Summary
"Bio-inspired catalysis in aqueous coacervate droplets: towards a softer chemistry
Recent advancements in modern synthetic chemistry have aligned with the imperative of reducing environmental impact, driving the emergence of a more sustainable chemistry, inspired by nature. In organic chemistry, the formation of C-C bonds is pivotal but often necessitates the use of both metal and organic solvents. However, a non-enzymatic approach to forge C-C bonds in water has been demonstrated through the Stetter reaction, a bio-inspired process catalyzed by N-heterocyclic carbenes (NHC) and thiamin cofactor mimics. Due to their limited water solubility, organic substrates generate water-isolated organic droplets, effectively promoting the Stetter reaction despite NHC's sensitivity to hydrolysis. Our objective is to investigate the Stetter reaction within polymer-rich aqueous microdroplets known as ""coacervates,"" which emulate primitive models of early living cells. Similar to micellar chemistry, these droplets possess a hydrophobic inner core, facilitating the spontaneous uptake and accumulation of organic molecules. We hypothesize that coacervates can serve as microreactors for C-C bond synthesis, catalyzed by newly designed azolium-based organocatalysts compatible with coacervates. Our aim is to demonstrate in-situ C-C bond formation via a model Stetter reaction and explore the molecular mechanism, akin to an ""on-water"" environment, while considering the impact of coacervates' internal polarity on reaction kinetics, yield, and selectivity. Altogether, our findings will broaden horizons in sustainable bio-inspired chemistry, enhancing the soft chemistry toolbox and potentially inaugurating a new realm of research: bio-inspired organic synthesis within coacervates. Significantly, the chemical synthesis of complex molecules in coacervates could also shed light on mechanisms that could have led to the formation of Life’s molecules in protocells before enzymes emerged.
"
Recent advancements in modern synthetic chemistry have aligned with the imperative of reducing environmental impact, driving the emergence of a more sustainable chemistry, inspired by nature. In organic chemistry, the formation of C-C bonds is pivotal but often necessitates the use of both metal and organic solvents. However, a non-enzymatic approach to forge C-C bonds in water has been demonstrated through the Stetter reaction, a bio-inspired process catalyzed by N-heterocyclic carbenes (NHC) and thiamin cofactor mimics. Due to their limited water solubility, organic substrates generate water-isolated organic droplets, effectively promoting the Stetter reaction despite NHC's sensitivity to hydrolysis. Our objective is to investigate the Stetter reaction within polymer-rich aqueous microdroplets known as ""coacervates,"" which emulate primitive models of early living cells. Similar to micellar chemistry, these droplets possess a hydrophobic inner core, facilitating the spontaneous uptake and accumulation of organic molecules. We hypothesize that coacervates can serve as microreactors for C-C bond synthesis, catalyzed by newly designed azolium-based organocatalysts compatible with coacervates. Our aim is to demonstrate in-situ C-C bond formation via a model Stetter reaction and explore the molecular mechanism, akin to an ""on-water"" environment, while considering the impact of coacervates' internal polarity on reaction kinetics, yield, and selectivity. Altogether, our findings will broaden horizons in sustainable bio-inspired chemistry, enhancing the soft chemistry toolbox and potentially inaugurating a new realm of research: bio-inspired organic synthesis within coacervates. Significantly, the chemical synthesis of complex molecules in coacervates could also shed light on mechanisms that could have led to the formation of Life’s molecules in protocells before enzymes emerged.
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Web resources: | https://cordis.europa.eu/project/id/101152804 |
Start date: | 01-07-2024 |
End date: | 30-06-2026 |
Total budget - Public funding: | - 211 754,00 Euro |
Cordis data
Original description
"Bio-inspired catalysis in aqueous coacervate droplets: towards a softer chemistryRecent advancements in modern synthetic chemistry have aligned with the imperative of reducing environmental impact, driving the emergence of a more sustainable chemistry, inspired by nature. In organic chemistry, the formation of C-C bonds is pivotal but often necessitates the use of both metal and organic solvents. However, a non-enzymatic approach to forge C-C bonds in water has been demonstrated through the Stetter reaction, a bio-inspired process catalyzed by N-heterocyclic carbenes (NHC) and thiamin cofactor mimics. Due to their limited water solubility, organic substrates generate water-isolated organic droplets, effectively promoting the Stetter reaction despite NHC's sensitivity to hydrolysis. Our objective is to investigate the Stetter reaction within polymer-rich aqueous microdroplets known as ""coacervates,"" which emulate primitive models of early living cells. Similar to micellar chemistry, these droplets possess a hydrophobic inner core, facilitating the spontaneous uptake and accumulation of organic molecules. We hypothesize that coacervates can serve as microreactors for C-C bond synthesis, catalyzed by newly designed azolium-based organocatalysts compatible with coacervates. Our aim is to demonstrate in-situ C-C bond formation via a model Stetter reaction and explore the molecular mechanism, akin to an ""on-water"" environment, while considering the impact of coacervates' internal polarity on reaction kinetics, yield, and selectivity. Altogether, our findings will broaden horizons in sustainable bio-inspired chemistry, enhancing the soft chemistry toolbox and potentially inaugurating a new realm of research: bio-inspired organic synthesis within coacervates. Significantly, the chemical synthesis of complex molecules in coacervates could also shed light on mechanisms that could have led to the formation of Life’s molecules in protocells before enzymes emerged.
"
Status
SIGNEDCall topic
HORIZON-MSCA-2023-PF-01-01Update Date
24-11-2024
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