Your search keyword '"Keutz, Timo"' showing total 13 results

1. Continuous flow multistep synthesis of α-functionalized esters via lithium enolate intermediates

Author

von Keutz, Timo, Strauss, Franz J., Cantillo, David, and Kappe, C. Oliver

Published

2018

2. Enhanced mixing of biphasic liquid-liquid systems for the synthesis of gem-dihalocyclopropanes using packed bed reactors

Author

von Keutz, Timo, Cantillo, David, and Kappe, C. Oliver

Published

2019

3. Generation and Utilization of Highly Reactive Organometallic Intermediates Using Continuous Flow Technology

Author

von Keutz, Timo

Abstract

Kontinuierliche Durchflusschemie ist ein wertvolles Werkzeug in der organischen Chemie, welche den operativen Horizont erweitert und neue synthetische Routen ermöglicht. Die Bezeichnung „Durchflusschemie“ wird oft mit der Mikroreaktortechnologie in Verbindung gebracht, welche wesentliche Vorteile im Vergleich zu traditionellen Rührkesseln bietet, wie beispielsweise ein sehr schnelles Mischverhalten, effiziente Wärmeübertragung, präzise Steuerung der Reaktionszeit und eine unkomplizierte Skalierbarkeit. Diese einmalige Konstellation an Vorteilen wird konzeptionell in der Flash Chemie verwendet, um extrem schnelle und exotherme Transformationen zu kontrollieren und gezielt zu steuern. In dieser Doktorarbeit wurde mithilfe modernster Mikroreaktortechnologie ein komplexer metallorganischer Schlüsselschritt für die Herstellung von Remdesivir erforscht. Unter Verwendung von Grignard Reagenzien und Lithiumorganylen wurden zwei Strategien entwickelt, welche moderate Reaktionstemperaturen und eine robuste Reaktionsführung ermöglichen. Diese Strategien wurden unter Berücksichtigung der Skalierbarkeit entworfen, da Remdesivir ein Medikament für die Behandlung von COVID 19 eingesetzt wird. Das Konzept der Flash Chemie wurde zudem verwendet, um kontinuierliche Methoden für die Erzeugung und Verwendung von hochreaktiven und kurzlebigen metallorganischen Intermediaten. Durch gewissenhafte Auswahl des Durchflussequipments und präziser Abstimmung der Reaktionsparameter wurden C-1 Carbenoiden mittels Metall-Halogen Austausch generiert, welche anschließend mit Ketonen oder Aldehyden jeweils zu entsprechenden Epoxiden oder Halohydrinen umgesetzt wurden. Im weiteren Verlauf wurde dieses Verfahren angewendet, um eine neuartige und ertragsreiche Syntheseroute für Fluconazol zu entwickeln, welche die Epoxidbildung als zentralen Schritt beinhaltet. Continuous Flow Chemistry is a powerful tool in organic synthesis, which broadens the operational window and enables novel synthetic pathways. The term “flow chemistry” often refers to microreactor technology, which provides significant advantages over traditional batch reactors, such as rapid mixing, efficient heat transfer, precise residence time control and a straightforward scalability. These unique advantages are utilized in the concept of Flash Chemistry to conduct extremely fast and exothermic transformations in a highly controlled and selective manner.Within this doctoral thesis, state-of-the-art flow microreactor technology was employed to successfully furnish a key building block for the synthesis of Remdesivir in a rapid organometallic process. Two different strategies utilizing Grignard- or organolithium species were developed, enabling the use of moderate temperatures for this highly exothermic chemical transformation. Microreactor technology also permitted stable processing in a scalable environment, since Remdesivir is an urgently needed active pharmaceutical ingredient (API) for the treatment of COVID-19. The concept of Flash Chemistry was used to develop continuous methodologies for the generation and utilization of highly reactive and short-lived organometallic intermediates. Careful selection of the continuous flow equipment and precise adjustment of the reaction parameters enabled the preparation of C-1 carbenoids via metal-halogen exchange to furnish epoxides or halohydrins from corresponding ketones or aldehydes. This procedure was further applied towards the preparation of Fluconazole, which allowed for establishing a novel and high yielding synthetic route, featuring the key epoxidation step. Arbeit an der Bibliothek noch nicht eingelangt - Daten nicht geprüft Abweichender Titel laut Übersetzung des Verfassers/der Verfasserin Karl-Franzens-Universität Graz, Dissertation, 2021 (VLID)5805919

Published

2021

4. Flash Chemistry Approach to Organometallic C-Glycosylation for the Synthesis of Remdesivir

Author

von Keutz, Timo, primary, Williams, Jason D., additional, and Kappe, C. Oliver, additional

Published

2021

5. Flow Technology for Telescoped Generation, Lithiation and Electrophilic (C3) Functionalization of Highly Strained 1‐Azabicyclo[1.1.0]butanes

Author

Musci, Pantaleo, primary, von Keutz, Timo, additional, Belaj, Ferdinand, additional, Degennaro, Leonardo, additional, Cantillo, David, additional, Kappe, C. Oliver, additional, and Luisi, Renzo, additional

Published

2021

6. Flow Technology for Telescoped Generation, Lithiation and Electrophilic (C 3 ) Functionalization of Highly Strained 1‐Azabicyclo[1.1.0]butanes

Author

Musci, Pantaleo, primary, Keutz, Timo, additional, Belaj, Ferdinand, additional, Degennaro, Leonardo, additional, Cantillo, David, additional, Kappe, C. Oliver, additional, and Luisi, Renzo, additional

Published

2021

7. Continuous Flow C-Glycosylation via Metal–Halogen Exchange: Process Understanding and Improvements toward Efficient Manufacturing of Remdesivir

Author

von Keutz, Timo, primary, Williams, Jason D., additional, and Kappe, C. Oliver, additional

Published

2020

8. Organomagnesium Based Flash Chemistry: Continuous Flow Generation and Utilization of Halomethylmagnesium Intermediates

Author

von Keutz, Timo, primary, Cantillo, David, additional, and Kappe, C. Oliver, additional

Published

2020

9. Continuous Flow Synthesis of Terminal Epoxides from Ketones Using in Situ Generated Bromomethyl Lithium

Author

von Keutz, Timo, primary, Cantillo, David, additional, and Kappe, C. Oliver, additional

Published

2019

10. Flow Technology for Telescoped Generation, Lithiation and Electrophilic (C3) Functionalization of Highly Strained 1‐Azabicyclo[1.1.0]butanes.

Author

Musci, Pantaleo, Keutz, Timo, Belaj, Ferdinand, Degennaro, Leonardo, Cantillo, David, Kappe, C. Oliver, and Luisi, Renzo

Subjects

*BUTANE, *LITHIATION, *FLOW chemistry, *HIGH temperatures, *MOIETIES (Chemistry)

Abstract

Strained compounds are privileged moieties in modern synthesis. In this context, 1‐azabicyclo[1.1.0]butanes are appealing structural motifs that can be employed as click reagents or precursors to azetidines. We herein report the first telescoped continuous flow protocol for the generation, lithiation, and electrophilic trapping of 1‐azabicyclo[1.1.0]butanes. The flow method allows for exquisite control of the reaction parameters, and the process operates at higher temperatures and safer conditions with respect to batch mode. The efficiency of this intramolecular cyclization/C3‐lithiation/electrophilic quenching flow sequence is documented with more than 20 examples. [ABSTRACT FROM AUTHOR]

Published

2021

11. Rapid Asymmetric Synthesis of Disubstituted Allenes by Coupling of Flow-Generated Diazo Compounds and Propargylated Amines

Author

Poh, Jian-Siang, primary, Makai, Szabolcs, additional, von Keutz, Timo, additional, Tran, Duc N., additional, Battilocchio, Claudio, additional, Pasau, Patrick, additional, and Ley, Steven V., additional

Published

2017

12. Enhanced mixing of biphasic liquid-liquid systems for the synthesis of gem-dihalocyclopropanes using packed bed reactors

Author

Keutz, Timo, Cantillo, David, and Kappe, C.

Abstract

A continuous flow procedure for the gem-dichlorocyclopropanation of alkenes has been developed. The method is based on the generation of dichlorocarbene utilizing the classical biphasic aqueous sodium hydroxide/chloroform system. This reaction typically requires vigorous stirring for several hours in batch for completion. Tarry materials precipitate due to partial polymerization of dichlorocarbene and the process is difficult to scale. To overcome these problems and achieve very efficient mixing during the flow process a column reactor packed with PTFE beads as inert filling material has been used. PTFE beads have been found to be the optimal material to obtain fine dispersions of the aqueous phase in the organic solution. By heating the packed-bed reactor at 80 °C excellent conversions have been achieved after a residence time of only 4 min. The process has been applied for the synthesis of Ciprofibrate, a dichlorocyclopropane-containing drug used as treatment for several diseases associated with high lipid content in blood.

Published

2019

13. Rapid Asymmetric Synthesis of Disubstituted Allenes by Coupling of Flow-Generated Diazo Compounds and Propargylated Amines

Author

Poh, Jian-Siang, Makai, Szabolcs, Von Keutz, Timo, Tran, Duc N, Battilocchio, Claudio, Pasau, Patrick, and Ley, Steven V

Subjects

34 Chemical Sciences, 3405 Organic Chemistry, 3. Good health