Hai-Chao Xu

Bio: Hai-Chao Xu is an academic researcher from Xiamen University. The author has contributed to research in topics: Alkene & Electrosynthesis. The author has an hindex of 37, co-authored 90 publications receiving 3585 citations. Previous affiliations of Hai-Chao Xu include Washington University in St. Louis & Nankai University.

Chemistry with Electrochemically Generated N-Centered Radicals

Abstract: N-centered radicals are versatile reaction intermediates that can react with various π systems to construct C-N bonds. Current methods for generating N-centered radicals usually involve the cleavage of an N-heteroatom bond; however, similar strategies that are applicable to N-H bonds prove to be more challenging to develop and therefore are attracting increasing attention. In this Account, we summarize our recent efforts in the development of electrochemical methods for the generation and synthetic utilization of N-centered radicals. In our studies, N-aryl amidyl radical, amidinyl radical and iminyl radical cation intermediates are generated from N-H precursors through direct electrolysis or indirect electrolysis assisted by a redox catalyst. In addition, an electrocatalytic method that converts oximes to iminoxyl radicals has also been developed. The electrophilic amidyl radical intermediates can participate in 5-exo or 6-exo cyclization with alkenes and alkynes to afford C-centered radicals, which can then undergo various transformations such as H atom abstraction, single-electron transfer oxidation to a carbocation, cyclization, or aromatic substitution, leading to a diverse range of N-heterocyclic products. Furthermore, amidinyl radicals, iminyl radical cations, and iminoxyl radicals can undergo intramolecular aromatic substitution to afford various N-heteroaromatic compounds. Importantly, the electrochemical reaction can be channeled toward a specific product despite the presence of other competing pathways. For a successful electrosynthesis, it is important to take into consideration of both the electron transfer steps associated with the electrode and the nonelectrode related processes. A unique feature of electrochemistry is the simultaneous occurrence of anodic oxidation and cathodic reduction, which, as this Account demonstrates, allows the dehydrogenative transformations to proceed through H2 evolution without the need for chemical oxidants. In addition, cathodic solvent reduction can continuously generate a low concentration of base, which facilitates anodic substrate oxidation. Such a mechanistic paradigm obviates the need for stoichiometric strong bases and avoids base-promoted decomposition of sensitive substrates or products. Furthermore, electrode materials can also be adjusted to control the reaction outcome, as demonstrated by the synthesis of N-heteroaromatics and the corresponding N-oxides from biaryl ketoximes.

Electrochemical C-H/N-H Functionalization for the Synthesis of Highly Functionalized (Aza)indoles.

Abstract: Indoles and azaindoles are among the most important heterocycles because of their prevalence in nature and their broad utility in pharmaceutical industry. Reported herein is an unprecedented noble-metal- and oxidant-free electrochemical method for the coupling of (hetero)arylamines with tethered alkynes to synthesize highly functionalized indoles, as well as the more challenging azaindoles.

Electrochemical Difluoromethylarylation of Alkynes.

Abstract: An unprecedented radical difluoromethylarylation reaction of alkynes has been developed by discovering a new difluoromethylation reagent, CF2HSO2NHNHBoc. This air-stable and solid reagent can be prepared in one step from commercially available reagents CF2HSO2Cl and NH2NHBoc. The CF2H radical, generated through ferrocene-mediated electrochemical oxidation, participates in an unexplored alkyne addition reaction followed by a challenging 7-membered ring-forming homolytic aromatic substitution step to afford fluorinated dibenzazepines.

Electrocatalytic Generation of Amidyl Radicals for Olefin Hydroamidation: Use of Solvent Effects to Enable Anilide Oxidation

Abstract: Oxidative generation of synthetically important amidyl radicals from N-H amides is an appealing and yet challenging task. Previous methods require a stoichiometric amount of a strong oxidant and/or a costly noble-metal catalyst. We report herein the first electrocatalytic method that employs ferrocene (Fc), a cheap organometallic reagent, as the redox catalyst to produce amidyl radicals from N-aryl amides. Based on this radical-generating method, an efficient intramolecular olefin hydroamidation reaction has been developed.

Metal- and Reagent-Free Intramolecular Oxidative Amination of Tri- and Tetrasubstituted Alkenes

Abstract: A metal- and reagent-free, electrochemical intramolecular oxidative amination reaction of tri- and tetrasubstituted alkenes has been developed. The electrosynthetic method proceeds through radical cyclization to form the key C–N bond, allowing a variety of hindered tri- and tetrasubstituted olefins to participate in the amination reaction. The result is the efficient synthesis of a host of alkene-bearing cyclic carbamates and ureas and lactams.

Synthetic Organic Electrochemical Methods Since 2000: On the Verge of a Renaissance

Abstract: Electrochemistry represents one of the most intimate ways of interacting with molecules. This review discusses advances in synthetic organic electrochemistry since 2000. Enabling methods and synthetic applications are analyzed alongside innate advantages as well as future challenges of electroorganic chemistry.

Electrifying Organic Synthesis

Abstract: The direct synthetic organic use of electricity is currently experiencing a renaissance. More synthetically oriented laboratories working in this area are exploiting both novel and more traditional concepts, paving the way to broader applications of this niche technology. As only electrons serve as reagents, the generation of reagent waste is efficiently avoided. Moreover, stoichiometric reagents can be regenerated and allow a transformation to be conducted in an electrocatalytic fashion. However, the application of electroorganic transformations is more than minimizing the waste footprint, it rather gives rise to inherently safe processes, reduces the number of steps of many syntheses, allows for milder reaction conditions, provides alternative means to access desired structural entities, and creates intellectual property (IP) space. When the electricity originates from renewable resources, this surplus might be directly employed as a terminal oxidizing or reducing agent, providing an ultra-sustainable and therefore highly attractive technique. This Review surveys recent developments in electrochemical synthesis that will influence the future of this area.

Use of Electrochemistry in the Synthesis of Heterocyclic Structures.

Abstract: The preparation and transformation of heterocyclic structures have always been of great interest in organic chemistry. Electrochemical technique provides a versatile and powerful approach to the assembly of various heterocyclic structures. In this review, we examine the advance in relation to the electrochemical construction of heterocyclic compounds published since 2000 via intra- and intermolecular cyclization reactions.

Synthetic Organic Electrochemistry: An Enabling and Innately Sustainable Method

Abstract: While preparative electrolysis of organic molecules has been an active area of research over the past century, modern synthetic chemists have generally been reluctant to adopt this technology. In fact, electrochemical methods possess many benefits over traditional reagent-based transformations, such as high functional group tolerance, mild conditions, and innate scalability and sustainability. In this Outlook we highlight illustrative examples of electrochemical reactions in the context of the synthesis of complex molecules, showcasing the intrinsic benefits of electrochemical reactions versus traditional reagent-based approaches. Our hope is that this field will soon see widespread adoption in the synthetic community.

Macrocycles Are Great Cycles: Applications, Opportunities, and Challenges of Synthetic Macrocycles in Drug Discovery

Abstract: Macrocycles occupy a unique segment of chemical space. In the past decade, their chemical diversity expanded significantly, supported by advances in bioinformatics and synthetic methodology. As a consequence, this structural type has now been successfully tested on most biological target classes. The goal of this article is to put into perspective the current applications, opportunities, and challenges associated with synthetic macrocycles in drug discovery. Historically, macrocyclic drug candidates have originated primarily from two sources. The first, natural products, provided unique drugs such as erythromycin, rapamycin, vancomycin, cyclosporin, and epothilone. Excellent reviews are dedicated to this class and how it inspired further synthetic and medicinal chemistry efforts; thus, it will not be covered here. From a molecular evolution standpoint, the medicinal chemistry of macrocyclic natural products usually involved direct use as a therapeutic agent or functionalization of the natural product scaffold by hemisynthesis. It parallels significant advances in the total synthesis of macrocyclic natural products during the past 2 decades. The second traditional source of macrocycles stems from peptides, some of which are natural products and, hence, also belong to the first category. Macrocyclization was recognized early in peptide chemistry as an efficient way to restrict peptide conformation, reduce polarity, increase proteolytic stability, and consequently improve druggability. Chemists accessed macrocyclic peptides with different geometries (head to tail, side chain to side chain, head to side chain), including the incorporation of nonpeptidic groups. Compelling examples of macrocyclic scaffolding of peptides include the works on somatostatins, melanocortins, and integrins, among others. Macrocyclic peptides generated several drugs from synthetic or natural sources, including octreotide, cyclosporine, eptifibatide, and caspofungin. Purely peptidic, depsipeptidic, and peptoid macrocycles will also not be covered in this article; the reader is instead referred to previous reviews. It is well understood that the boundary between synthetic macrocycles and the above categories is not always clear-cut; as a result, examples presented in the following sections could occasionally belong to one of these categories. In these cases, they were selected owing to their relevance to the perspective. Macrocycles are defined herein as molecules containing at least one large ring composed of 12 or more atoms. On the basis of standard molecular descriptors, macrocycles as a class are at the outskirts of the window generally considered optimal for good PK-ADME properties using these criteria. Indeed, their molecular weights tend to be on the higher end (often in the 500-900 g 3mol -1 range), their numbers of H-bond donors and acceptors, as well as their polar surface area (PSA), tend to be on the far side of the accepted druglike spectrum. For an equal number of heavy atoms, macrocycles inherently possess a lower number of rotatable bonds than their acyclic analogues, a beneficial feature for oral bioavailability (in the following, “acyclic” will be used in the sense of “nonmacrocyclic”). As a result, macrocycles are more conformationally restricted than their acyclic analogues, which potentially can impart higher target binding and selectivity and improved oral bioavailability (in this assessment, endocyclic bonds are considered to be nonrotatable, which is only an approximation; see ref 18). For a systematic chemoinformatic analysis of biologically active macrocycles, the reader is referred to the recent review of Brandt et al. Topologically, macrocycles have the unique ability to span large surface areas while remaining conformationally restricted compared to acyclic molecules of equivalent molecular weight. This characteristic makes them especially suited for targets displaying shallow surfaces, which can prove to be quite challenging for acyclic small molecules. Medicinal chemistry relies strategically on robust synthetic methods capable of producing an acceptable chemical diversity to adequately interrogate the chemical space of a biological target. Macrocycles are often (and rightly so) perceived as difficult to synthesize and hence deterred many medicinal chemists because of the lack of versatile synthetic platforms. The macrocyclization step is regularly plagued by low yields and often requires high dilution conditions to counterbalance entropic loss. In other words, the reduction in entropy responsible for beneficial conformational restrictions to the final molecule comes at a price during synthesis: what goes around comes around. Accordingly, the first part of this article is dedicated to the drug discovery aspects ofmacrocycles and highlights salient features of their medicinal chemistry. This section is organized by target class, a choice aimed at providing the reader an appreciation of the structural diversity generated for each class. To give the reader an appreciation of the tools available to construct macrocyclic scaffolds, the site and method of the pivotal macrocyclization step are indicated in the figures. Readers are referred to the source articles for further details. In the second part, the technologies and synthetic approaches that already have demonstrated utility or possess a high potential for macrocycle-based