Suppressing catalyst poisoning in the carbodiimide-fueled reaction cycle

14 July 2023, Version 1
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

In biology, cells regulate the function of molecules using catalytic reaction cycles that convert reagents with high chemical potential (fuel) to waste molecules. Inspired by biology, synthetic analogs of such chemical reaction cycles have been devised, and a widely used catalytic reaction cycle uses carboxylates as catalysts to accelerate the hydration of carbodiimides. The cycle is versatile and easy to use, so it is widely applied to regulate motors, pumps, self-assembly, and phase separation. However, the cycle suffers from side reactions, especially the formation of N-acylurea. In catalytic reaction cycles, side reactions are disastrous as they decrease the fuel’s efficiency and, more importantly, destroy the molecular machinery or assembling molecules. To put that in perspective, a side reaction that irreversibly converts as little as 1% of the fuel into a side product would mean less than 5% of the molecular machine left after 100 cycles. Therefore, this work tested how to suppress N-acylurea by screening precursor concentration, its structure, carbodiimide structure, additives, temperature, and pH. It turned out that the combination of low temperature, low pH, and 10% pyridine as a fraction of the fuel could significantly suppress the N-acylurea side product and keep the reaction cycle highly effective to regulate successful assembly. We anticipate that our work will provide guidelines for using carbodiimide-fueled reaction cycles to regulate molecular function about how to choose an optimal condition.

Keywords

Chemically fueled self-assembly
Self-assembly
Chemical reaction networks
chemical reaction cycles
Carboddimides

Supplementary materials

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