Reductive Ring Opening Research Articles

Adaptable Synthesis of Chondroitin Sulfate Disaccharide Subtypes Preprogrammed for Regiospecific O‐Sulfation

AbstractA divergent synthetic route to chondroitin sulfate (CS) disaccharide precursors, including rarer subtypes such as CS−D, has been developed. From common intermediates, a series of thioglycoside D‐glucosyl donors and 4,6‐O‐benzylidene protected D‐galactosamine acceptors are utilised in a robust glycosylation reaction, achieving β‐selectivity and consistent yields (60–75 %) on scales >2.0 g. A post‐glycosylation oxidation to D‐glucuronic acid and orthogonal protecting groups delivers access to CS−A, CS−C, CS−D, CS−E and CS−O precursor subtypes. Of further note is a 4‐O‐benzyl regioselective reductive ring opening of a 4,6‐O‐benzylidene protected disaccharide using dichlorophenylborane (PhBCl2) and triethylsilane (Et3SiH) to access a CS−D precursor, in 73 % yield over two steps. Finally, synthesis of a 6‐O‐sulfated CS−C disaccharide containing a conjugable anomeric allyl tether is completed. These materials will provide a benchmark to further synthesise and study chondroitin sulfates.

B2(OH)4-Mediated Reductive Ring-Opening of N-Tosyl Aziridines by Nitroarenes: A Green and Regioselective Access to Vicinal Diamines.

The nucleophilic ring-opening of aziridine derivatives provides an important synthetic tool for the preparation of various β-functionalized amines. Amines as nucleophiles are employed to prepare synthetically useful 1,2-diamines in the presence of various catalysts or activators. Herein, the B2(OH)4-mediated reductive ring-opening transformation of N-tosyl aziridines by nitroarenes was developed. This aqueous protocol employed nitroarenes as cheap and readily available amino sources and proceeds under external catalyst-free conditions. Control experiments and DFT calculations pointed to the in situ reduction of nitroarenes to aryl amines via N-aryl boramidic acid (E) and an SN1-type ring-opening of N-tosylaziridines by the resultant aryl amines with high regioselectivity.

A Flexible Synthesis of Polypropionates via Diastereodivergent Reductive Ring-Opening of Trisubstituted Secondary Glycidols.

Polypropionates, characterized by their alternating sequence of stereocenters bearing methyl- and hydroxy-groups, are structurally diverse natural products of utmost importance.[1] Herein, we introduce a novel concept approach towards polypropionate synthesis featuring a diastereodivergent reductive epoxide-opening as a key step. Readily available and stereochemically uniform trisubstituted sec-glycidols serve as branching points for the highly selective synthesis of all isomers of polypropionate building blocks with three or more consecutive stereocenters. Stereodiversification is accomplished by an unprecedented mechanism-control over the stereochemically complementary modification of the epoxide's tertiary C-atom with excellent control of regio- and stereoselectivity. Since our method is not only suited for the preparation of specific targets but also for compound libraries, it will have a great impact on polypropionate synthesis.

Synthetic studies towards volvalerenol A: access to a fully functionalized cycloheptane framework in an asymmetric fashion through the exploitation of C2-symmetry.

The enantioselective synthesis of a fully functionalized cycloheptane core of the naturally occurring triterpenoid volvalerenol A, exhibiting pseudo-C2 symmetry, was achieved. Enantioselective enzymatic desymmetrization (EED), asymmetric methallylation, and reductive ring opening of an cyclopropane overbred intermediate were the key reactions to access the cycloheptanone core. Further synthetic manipulations, via a unique "MPV" (Meerwein-Ponndorf-Verley) type reductive ring-opening of an epoxide and other synthetic transformations, afforded two fully functionalized cycloheptane frameworks of the target molecule.

Regioselective Ring-Opening of Terminal Epoxides Catalyzed by a Porous Metal Silicate Material.

Reductive ring-opening of epoxides is a green pathway for synthesizing highly value-added alcohols. In this study, we present a practically applicable approach for the synthesis of anti-Markovnikov-type alcohols with high yields from aliphatic and aromatic epoxides under mild conditions by developing porous metal silicate (PMS) catalysts. A PMS material PMS-20 consists of cobalt and nickel bimetal redox-active sites, exhibiting exceptional catalytic activity and selectivity in the reductive ring-opening of terminal epoxides with >99% yield of primary alcohols. Comparing with the existing methods using noble metals, PMS-20 exhibits broad substrate scope and excellent functional group tolerance by synergistic work between cobalt and nickel species, which is clarified by dual chamber cell system characterization and theoretical calculation results.

An efficient synthesis of optically active herbicide (S)-metolachlor via reductive ring opening of 2-methoxymethylaziridine

An efficient synthesis of optically active herbicide (S)-metolachlor via reductive ring opening of 2-methoxymethylaziridine

Enantioselective radical cascade cyclization via Ti-catalyzed redox relay

Radical cascade cyclization reactions provide an efficient method for the construction of polycyclic architectures with multiple stereogenic centers. However, achieving enantioselectivity control of this type of reaction is a challenging task. Here, we report an enantioselective cyclization of polyfunctional aryl cyclopropyl ketone and alkyne units, wherein the stereochemical outcome is directed by a chiral Ti(salen) catalyst. This transformation was proposed to proceed via a radical cascade process involving the reductive ring-opening of the cyclopropyl ketone followed by two annulation events entailing cyclization of the ensuing alkyl radical onto the alkyne and subsequent addition of the incipient vinyl radical to the Ti(IV)-enolate.

Integrating Process Development and Safety Analysis for Scale-Up of a Diborane-Generating Reduction Reaction

Our company has developed a robust and scalable process to synthesize an amino alcohol tosylate salt, a penultimate intermediate in the synthesis of nemtabrutinib. A key reaction in this synthetic sequence is a reductive acetal ring opening using boron trifluoride diethyl etherate as a Lewis acid and triethylsilane as the reducing agent. Detailed mechanistic inquisition revealed that in the presence of sulfolane, boron trifluoride is reduced by triethylsilane to generate diborane as the active reductant. Diborane poses many process safety hazards; it is highly reactive, flammable, and acutely toxic. The reaction headspace was studied using infrared spectroscopy and gas chromatography, while the reaction stream was studied using heat flow and adiabatic calorimetry to ensure safe scale-up of the process. Process understanding demonstrated that containing diborane within the reactor was essential to control key impurities. Extensive development efforts were directed to design a process that could safely sequester the hazardous gas. Herein, we describe the process safety analysis, the optimization, and the scale-up of the reduction reaction and the isolation, producing two batches of the amino alcohol tosylate salt with high purity at a pilot scale.

Iron-Catalyzed Reductive Ring Opening/gem-Difluoroallylation of Cyclopropyl Ketones.

By merging C-C and C-F bond cleavage, we developed a regioselective ring opening/gem-difluoroallylation of cyclopropyl ketones with α-trifluoromethylstyrenes, which proceeds under the catalysis of iron with the combination of manganese and TMSCl as the reducing agents, providing a new entry to the synthesis of carbonyl-containing gem-difluoroalkenes. Remarkably, the ketyl radical-induced selective C-C bond cleavage and the following generation of more-stable carbon-centered radicals enable complete regiocontrol of this ring opening reaction for various substitution patterns of the cyclopropane ring.

B(C6 F5 )3 -Catalyzed Regioselective Ring Opening of Cyclic Amines with Hydrosilanes.

Opening the ring of cyclic amines by regioselective fission of one of the carbon-nitrogen bonds greatly expands the repertoire of available nitrogen-containing skeletons. Unlike approaches starting from cyclic tertiary amines, methods that can directly open secondary amines are still scarce. The present work discloses an efficient reductive ring opening of either of these cyclic amines using PhSiH3 under B(C6 F5 )3 catalysis. By this, the direct transformation of unstrained cyclic amines into the corresponding acyclic amines is achieved in a simple one-pot operation. A stepwise mechanism proceeding through the intermediacy of silylammonium ions followed by reductive cleavage of a carbon-nitrogen bond was experimentally verified.

Nickel-catalyzed reductive asymmetric alkylative ring opening of oxa- and azabicyclic alkenes

Nickel-catalyzed reductive asymmetric alkylative ring opening of oxa- and azabicyclic alkenes

Reductive opening of a cyclopropane ring in the Ni(II) coordination environment: a route to functionalized dehydroalanine and cysteine derivatives

The involvement of an α,α-cyclopropanated amino acid in the chiral Ni(II) coordination environment in the form of a Schiff base is considered as a route to electrochemical broadening of the donor–acceptor cyclopropane concept in combination with chirality induction in the targeted products. A tendency to the reductive ring-opening and the follow-up reaction paths of thus formed radical anions influenced by substituents in the cyclopropane ring are discussed. Optimization of the reaction conditions opens a route to the non-proteinogenic amino acid derivatives containing an α–β or β–γ double C=C bond in the side chain; the regioselectivity can be tuned by the addition of Lewis acids. One-pot combination of the reductive ring opening and subsequent addition of thiols allows obtaining the cysteine derivatives in practical yields and with high stereoselectivity at the removed β-stereocenter.

Cobalt-catalyzed ring expansion/ring opening of oxetanes using phosphine oxides as promoters under hydroformylation conditions

Phosphine oxides, especially tricyclohexylphosphine oxide (P7), promote the cobalt catalyzed carbonylative ring expansion and reductive ring opening reaction of oxetanes under syngas atmosphere. Depending on the substrate structure and the stability of the carbocation intermediate either γ-lactones or primary alcohols are obtained in moderate to excellent yields. Syngas proved to play a crucial role for the catalyst activity and its stability in this process. Green solvents with high sustainability rankings, such as dimethyl carbonate (DMC), can be used in replacement of traditional solvents. The optimized conditions for both procedures were substrate (1 mmol), Co2(CO)8 (2 mol%), DMC (2 mL), 100 °C, gas phase – CO/H2 (1:1) 40 atm, 24 h resulting in the yields of 56–94% in the ring expansion, and 65–94% in the ring opening of oxetanes.

Flavin-enabled reductive and oxidative epoxide ring opening reactions

Epoxide ring opening reactions are common and important in both biological processes and synthetic applications and can be catalyzed in a non-redox manner by epoxide hydrolases or reductively by oxidoreductases. Here we report that fluostatins (FSTs), a family of atypical angucyclines with a benzofluorene core, can undergo nonenzyme-catalyzed epoxide ring opening reactions in the presence of flavin adenine dinucleotide (FAD) and nicotinamide adenine dinucleotide (NADH). The 2,3-epoxide ring in FST C is shown to open reductively via a putative enol intermediate, or oxidatively via a peroxylated intermediate with molecular oxygen as the oxidant. These reactions lead to multiple products with different redox states that possess a single hydroxyl group at C-2, a 2,3-vicinal diol, a contracted five-membered A-ring, or an expanded seven-membered A-ring. Similar reactions also take place in both natural products and other organic compounds harboring an epoxide adjacent to a carbonyl group that is conjugated to an aromatic moiety. Our findings extend the repertoire of known flavin chemistry that may provide new and useful tools for organic synthesis.

Reductive Ring Opening of Epoxides under Dual Zirconocene and Photoredox Catalysis

Reductive Ring Opening of Epoxides under Dual Zirconocene and Photoredox Catalysis

CdS Quantum Dots as Potent Photoreductants for Organic Chemistry Enabled by Auger Processes.

Strong reducing agents (<-2.0 V vs saturated calomel electrode (SCE)) enable a wide array of useful organic chemistry, but suffer from a variety of limitations. Stoichiometric metallic reductants such as alkali metals and SmI2 are commonly employed for these reactions; however, considerations including expense, ease of use, safety, and waste generation limit the practicality of these methods. Recent approaches utilizing energy from multiple photons or electron-primed photoredox catalysis have accessed reduction potentials equivalent to Li0 and shown how this enables selective transformations of aryl chlorides via aryl radicals. However, in some cases, low stability of catalytic intermediates can limit turnover numbers. Herein, we report the ability of CdS nanocrystal quantum dots (QDs) to function as strong photoreductants and present evidence that a highly reducing electron is generated from two consecutive photoexcitations of CdS QDs with intermediate reductive quenching. Mechanistic experiments suggest that Auger recombination, a photophysical phenomenon known to occur in photoexcited anionic QDs, generates transient thermally excited electrons to enable the observed reductions. Using blue light-emitting diodes (LEDs) and sacrificial amine reductants, aryl chlorides and phosphate esters with reduction potentials up to -3.4 V vs SCE are photoreductively cleaved to afford hydrodefunctionalized or functionalized products. In contrast to small-molecule catalysts, QDs are stable under these conditions and turnover numbers up to 47 500 have been achieved. These conditions can also effect other challenging reductions, such as tosylate protecting group removal from amines, debenzylation of benzyl-protected alcohols, and reductive ring opening of cyclopropane carboxylic acid derivatives.

Catalytic reductive ring opening of epoxides enabled by zirconocene and photoredox catalysis

Catalytic reductive ring opening of epoxides enabled by zirconocene and photoredox catalysis

Nickel-Catalyzed Regioselective Reductive Ring Opening of Aryl Cyclopropyl Ketones with Alkyl Bromides

Nickel-Catalyzed Regioselective Reductive Ring Opening of Aryl Cyclopropyl Ketones with Alkyl Bromides

Species differences between rats and primates (humans and monkeys) in complex cleavage pathways of DS-8500a characterized by 14C-ADME studies in humans and monkeys after administration of two radiolabeled compounds and in vitro studies

Our previous study in rats demonstrated that the metabolic pathways of DS-8500a, a novel GPR119 agonist, include cleavage pathways: reductive cleavage of the oxadiazole ring in the liver and hydrolysis of the amide side chain. In the present study, in vivo metabolic profiling in humans and monkeys after the oral administration of two 14C-labeled compounds was performed to investigate species differences of the cleavage pathways. In monkeys, the oxadiazole ring-cleaved metabolites were mainly detected in feces, but not observed in bile, unlike in rats, suggesting that the reductive ring-opening metabolism occurs in the gastrointestinal tract. In vitro incubation with enterobacterial culture media demonstrated that the reductive cleavage of the oxadiazole ring in humans and monkeys was considerably faster than that in rats. The other cleavage metabolite (M20), produced via hydrolysis of the amide side chain, was detected as the major plasma metabolite in humans and monkeys, and its subsequent metabolite (M21) was excreted in feces, whereas M21 was not a major component in rats, indicating a notable species difference in the amide hydrolysis. In conclusion, this study comprehensively revealed the pronounced species difference of the cleavage pathways: reductive ring-opening by intestinal microflora and liver, and amide hydrolysis.

Reductive Ring Opening of Arylcyclopropanecarboxamides Accompanied by Borylation and Enolate Formation.

Treatment of arylcyclopropanecarboxamides with a sodium dispersion in the presence of methoxypinacolborane as a reduction-resistant electrophile leads to reductive cleavage of the cyclopropane ring followed by instant trapping with the boron electrophile to yield the enolates of γ-aryl-γ-borylalkanamides. The enolates react further with a different electrophile to yield the corresponding α-substituted amides with anti selectivity.