Membrane insertion of—and membrane potential sensing by—semiconductor voltage nanosensors: Feasibility demonstration

Kyoungwon Park; Yung Kuo; Volodymyr Shvadchak; Antonino Ingargiola; Xinghong Dai; Lawrence Hsiung; Wookyeom Kim; Hong Zhou; Peng Zou; Alex J. Levine; Jack Li; Shimon Weiss

doi:https://doi.org/10.1126/sciadv.1601453

Membrane insertion of—and membrane potential sensing by—semiconductor voltage nanosensors: Feasibility demonstration

Kyoungwon Park, Yung Kuo, Volodymyr Shvadchak, Antonino Ingargiola, Xinghong Dai, Lawrence Hsiung, Wookyeom Kim, Hong Zhou, Peng Zou, Alex J. Levine, Jack Li, Shimon Weiss

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

Abstract

We developed membrane voltage nanosensors that are based on inorganic semiconductor nanoparticles. We provide here a feasibility study for their utilization. We use a rationally designed peptide to functionalize the nanosensors, imparting them with the ability to self-insert into a lipid membrane with a desired orientation. Once inserted, these nanosensors could sense membrane potential via the quantum confined Stark effect, with a single-particle sensitivity. With further improvements, these nanosensors could potentially be used for simultaneous recording of action potentials from multiple neurons in a large field of view over a long duration and for recording electrical signals on the nanoscale, such as across one synapse.

Original language	English
Article number	e1601453
Pages (from-to)	e1601453
Journal	Science Advances
Volume	4
Issue number	1
DOIs	https://doi.org/10.1126/sciadv.1601453
State	Published - Jan 2018
Externally published	Yes

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title = "Membrane insertion of—and membrane potential sensing by—semiconductor voltage nanosensors: Feasibility demonstration",

abstract = "We developed membrane voltage nanosensors that are based on inorganic semiconductor nanoparticles. We provide here a feasibility study for their utilization. We use a rationally designed peptide to functionalize the nanosensors, imparting them with the ability to self-insert into a lipid membrane with a desired orientation. Once inserted, these nanosensors could sense membrane potential via the quantum confined Stark effect, with a single-particle sensitivity. With further improvements, these nanosensors could potentially be used for simultaneous recording of action potentials from multiple neurons in a large field of view over a long duration and for recording electrical signals on the nanoscale, such as across one synapse.",

author = "Kyoungwon Park and Yung Kuo and Volodymyr Shvadchak and Antonino Ingargiola and Xinghong Dai and Lawrence Hsiung and Wookyeom Kim and Hong Zhou and Peng Zou and Levine, {Alex J.} and Jack Li and Shimon Weiss",

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doi = "https://doi.org/10.1126/sciadv.1601453",

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AU - Park, Kyoungwon

AU - Kuo, Yung

AU - Shvadchak, Volodymyr

AU - Ingargiola, Antonino

AU - Dai, Xinghong

AU - Hsiung, Lawrence

AU - Kim, Wookyeom

AU - Zhou, Hong

AU - Zou, Peng

AU - Levine, Alex J.

AU - Li, Jack

AU - Weiss, Shimon

PY - 2018/1

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N2 - We developed membrane voltage nanosensors that are based on inorganic semiconductor nanoparticles. We provide here a feasibility study for their utilization. We use a rationally designed peptide to functionalize the nanosensors, imparting them with the ability to self-insert into a lipid membrane with a desired orientation. Once inserted, these nanosensors could sense membrane potential via the quantum confined Stark effect, with a single-particle sensitivity. With further improvements, these nanosensors could potentially be used for simultaneous recording of action potentials from multiple neurons in a large field of view over a long duration and for recording electrical signals on the nanoscale, such as across one synapse.

AB - We developed membrane voltage nanosensors that are based on inorganic semiconductor nanoparticles. We provide here a feasibility study for their utilization. We use a rationally designed peptide to functionalize the nanosensors, imparting them with the ability to self-insert into a lipid membrane with a desired orientation. Once inserted, these nanosensors could sense membrane potential via the quantum confined Stark effect, with a single-particle sensitivity. With further improvements, these nanosensors could potentially be used for simultaneous recording of action potentials from multiple neurons in a large field of view over a long duration and for recording electrical signals on the nanoscale, such as across one synapse.

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Membrane insertion of—and membrane potential sensing by—semiconductor voltage nanosensors: Feasibility demonstration

Abstract

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