Sustainable Synthesis of N−N Bond Bearing Organic Frameworks by Advanced Heterogeneous Metal Catalysis

The most significant task in synthetic organic chemistry is developing organic reactions from a green and sustainable perspective. In these ways, heterogeneous catalysts are essential in many organic reactions. Thus, this study focuses on the synthesis of N−N bond bearing organic frameworks, particularly aromatic azo compounds and indazoles, using a heterogeneous metal catalyst. Organic molecules containing nitrogen-nitrogen bonds are greatly sought after in the synthesis of dyes, photochemical switches, food additives, and bioactive chemicals due to industry and human requirements. Finally, this review provides an overview of synthetic routes for the formation of N−N bonds by using various heterogeneous metal catalytic systems.     

Organoselenium Chemistry in Stereoselective Reactions

Selenium-based methods have developed rapidly over the past few years asnd organoselenium chemistry has become a very useful tool in the hands of synthetic chemists. The different reactivity of selenium-containing compounds in contrast to the sulfur analogues has led to versatile and new synthetic methods in organic chemistry. Various functionalities can be selectively introduced into complex molecules under very mild reaction conditions. In this review, the principles of organoselenium chemistry are traced back to their origins and are highlighted with respect to stereoselective synthesis. The unique properties of selenium allow the development of new and highly selective transformations, which can be employed subsequently in new routes for the synthesis of versatile chiral building blocks and for natural product synthesis.     

Unclicking the Click: Metal-Assisted Mechanochemical Cycloreversion of Triazoles Is Possible

The mechanochemical cycloreversion of 1,2,3-triazole compounds, which serve as unusually stable building blocks in materials and biomolecular chemistry as a result of mild “click chemistry”, remains puzzling. We show that the hitherto discussed straight-forward retro-click mechanism of the 1,4-disubstituted isomer, even if Cu^I catalyzed, can be ruled out in view of more favorable activation free energies of destructive pathways. In stark contrast, the 1,5-regioiomer can undergo cycloreversion under rather mild mechanochemical conditions owing to its favorable response to the external force in conjunction with standard Ru^II catalysis.     

Recent Trends in the Synthesis of Benzimidazoles From o‐Phenylenediamine via Nanoparticles and Green Strategies Using Transition Metal Catalysts

Benzimidazole is a heterocyclic moiety of immense importance as it acts as a primary “biolinker” in diverse synthetic routes to obtain bioactive compounds. Substituted benzimidazoles are known to possess a varied range of pharmacological applications, namely, anti‐cancer, anti‐diabetic, anti‐inflammatory, and antiviral like anti‐HIV and anti‐fungal. A number of reviews covering the important aspects of benzimidazoles such as pharmacological activities, SAR studies, and well‐known methods of synthesis have appeared in the literature. However, green synthetic methods particularly using transition metal (TM) catalysts and their nanoparticles, although being more viable and extensively applied by researchers in the present scenario, have not been exclusively and expansively reviewed. Besides this, the vital precursors required for knitting the skeleton of benzimidazole are mainly o‐aryldiamines. The conventional synthesis generally involved the condensation of these diamines with carbonyl/carboxylic acid derivatives either via high temperature heating or via adding strong acids, mostly resulting in poor yields or mixtures. However, recent trends are replacing these conditions by mild and green conditions through TM catalysts. Therefore, the current review emphasizes on the recent trends adopted in the synthesis of benzimidazoles using condensation reaction of o‐phenylenediamines and various aldehydes/ester/amide/alcohols with TM in a catalytic role in nanoform and under environmentally benign green conditions.     

Unclicking the Click: Metal‐Assisted Mechanochemical Cycloreversion of Triazoles Is Possible

The mechanochemical cycloreversion of 1,2,3‐triazole compounds, which serve as unusually stable building blocks in materials and biomolecular chemistry as a result of mild “click chemistry”, remains puzzling. We show that the hitherto discussed straight‐forward retro‐click mechanism of the 1,4‐disubstituted isomer, even if Cu^I catalyzed, can be ruled out in view of more favorable activation free energies of destructive pathways. In stark contrast, the 1,5‐regioiomer can undergo cycloreversion under rather mild mechanochemical conditions owing to its favorable response to the external force in conjunction with standard Ru^II catalysis.     

Microwave‐Assisted Solvent‐Free Regiospecific Synthesis of 5‐Alkylidene and 5‐Arylidenehydantoins

Hydantoins have become a well‐known class of structures that have found significant applications as agrochemicals and therapeutics. This structural motif is of interest in the synthesis of small building blocks suitable for the preparation of potentially bioactive molecules. In this sense, 5‐alkylidene and 5‐arylidenehydantoins constitute nice examples of precursors of synthetic α‐amino acids. The microwave‐assisted synthesis of these compounds under green chemistry conditions is reported in this article. The method has proved to afford yields of 74–96%.     

Chemical Syntheses and Chemical Biology of Carboxyl Polyether Ionophores: Recent Highlights

A central goal of chemical biology is to develop molecular probes that enable fundamental studies of cellular systems. In the hierarchy of bioactive molecules, the so‐called ionophore class occupies an unflattering position in the lower branches, with typical labels being “non‐specific” and “toxic”. In fact, the mere possibility that a candidate molecule possesses “ionophore activity” typically prompts its removal from further studies; ionophores—from a chemical genetics perspective—are molecular outlaws. In stark contrast to this overall poor reputation of ionophores, synthetic chemistry owes some of its most amazing achievements to studies of ionophore natural products, in particular the carboxyl polyethers renowned for their intricate molecular structures. These compounds have for decades been academic battlegrounds where new synthetic methodology is tested and retrosynthetic tactics perfected. Herein, we review the most exciting recent advances in carboxyl polyether ionophore (CPI) synthesis and in addition discuss the burgeoning field of CPI chemical biology.     

光催化应用于药物合成反应实验教学的设计与改革

可见光诱导的光催化具有绿色、高效、可持续等特点,在有机医药中间体和药物分子的合成上极具创新性.近年来,将前沿性、创新性的科研成果实施于本科实验教学项目中已成为高校实验教学改革的重点与趋势之一.本实验利用苝二酰亚胺作为光催化剂,在温和的光照条件下高效选择性氧化硫醚得到亚砜.通过本实验的学习,为学生实践绿色、低能耗的有机化...     

Starburst Dendrimers: Molecular-Level Control of Size,Shape, Surface Chemistry,Topology, and Flexibility from Atoms to Macroscopic Matter

Starburst dendrimers are three-dimensional, highly ordered oligomeric and polymeric compounds formed by reiterative reaction sequences starting from smaller molecules—“initiator cores” such as ammonia or pentaerythritol. Protecting group strategies are crucial in these syntheses, which proceed via discrete “Aufbau” stages referred to as generations. Critical molecular design parameters (CMDPs) such as size, shape, and surface chemistry may be controlled by the reactions and synthetic building blocks used. Starburst dendrimers can mimic certain properties of micelles and liposomes and even those of biomolecules and the still more complicated, but highly organized, building blocks of biological systems. Numerous applications of these compounds are conceivable, particularly in mimicking the functions of large biomolecules as drug carriers and immunogens. This new branch of “supramolecular chemistry” should spark new developments in both organic and macromolecular chemistry.     

Linked drug-drug conjugates based on triterpene and phenol structures. Rational synthesis,molecular properties,toxicity and bioactivity prediction

One of the tasks of modern medicinal chemistry is to produce new molecules that have interesting and desired biological effects. In addition, the synthetic procedure for obtaining these compounds should be at least partially smart and rational e.g. “Lego” and green approaches. The study focuses on the synthesis of several hybrid type compounds that are expected to be characterized by beneficial bioactivities. In order to hybridize natural triterpene oleanolic acid and phenol structures, the linker-mode concept was selected. The synthetic goal was achieved in two stages. The first concerns the rapid introduction of the halogenoacidic linker to active phenols selected as a result of microwave-ultrasonic (MW-US) assisted O-alkylation with the use of 2-halogenoacetic acid. The next stage of the synthetic studies involves the reaction of phenoxyacetic acid derivatives obtained containing an active carboxylic group with oleanolic acid/oxime units by the methods typical of triterpene chemistry. Novel linked ester- and iminoester-type triterpene derivatives with phenols (thymol, eugenol, paracetamol, nipagins, naphthols, curcumin and genistein) were obtained and characterized. Additionally, based on the analysis of numerous references and selected methods of computational chemistry (Molinspiration Cheminformatics, Osiris Property Explorer and PASS method) the molecular parameters and the preliminary anti-inflammatory and antinociceptive activity characterising these molecules as potential drugs were calculated and predicted.     

Easy Access to Crystalline Indolines via Hydrogen Bond Transfer

Several indoline derivatives with specific geometries are biologically active and have inhibitor properties. Many indolines are a key part of natural products. Much attention has been focused on the development of synthetic routes for their easy access. Current synthesis depends largely on metal catalysis, iodine reagents, and Oxone. To date, no synthetic route has been established that is metal‐free, reagent‐free, and environmentally friendly and provides a base for green chemistry. Here, we report the first facile metal‐free and reagent‐free synthesis of indoline derivatives, which could potentially be influential in the design of new biologically active compounds. The synthesis proceeds through intramolecular amination between a urea nucleophile and unactivated alkene. The ring closure occurs in a few hours in the presence of pre‐dried silica gel and gives good yields of indolines products, but in the absence of silica gel, the ring closure occurred overnight with stirring in dry solvent. An electron withdrawing group at the substituted aryl moiety of ureas increases the hydrogen bond donor ability of substrates that mediate the internal proton transfer at the terminal alkene and results in facile amination to give the indoline product with an “in plane” orientation of the carbonyl group and aromatic part of indoline framework. Such orientation in indolines is important for potent biological activities.     

可见光促进的偕二氟烯烃制备与应用研究进展

偕二氟烯烃化合物在医药、材料、精细化工等领域具有广泛的应用,同时也是一类非常重要的用于制备各类复杂的有机氟化合物的有机合成中间体.可见光催化反应具有条件温和、绿色清洁等特点,已经成为有机化学中非常重要的合成手段之一.本文综述了近年来可见光促进的偕二氟烯烃化合物的制备及其在有机合成化学中的应用.     

Ultrasound-assisted green one-pot synthesis of linked bis-heterocycle peptidomimetics via IMCR/post-transformation/tandem strategy

The sequential aligning of two eco-friendly and powerful tools for the synthesis of peptidomimetics resulted in the rapid generation of molecular complexity in target molecules. We herein report a versatile IMCR/post-transformation/tandem synthetic strategy that emphasizes the special role of orthogonal bifunctional reagents in isocyanide based multicomponent reactions (IMCR) to generate a synthetic platform for subsequent heterocyclization reactions. This is the first one-pot synthesis of a 2,5-diketopiperazine linked to a 1,4-disubstituted 1,2,3-triazole. The Ugi-4CR/lactamization/click sequence is facile, mild, atom-economical, and green. The present work contributes to the green and one-pot synthesis of bis-heterocycle peptidomimetics and design of new bioactive molecules.     

Laccase‐Mediated Synthesis of Novel Substituted Phenoxazine Chromophores Featuring Tuneable Water Solubility

Laccases are members of the blue copper oxidases family found in nature. They commonly oxidise a wide range of phenol and aniline derivatives, which in turn are involved in oxidative coupling reactions. Yet, laccases remain rarely described as biocatalysts in organic synthesis. This paper describes the chemical preparation of original sulfonated aminophenol substrates and their enzyme‐mediated dimerisation into phenoxazine chromophores that feature tuneable water solubility as a function of the sulfonyl substituent. The scope and limitations of the biocatalysed synthetic process are outlined. Kinetic data were collected to evaluate the influence of physicochemical parameters. The structure of the novel phenoxazine dyes (“head‐to‐head” or “head‐to‐tail” dimer) was assessed by NMR spectroscopic analysis. Two crystalline compounds were analysed by X‐ray diffraction. Such laccase‐mediated synthesis (a green chemistry process) was proven to be more efficient than the chemical oxidation of o‐aminophenols with silver oxide.     

A general,most basic rule for ion dissociation: Ionized molecules

Herein we revisit a basic rule for the interpretation of ion chemistry of ionized molecules, first proposed by the pioneers of MS spectra interpretation, but somewhat overlooked over the years. This rule states that, when rationalizing or predicting the dissociation chemistry of an ionized molecule (M^+.), a model analog to the “mobile proton model,” that is, a “mobile electron model” via “e^--jumping” should be considered. Ground-state M^+. is indeed the first species to be considered, but “e^--jumping” may eventually lead to other more energetic electromers—ionized molecules that differ only in the location of the missing electron—and each one of these electromers may dissociate via distinctive routes. In such a scenario, the route involving not necessarily the ground-state M^+., but the most labile electromer could become predominant or even exclusive. We argue that this “most labile electromer” rule, as well as an analogous “most labile protomer” rule that we have proposed for protonated molecules in an accompanying article, with the application of our conventional toolbox of a few cleavages and rearrangements, greatly simplifies the interpretation and prediction of ion chemistry.     

Nickel‐Catalyzed Tandem Reaction of Functionalized Arylacetonitriles with Arylboronic Acids in 2‐MeTHF: Eco‐Friendly Synthesis of Aminoisoquinolines and Isoquinolones

The first example of the nickel‐catalyzed tandem addition/cyclization of 2‐(cyanomethyl)benzonitriles with arylboronic acids in 2‐MeTHF has been developed, which provides the facile synthesis of aminoisoquinolines with good functional group tolerance under mild conditions. This chemistry has also been successfully applied to the synthesis of isoquinolones by the tandem reaction of methyl 2‐(cyanomethyl)benzoates with arylboronic acids. The use of the bio‐based and green solvent 2‐MeTHF as the reaction medium makes the synthesis process environmentally benign. The synthetic utility of this chemistry is also indicated by the synthesis of biologically active molecules.     

Synthesis of Triazenes with Nitrous Oxide

Triazenes are valuable compounds in organic chemistry and numerous applications have been reported. Furthermore, triazenes have been investigated extensively as potential antitumor drugs. Here, we describe a new method for the synthesis of triazenes. The procedure involves a reagent which is rarely used in synthetic organic chemistry: nitrous oxide (N₂O, “laughing gas”). Nitrous oxide mediates the coupling of lithium amides and organomagnesium compounds while serving as a nitrogen donor. Despite the very inert character of nitrous oxide, the reactions can be performed in solution under mild conditions. A key advantage of the new procedure is the ability to access triazenes with alkynyl and alkenyl substituents. These compounds are difficult to prepare by conventional methods because the required starting materials are unstable. Some of the new alkynyltriazenes were found to display high cytotoxicity in in vitro tests on ovarian and breast cancer cell lines.     

Isa‒NHC‒catalyzed intermolecular Stetter reaction of aromatic aldehydes with maleimides: An efficient access to 3‒aroylsuccinimides

An intermolecular Stetter reaction of aromatic aldehydes with maleimides has been developed using thiazolylidene salt derived Isa?NHC as an efficient organocatalyst. The synthesized Stetter products “3?aroylsuccinimides” are important building blocks for the synthesis of natural products and bioactive compounds. The reaction conditions are mild, and various substituents on aromatic aldehyde and maleimide nitrogen were tolerated.     

Palladium-Catalyzed Direct Carbonylation of Bromoacetonitrile to Synthesize 2-Cyano-N-acetamide and 2-Cyanoacetate Compounds

Nitrile compounds containing ester and amide groups are important functionalized chemicals in synthetic and medicinal chemistry. In this article, an efficient and convenient palladium-catalyzed carbonylative procedure toward 2-cyano-N-acetamide and 2-cyanoacetate compounds has been developed. The reaction proceeds under mild conditions via radical intermediate which is suitable for late-stage functionalization. Gram-scale experiment was performed successfully under low catalyst loading and gave the target product in excellent yield. Additionally, this transformation can be performed under atmospheric pressure and provide alternative routes to 7 drug precursors.     

Biocatalytic Oxidation Reactions: A Chemist's Perspective

Oxidation chemistry using enzymes is approaching maturity and practical applicability in organic synthesis. Oxidoreductases (enzymes catalysing redox reactions) enable chemists to perform highly selective and efficient transformations ranging from simple alcohol oxidations to stereoselective halogenations of non‐activated C?H bonds. For many of these reactions, no “classical” chemical counterpart is known. Hence oxidoreductases open up shorter synthesis routes based on a more direct access to the target products. The generally very mild reaction conditions may also reduce the environmental impact of biocatalytic reactions compared to classical counterparts. In this Review, we critically summarise the most important recent developments in the field of biocatalytic oxidation chemistry and identify the most pressing bottlenecks as well as promising solutions.