiolabeling methods for aromatic C–H bonds, which limits advancements in PET radiotracer development. Here, we disclose a mild method for the fluorine-18 (18F)–fluorination of aromatic C–H bonds by an [18F]F− salt via organic photoredox catalysis under blue light illumination. This strategy was applied to the synthesis of a wide range of 18F-labeled arenes and heteroaromatics, including pharmaceutical compounds. These products can serve as diagnostic agents or provide key information about the in vivo fate of the labeled substrates, as showcased in preliminary tracer studies in mice.
State-of-the art photoactivation strategies in chemical biology provide spatiotemporal control and visualization of biological processes. However, using high energy light (l < 500 nm) for substrate or photocatalyst sensitization can lead to background activation of photoactive small molecule probes and reduce its efficacy in complex biological environments. Here we describe the development of targeted aryl azide activation via deep red light (l = 660 nm) photoredox catalysis and its use in photocatalyzed proximity labeling. We demonstrate that aryl azides are converted to triplet nitrenes via a novel redox-centric mechanism and show that its spatially localized-formation requires both red light and a photocatalyst-targeting modality. This technology was applied in different colon cancer cell systems for targeted protein environment labeling of epithelial cell adhesion molecule (EpCAM). We identified a small subset of proteins with previously known and unknown association to EpCAM, including CDH3, a clinically relevant protein that shares high tumor selective expression with EpCAM.
Aryl amination is an essential transformation for medicinal, process, and materials chemistry. In addition to classic Buchwald−Hartwig amination conditions, blue-light-driven metallaphotoredox catalysis has emerged as a valuable tool for C−N cross-coupling. However, blue light suffers from low penetration through reaction media, limiting its scalability for industrial purposes. In addition, blue light enhances unwanted side-product formation in metallaphotoredox catalysis, namely hydrodehalogenation. Low-energy light, such as deep red (DR) or near-infrared (NIR), offers a solution to this problem as it can provide enhanced penetration through reaction media as compared to higher-energy wavelengths. Herein, we show that lowenergy light can also enhance the desired reactivity in metallaphotoredox catalysis by suppressing unwanted hydrodehalogenation. We hypothesize that the reduced side product is formed by direct photolysis of the aryl−nickel bond by the high-energy light, leading to the generation of aryl radicals. Using deep-red or near-infrared light and an osmium photocatalyst, we demonstrate an enhanced scope of (hetero)aryl bromides and amine-based nucleophiles with minimal formation of hydrodehalogenation byproducts.
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