Abstract
Polymeric assemblies, such as micelles, are gaining increasing attention due to their ability to serve as nanoreactors for the execution of organic reactions in aqueous media. The ability to conduct organic transformations, which have been traditionally limited to organic media, in water is essential for the further development of important fields ranging from green catalysis to bioorthogonal chemistry. Considering the recent progress that has been made to expand the range of organometallic reactions conducted using nanoreactors, we aimed to gain a deeper understanding of the roles of the hydrophobicity of both the core of micellar nanoreactors and the substrates on the reaction rates in water. Toward this goal, we designed a set of five metal-loaded micelles composed of polyethylene glycol–dendron amphiphiles and studied their ability to serve as nanoreactors for a palladium-mediated depropargylation reaction of four substrates with different log P values. Using dendrons as the hydrophobic block, we could precisely tune the lipophilicity of the nanoreactors, which allowed us to reveal linear correlations between the rate constants and the hydrophobicity of the amphiphiles (estimated by the dendron’s cLog P). While exponential dependence was obtained for the lipophilicity of the substrates, a similar degree of rate acceleration was observed due to the increase in the hydrophobicity of the amphiphiles regardless of the effect of the substrate’s log P. Our results demonstrate that while increasing the hydrophobicity of the substrates may be used to accelerate reaction rates, tuning the hydrophobicity of the micellar nanoreactors can serve as a vital tool for further optimization of the reactivity and selectivity of nanoreactors.
Highlights
While an aqueous environment is essential for all living systems, using water as a solvent does not necessarily translate well for conducting organic reactions, in organometallic chemistry
The thiol-yne reaction of the dialkyne-functionalized monofunctional polyethylene glycol (mPEG) with five different linear aliphatic thiols with lengths ranging from 6 to 14 carbons allowed us to produce a dendritic structure containing two 1,2 di-mercapto ether moieties in each dendron (Scheme 1). 1H NMR, size exclusion chromatography (SEC), high-performance liquid chromatography (HPLC), and matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS) measurements were used to verify the synthetic aX refers to the number of carbons at the aliphatic chain
To systematically evaluate the influence of changes in the lipophilicity of the nanoreactor on the reaction rates, we synthesized a small library of five amphiphiles and precisely tuned their hydrophobicity by varying the length of their aliphatic end-groups
Summary
While an aqueous environment is essential for all living systems, using water as a solvent does not necessarily translate well for conducting organic reactions, in organometallic chemistry. The development of methodologies for conducting organic reactions in aqueous media has a significant influence on various fields, from synthetic biology and therapeutic biomaterials to green chemistry.[1−9]. Polymeric micelles can act as nanometer-sized flasks for conducting organic reactions in water.[10] Micelles can provide the solubility and protective environment for the lipophilic reactants, shielding them from the surrounding aqueous environment.[11,12] In recent years, significant progress in conducting organic transformation and organometallic reactions in water has been reported by Lipshutz,[12−17] Meijer,[3,18,19] Unciti-Broceta,[5,20−24] Zimmerman,[25−27] O’Reilly,[28,29] and others.[30−34] The ability to perform organometallic reactions in aqueous media can contribute significantly to increasing the sustainability of organic synthesis by reducing the usage of organic solvents. Despite the great progress in this field, the rational design of micellar systems as nanoreaction vessels is still a huge chemical challenge, mostly due to the lack of broader knowledge of the structure−activity relations of these systems
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