Conducting Polymer Microcups for Organic Bioelectronics and Drug Delivery Applications

Martin Antensteiner; Milad Khorrami; Fatemeh Fallahianbijan; Ali Borhan; Mohammad Reza Abidian

doi:10.1002/adma.201702576

Conducting Polymer Microcups for Organic Bioelectronics and Drug Delivery Applications

Martin Antensteiner
, Milad Khorrami
, Fatemeh Fallahianbijan
, Ali Borhan
, Mohammad Reza Abidian

Chemical Engineering

Research output: Contribution to journal › Article › peer-review

33 Scopus citations

Abstract

An ideal neural device enables long-term, sensitive, and selective communication with the nervous system. To accomplish this task, the material interface should mimic the biophysical and the biochemical properties of neural tissue. By contrast, microfabricated neural probes utilize hard metallic conductors, which hinder their long-term performance because these materials are not intrinsically similar to soft neural tissue. This study reports a method for the fabrication of monodisperse conducting polymer microcups. It is demonstrated that the physical surface properties of conducting polymer microcups can be precisely modulated to control electrical properties and drug-loading/release characteristics.

Original language	English (US)
Article number	1702576
Journal	Advanced Materials
Volume	29
Issue number	39
DOIs	https://doi.org/10.1002/adma.201702576
State	Published - Oct 18 2017

All Science Journal Classification (ASJC) codes

General Materials Science
Mechanics of Materials
Mechanical Engineering

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10.1002/adma.201702576

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abstract = "An ideal neural device enables long-term, sensitive, and selective communication with the nervous system. To accomplish this task, the material interface should mimic the biophysical and the biochemical properties of neural tissue. By contrast, microfabricated neural probes utilize hard metallic conductors, which hinder their long-term performance because these materials are not intrinsically similar to soft neural tissue. This study reports a method for the fabrication of monodisperse conducting polymer microcups. It is demonstrated that the physical surface properties of conducting polymer microcups can be precisely modulated to control electrical properties and drug-loading/release characteristics.",

author = "Martin Antensteiner and Milad Khorrami and Fatemeh Fallahianbijan and Ali Borhan and Abidian, \{Mohammad Reza\}",

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AU - Khorrami, Milad

AU - Fallahianbijan, Fatemeh

AU - Borhan, Ali

AU - Abidian, Mohammad Reza

PY - 2017/10/18

Y1 - 2017/10/18

N2 - An ideal neural device enables long-term, sensitive, and selective communication with the nervous system. To accomplish this task, the material interface should mimic the biophysical and the biochemical properties of neural tissue. By contrast, microfabricated neural probes utilize hard metallic conductors, which hinder their long-term performance because these materials are not intrinsically similar to soft neural tissue. This study reports a method for the fabrication of monodisperse conducting polymer microcups. It is demonstrated that the physical surface properties of conducting polymer microcups can be precisely modulated to control electrical properties and drug-loading/release characteristics.

AB - An ideal neural device enables long-term, sensitive, and selective communication with the nervous system. To accomplish this task, the material interface should mimic the biophysical and the biochemical properties of neural tissue. By contrast, microfabricated neural probes utilize hard metallic conductors, which hinder their long-term performance because these materials are not intrinsically similar to soft neural tissue. This study reports a method for the fabrication of monodisperse conducting polymer microcups. It is demonstrated that the physical surface properties of conducting polymer microcups can be precisely modulated to control electrical properties and drug-loading/release characteristics.

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UR - https://www.scopus.com/pages/publications/85027891754#tab=citedBy

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Conducting Polymer Microcups for Organic Bioelectronics and Drug Delivery Applications

Abstract

All Science Journal Classification (ASJC) codes

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