Your search keyword '"Katayev A"' showing total 7 results

1. Mechanochemistry Drives Alkene Difunctionalization via Radical Ligand Transfer and Electron Catalysis

Author

Subrata Patra, Bhargav N. Nandasana, Vasiliki Valsamidou, and Dmitry Katayev

Subjects

electron catalysis, mechanochemistry, nitration, olefin difunctionalization, radical ligand transfer (RLT), Science

Abstract

Abstract A general and modular protocol is reported for olefin difunctionalization through mechanochemistry, facilitated by cooperative radical ligand transfer (RLT) and electron catalysis. Utilizing mechanochemical force and catalytic amounts of 2,2,6,6‐tetramethylpiperidinyloxyl (TEMPO), ferric nitrate can leverage nitryl radicals, transfer nitrooxy‐functional group via RLT, and mediate an electron catalysis cycle under room temperature. A diverse range of activated and unactivated alkenes exhibited chemo‐ and regioselective 1,2‐nitronitrooxylation under solvent‐free or solvent‐less conditions, showcasing excellent functional group tolerance. Mechanistic studies indicated a significant impact of mechanochemistry and highlighted the radical nature of this nitrative difunctionalization process.

Published

2024

2. Mechanochemistry Drives Alkene Difunctionalization via Radical Ligand Transfer and Electron Catalysis.

Author

Patra, Subrata, Nandasana, Bhargav N., Valsamidou, Vasiliki, and Katayev, Dmitry

Subjects

ELECTRON-transfer catalysis, RADICALS (Chemistry), FERRIC nitrate, MECHANICAL chemistry, FUNCTIONAL groups

Abstract

A general and modular protocol is reported for olefin difunctionalization through mechanochemistry, facilitated by cooperative radical ligand transfer (RLT) and electron catalysis. Utilizing mechanochemical force and catalytic amounts of 2,2,6,6‐tetramethylpiperidinyloxyl (TEMPO), ferric nitrate can leverage nitryl radicals, transfer nitrooxy‐functional group via RLT, and mediate an electron catalysis cycle under room temperature. A diverse range of activated and unactivated alkenes exhibited chemo‐ and regioselective 1,2‐nitronitrooxylation under solvent‐free or solvent‐less conditions, showcasing excellent functional group tolerance. Mechanistic studies indicated a significant impact of mechanochemistry and highlighted the radical nature of this nitrative difunctionalization process. [ABSTRACT FROM AUTHOR]

Published

2024

3. Divergent functionalization of alkenes enabled by photoredox activation of CDFA and α-halo carboxylic acids.

Author

Giri, Rahul, Zhilin, Egor, and Katayev, Dmitry

Published

2024

4. Simplifying Nitration Chemistry with Bench-stable Organic Nitrating Reagents

Author

Patra, Subrata, primary, Valsamidou, Vasiliki, additional, and Katayev, Dmitry, additional

Published

2024

5. Feasibility of using real-world free thyroxine data from the US and Europe to enable fast and efficient transfer of reference intervals from one population to another

Author

Kurka, Hedwig, primary, Dilba, Peter, additional, Perez, Carlos Castillo, additional, Findeisen, Peter, additional, Gironés, Ignacio Gadea, additional, Katayev, Alex, additional, Alonso, Laura Rodríguez, additional, Valcour, André, additional, Rehberg, Thorsten, additional, Weber, Benedikt, additional, Donner, Horst, additional, and Thorenz, Anja, additional

Published

2024

6. Feasibility of using real-world free thyroxine data from the US and Europe to enable fast and efficient transfer of reference intervals from one population to another

Author

Hedwig Kurka, Peter Dilba, Carlos Castillo Perez, Peter Findeisen, Ignacio Gadea Gironés, Alex Katayev, Laura Rodríguez Alonso, André Valcour, Thorsten Rehberg, Benedikt Weber, Horst Donner, and Anja Thorenz

Subjects

Reference intervals, Real-world data, Free thyroxine, Indirect approach, Direct approach, Medicine (General), R5-920, Chemistry, QD1-999

Abstract

Objectives: The direct approach for determining reference intervals (RIs) is not always practical. This study aimed to generate evidence that a real-world data (RWD) approach could be applied to transfer free thyroxine RIs determined in one population to a second population, presenting an alternative to performing multiple RI determinations. Design and methods: Two datasets (US, n = 10,000; Europe, n = 10,000) were created from existing RWD. Descriptive statistics, density plots and cumulative distributions were produced for each data set and comparisons made. Cumulative probabilities at the lower and upper limits of the RIs were identified using an empirical cumulative distribution function. According to these probabilities, estimated percentiles for each dataset and estimated differences between the two sets of percentiles were obtained by case resampling bootstrapping. The estimated differences were then evaluated against a pre-determined acceptance criterion of ≤7.8% (inter-individual biological variability). The direct approach was used to validate the RWD approach. Results: The RWD approach provided similar descriptive statistics for both populations (mean: US = 16.1 pmol/L, Europe = 16.4 pmol/L; median: US = 15.4 pmol/L, Europe = 15.8 pmol/L). Differences between the estimated percentiles at the upper and lower limits of the RIs fulfilled the pre-determined acceptance criterion and the density plots and cumulative distributions demonstrated population homogeneity. Similar RI distributions were observed using the direct approach. Conclusions: This study provides evidence that a RWD approach can be used to transfer RIs determined in one population to another.

Published

2024

7. Simplifying Nitration Chemistry with Bench-stable Organic Nitrating Reagents

Author

Subrata Patra, Vasiliki Valsamidou, and Dmitry Katayev

Subjects

Nitration, Nitronium ion, Nitryl radicals, Organic nitrating reagent, Photoredox, Chemistry, QD1-999

Abstract

Nitro compounds play a crucial role in academia and industries, serving as building blocks for the synthesis of drugs, agrochemicals, and materials. Nitration, a fundamental process in organic synthesis, has undergone significant evolution since the 19th century. While electrophilic nitration dominates historically, recent decades have seen a focus on new reagents and their reactivity modes for achieving mild and robust synthesis of nitro compounds. Our group has a longstanding interest in developing cost-effective, readily available, recyclable nitrating reagents derived from organic scaffolds. These reagents serve as a controllable source of nitryl radical and nitronium ion species, enabling mild and practical nitration of hydrocarbons with exceptional functional group tolerance. This account details the development of nitrating reagents and their diverse applications in catalytic nitration across various classes of organic molecules.

Published

2024