@article {360, title = {Synthetic Macrocycle Nanopore for Potassium-Selective Transmembrane Transport}, journal = {Journal of the American Chemical Society}, volume = {143}, year = {2021}, month = {08/2021}, pages = {15975-15983}, chapter = {15975}, abstract = {

Reproducing the structure and function of biological membrane channels, synthetic nanopores have been developed for applications in membrane filtration technologies and biomolecular sensing. Stable stand-alone synthetic nanopores have been created from a variety of materials, including peptides, nucleic acids, synthetic polymers, and solid-state membranes. In contrast to biological nanopores, however, furnishing such synthetic nanopores with an atomically defined shape, including deliberate placement of each and every chemical group, remains a major challenge. Here, we introduce a chemosynthetic macromolecule,\ extended pillararene macrocycle (EPM) as a chemically defined transmembrane nanopore that exhibits selective transmembrane transport. Our ionic current measurements reveal stable insertion of individual EPM nanopores into a lipid bilayer membrane and remarkable cation type-selective transport, with up to a 21-fold selectivity for potassium over sodium ions. Taken together, direct chemical synthesis offers a path to de novo design of a new class of synthetic nanopores with custom transport functionality imprinted in their atomically defined chemical structure.\ 

}, keywords = {Electrical conductivity, MD Simulations, Nanopores, Potassium Ions Selectivity}, doi = {10.1021/jacs.1c04910}, author = {Qiao, Dan and Joshi, Himanshu and Zhu, Huangtianzhi and Wang, Fushi and Xu, Yang and Gao, Jia and Huang, Feihe and Aleksei Aksimentiev and Feng, Jiandong} }