Interfacing with the Brain: How Nanotechnology Can Contribute

Abdullah A.A. Ahmed; Nuria Alegret; Bethany Almeida; Ramón Alvarez-Puebla; Anne M. Andrews; Laura Ballerini; Juan J. Barrios-Capuchino; Charline Becker; Robert H. Blick; Shahin Bonakdar; Indranath Chakraborty; Xiaodong Chen; Jinwoo Cheon; Gerwin Chilla; Andre Luiz Coelho Conceicao; James Delehanty; Martin Dulle; Alexander L. Efros; Matthias Epple; Mark Fedyk; Neus Feliu; Miao Feng; Rafael Fernández-Chacón; Irene Fernandez-Cuesta; Niels Fertig; Stephan Förster; Jose A. Garrido; Michael George; Andreas H. Guse; Norbert Hampp; Jann Harberts; Jili Han; Hauke R. Heekeren; Ulrich G. Hofmann; Malte Holzapfel; Hessam Hosseinkazemi; Yalan Huang; Patrick Huber; Taeghwan Hyeon; Sven Ingebrandt; Marcello Ienca; Armin Iske; Yanan Kang; Gregor Kasieczka; Dae Hyeong Kim; Kostas Kostarelos; Jae Hyun Lee; Kai Wei Lin; Sijin Liu; Xin Liu; Yang Liu; Christian Lohr; Volker Mailänder; Laura Maffongelli; Saad Megahed; Alf Mews; Marina Mutas; Leroy Nack; Nako Nakatsuka; Thomas G. Oertner; Andreas Offenhäusser; Martin Oheim; Ben Otange; Ferdinand Otto; Enrico Patrono; Bo Peng; Alessandra Picchiotti; Filippo Pierini; Monika Pötter-Nerger; Maria Pozzi; Arnd Pralle; Maurizio Prato; Bing Qi; Pedro Ramos-Cabrer; Ute Resch Genger; Norbert Ritter; Marten Rittner; Sathi Roy; Francesca Santoro; Nicolas W. Schuck; Florian Schulz; Erkin Şeker; Marvin Skiba; Martin Sosniok; Holger Stephan; Ruixia Wang; Ting Wang; K. David Wegner; Paul S. Weiss; Ming Xu; Chenxi Yang; Seyed Shahrooz Zargarian; Yuan Zeng; Yaofeng Zhou; Dingcheng Zhu; Robert Zierold; Wolfgang J. Parak

doi:10.1021/acsnano.4c10525

Interfacing with the Brain: How Nanotechnology Can Contribute

Abdullah A.A. Ahmed, Nuria Alegret, Bethany Almeida, Ramón Alvarez-Puebla, Anne M. Andrews, Laura Ballerini, Juan J. Barrios-Capuchino, Charline Becker, Robert H. Blick, Shahin Bonakdar, Indranath Chakraborty, Xiaodong Chen, Jinwoo Cheon, Gerwin Chilla, Andre Luiz Coelho Conceicao, James Delehanty, Martin Dulle, Alexander L. Efros, Matthias Epple, Mark FedykNeus Feliu, Miao Feng, Rafael Fernández-Chacón, Irene Fernandez-Cuesta, Niels Fertig, Stephan Förster, Jose A. Garrido, Michael George, Andreas H. Guse, Norbert Hampp, Jann Harberts, Jili Han, Hauke R. Heekeren, Ulrich G. Hofmann, Malte Holzapfel, Hessam Hosseinkazemi, Yalan Huang, Patrick Huber, Taeghwan Hyeon, Sven Ingebrandt, Marcello Ienca, Armin Iske, Yanan Kang, Gregor Kasieczka, Dae Hyeong Kim, Kostas Kostarelos, Jae Hyun Lee, Kai Wei Lin, Sijin Liu, Xin Liu, Yang Liu, Christian Lohr, Volker Mailänder, Laura Maffongelli, Saad Megahed, Alf Mews, Marina Mutas, Leroy Nack, Nako Nakatsuka, Thomas G. Oertner, Andreas Offenhäusser, Martin Oheim, Ben Otange, Ferdinand Otto, Enrico Patrono, Bo Peng, Alessandra Picchiotti, Filippo Pierini, Monika Pötter-Nerger, Maria Pozzi, Arnd Pralle, Maurizio Prato, Bing Qi, Pedro Ramos-Cabrer, Ute Resch Genger, Norbert Ritter, Marten Rittner, Sathi Roy, Francesca Santoro, Nicolas W. Schuck, Florian Schulz, Erkin Şeker, Marvin Skiba, Martin Sosniok, Holger Stephan, Ruixia Wang, Ting Wang, K. David Wegner, Paul S. Weiss, Ming Xu, Chenxi Yang, Seyed Shahrooz Zargarian, Yuan Zeng, Yaofeng Zhou, Dingcheng Zhu, Robert Zierold, Wolfgang J. Parak^*

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

Abstract

Interfacing artificial devices with the human brain is the central goal of neurotechnology. Yet, our imaginations are often limited by currently available paradigms and technologies. Suggestions for brain-machine interfaces have changed over time, along with the available technology. Mechanical levers and cable winches were used to move parts of the brain during the mechanical age. Sophisticated electronic wiring and remote control have arisen during the electronic age, ultimately leading to plug-and-play computer interfaces. Nonetheless, our brains are so complex that these visions, until recently, largely remained unreachable dreams. The general problem, thus far, is that most of our technology is mechanically and/or electrically engineered, whereas the brain is a living, dynamic entity. As a result, these worlds are difficult to interface with one another. Nanotechnology, which encompasses engineered solid-state objects and integrated circuits, excels at small length scales of single to a few hundred nanometers and, thus, matches the sizes of biomolecules, biomolecular assemblies, and parts of cells. Consequently, we envision nanomaterials and nanotools as opportunities to interface with the brain in alternative ways. Here, we review the existing literature on the use of nanotechnology in brain-machine interfaces and look forward in discussing perspectives and limitations based on the authors’ expertise across a range of complementary disciplines─from neuroscience, engineering, physics, and chemistry to biology and medicine, computer science and mathematics, and social science and jurisprudence. We focus on nanotechnology but also include information from related fields when useful and complementary.

Original language	English
Pages (from-to)	10630-10717
Number of pages	88
Journal	ACS Nano
Volume	19
Issue number	11
DOIs	https://doi.org/10.1021/acsnano.4c10525
Publication status	Published - Mar 25 2025
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2025 The Authors. Published by American Chemical Society.

ASJC Scopus Subject Areas

General Materials Science
General Engineering
General Physics and Astronomy

Keywords

brain-on-a-chip
brain−machine interfaces
control of ion channels
deep brain stimulation
electrode arrays
extracellular recordings
Nanoneuro interface
nanostructured interface
neuro-implants
neuronal communication

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1021/acsnano.4c10525

Cite this

Ahmed, A. A. A., Alegret, N., Almeida, B., Alvarez-Puebla, R., Andrews, A. M., Ballerini, L., Barrios-Capuchino, J. J., Becker, C., Blick, R. H., Bonakdar, S., Chakraborty, I., Chen, X., Cheon, J., Chilla, G., Coelho Conceicao, A. L., Delehanty, J., Dulle, M., Efros, A. L., Epple, M., ... Parak, W. J. (2025). Interfacing with the Brain: How Nanotechnology Can Contribute. ACS Nano, 19(11), 10630-10717. https://doi.org/10.1021/acsnano.4c10525

@article{c7181e9f14a4482fa13ebbb933da3e8e,

title = "Interfacing with the Brain: How Nanotechnology Can Contribute",

abstract = "Interfacing artificial devices with the human brain is the central goal of neurotechnology. Yet, our imaginations are often limited by currently available paradigms and technologies. Suggestions for brain-machine interfaces have changed over time, along with the available technology. Mechanical levers and cable winches were used to move parts of the brain during the mechanical age. Sophisticated electronic wiring and remote control have arisen during the electronic age, ultimately leading to plug-and-play computer interfaces. Nonetheless, our brains are so complex that these visions, until recently, largely remained unreachable dreams. The general problem, thus far, is that most of our technology is mechanically and/or electrically engineered, whereas the brain is a living, dynamic entity. As a result, these worlds are difficult to interface with one another. Nanotechnology, which encompasses engineered solid-state objects and integrated circuits, excels at small length scales of single to a few hundred nanometers and, thus, matches the sizes of biomolecules, biomolecular assemblies, and parts of cells. Consequently, we envision nanomaterials and nanotools as opportunities to interface with the brain in alternative ways. Here, we review the existing literature on the use of nanotechnology in brain-machine interfaces and look forward in discussing perspectives and limitations based on the authors{\textquoteright} expertise across a range of complementary disciplines─from neuroscience, engineering, physics, and chemistry to biology and medicine, computer science and mathematics, and social science and jurisprudence. We focus on nanotechnology but also include information from related fields when useful and complementary.",

keywords = "brain-on-a-chip, brain−machine interfaces, control of ion channels, deep brain stimulation, electrode arrays, extracellular recordings, Nanoneuro interface, nanostructured interface, neuro-implants, neuronal communication",

author = "Ahmed, {Abdullah A.A.} and Nuria Alegret and Bethany Almeida and Ram{\'o}n Alvarez-Puebla and Andrews, {Anne M.} and Laura Ballerini and Barrios-Capuchino, {Juan J.} and Charline Becker and Blick, {Robert H.} and Shahin Bonakdar and Indranath Chakraborty and Xiaodong Chen and Jinwoo Cheon and Gerwin Chilla and {Coelho Conceicao}, {Andre Luiz} and James Delehanty and Martin Dulle and Efros, {Alexander L.} and Matthias Epple and Mark Fedyk and Neus Feliu and Miao Feng and Rafael Fern{\'a}ndez-Chac{\'o}n and Irene Fernandez-Cuesta and Niels Fertig and Stephan F{\"o}rster and Garrido, {Jose A.} and Michael George and Guse, {Andreas H.} and Norbert Hampp and Jann Harberts and Jili Han and Heekeren, {Hauke R.} and Hofmann, {Ulrich G.} and Malte Holzapfel and Hessam Hosseinkazemi and Yalan Huang and Patrick Huber and Taeghwan Hyeon and Sven Ingebrandt and Marcello Ienca and Armin Iske and Yanan Kang and Gregor Kasieczka and Kim, {Dae Hyeong} and Kostas Kostarelos and Lee, {Jae Hyun} and Lin, {Kai Wei} and Sijin Liu and Xin Liu and Yang Liu and Christian Lohr and Volker Mail{\"a}nder and Laura Maffongelli and Saad Megahed and Alf Mews and Marina Mutas and Leroy Nack and Nako Nakatsuka and Oertner, {Thomas G.} and Andreas Offenh{\"a}usser and Martin Oheim and Ben Otange and Ferdinand Otto and Enrico Patrono and Bo Peng and Alessandra Picchiotti and Filippo Pierini and Monika P{\"o}tter-Nerger and Maria Pozzi and Arnd Pralle and Maurizio Prato and Bing Qi and Pedro Ramos-Cabrer and Genger, {Ute Resch} and Norbert Ritter and Marten Rittner and Sathi Roy and Francesca Santoro and Schuck, {Nicolas W.} and Florian Schulz and Erkin {\c S}eker and Marvin Skiba and Martin Sosniok and Holger Stephan and Ruixia Wang and Ting Wang and Wegner, {K. David} and Weiss, {Paul S.} and Ming Xu and Chenxi Yang and Zargarian, {Seyed Shahrooz} and Yuan Zeng and Yaofeng Zhou and Dingcheng Zhu and Robert Zierold and Parak, {Wolfgang J.}",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors. Published by American Chemical Society.",

year = "2025",

month = mar,

day = "25",

doi = "10.1021/acsnano.4c10525",

language = "English",

volume = "19",

pages = "10630--10717",

journal = "ACS Nano",

issn = "1936-0851",

publisher = "American Chemical Society",

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Ahmed, AAA, Alegret, N, Almeida, B, Alvarez-Puebla, R, Andrews, AM, Ballerini, L, Barrios-Capuchino, JJ, Becker, C, Blick, RH, Bonakdar, S, Chakraborty, I, Chen, X, Cheon, J, Chilla, G, Coelho Conceicao, AL, Delehanty, J, Dulle, M, Efros, AL, Epple, M, Fedyk, M, Feliu, N, Feng, M, Fernández-Chacón, R, Fernandez-Cuesta, I, Fertig, N, Förster, S, Garrido, JA, George, M, Guse, AH, Hampp, N, Harberts, J, Han, J, Heekeren, HR, Hofmann, UG, Holzapfel, M, Hosseinkazemi, H, Huang, Y, Huber, P, Hyeon, T, Ingebrandt, S, Ienca, M, Iske, A, Kang, Y, Kasieczka, G, Kim, DH, Kostarelos, K, Lee, JH, Lin, KW, Liu, S, Liu, X, Liu, Y, Lohr, C, Mailänder, V, Maffongelli, L, Megahed, S, Mews, A, Mutas, M, Nack, L, Nakatsuka, N, Oertner, TG, Offenhäusser, A, Oheim, M, Otange, B, Otto, F, Patrono, E, Peng, B, Picchiotti, A, Pierini, F, Pötter-Nerger, M, Pozzi, M, Pralle, A, Prato, M, Qi, B, Ramos-Cabrer, P, Genger, UR, Ritter, N, Rittner, M, Roy, S, Santoro, F, Schuck, NW, Schulz, F, Şeker, E, Skiba, M, Sosniok, M, Stephan, H, Wang, R, Wang, T, Wegner, KD, Weiss, PS, Xu, M, Yang, C, Zargarian, SS, Zeng, Y, Zhou, Y, Zhu, D, Zierold, R & Parak, WJ 2025, 'Interfacing with the Brain: How Nanotechnology Can Contribute', ACS Nano, vol. 19, no. 11, pp. 10630-10717. https://doi.org/10.1021/acsnano.4c10525

TY - JOUR

T1 - Interfacing with the Brain

T2 - How Nanotechnology Can Contribute

AU - Ahmed, Abdullah A.A.

AU - Alegret, Nuria

AU - Almeida, Bethany

AU - Alvarez-Puebla, Ramón

AU - Andrews, Anne M.

AU - Ballerini, Laura

AU - Barrios-Capuchino, Juan J.

AU - Becker, Charline

AU - Blick, Robert H.

AU - Bonakdar, Shahin

AU - Chakraborty, Indranath

AU - Chen, Xiaodong

AU - Cheon, Jinwoo

AU - Chilla, Gerwin

AU - Coelho Conceicao, Andre Luiz

AU - Delehanty, James

AU - Dulle, Martin

AU - Efros, Alexander L.

AU - Epple, Matthias

AU - Fedyk, Mark

AU - Feliu, Neus

AU - Feng, Miao

AU - Fernández-Chacón, Rafael

AU - Fernandez-Cuesta, Irene

AU - Fertig, Niels

AU - Förster, Stephan

AU - Garrido, Jose A.

AU - George, Michael

AU - Guse, Andreas H.

AU - Hampp, Norbert

AU - Harberts, Jann

AU - Han, Jili

AU - Heekeren, Hauke R.

AU - Hofmann, Ulrich G.

AU - Holzapfel, Malte

AU - Hosseinkazemi, Hessam

AU - Huang, Yalan

AU - Huber, Patrick

AU - Hyeon, Taeghwan

AU - Ingebrandt, Sven

AU - Ienca, Marcello

AU - Iske, Armin

AU - Kang, Yanan

AU - Kasieczka, Gregor

AU - Kim, Dae Hyeong

AU - Kostarelos, Kostas

AU - Lee, Jae Hyun

AU - Lin, Kai Wei

AU - Liu, Sijin

AU - Liu, Xin

AU - Liu, Yang

AU - Lohr, Christian

AU - Mailänder, Volker

AU - Maffongelli, Laura

AU - Megahed, Saad

AU - Mews, Alf

AU - Mutas, Marina

AU - Nack, Leroy

AU - Nakatsuka, Nako

AU - Oertner, Thomas G.

AU - Offenhäusser, Andreas

AU - Oheim, Martin

AU - Otange, Ben

AU - Otto, Ferdinand

AU - Patrono, Enrico

AU - Peng, Bo

AU - Picchiotti, Alessandra

AU - Pierini, Filippo

AU - Pötter-Nerger, Monika

AU - Pozzi, Maria

AU - Pralle, Arnd

AU - Prato, Maurizio

AU - Qi, Bing

AU - Ramos-Cabrer, Pedro

AU - Genger, Ute Resch

AU - Ritter, Norbert

AU - Rittner, Marten

AU - Roy, Sathi

AU - Santoro, Francesca

AU - Schuck, Nicolas W.

AU - Schulz, Florian

AU - Şeker, Erkin

AU - Skiba, Marvin

AU - Sosniok, Martin

AU - Stephan, Holger

AU - Wang, Ruixia

AU - Wang, Ting

AU - Wegner, K. David

AU - Weiss, Paul S.

AU - Xu, Ming

AU - Yang, Chenxi

AU - Zargarian, Seyed Shahrooz

AU - Zeng, Yuan

AU - Zhou, Yaofeng

AU - Zhu, Dingcheng

AU - Zierold, Robert

AU - Parak, Wolfgang J.

PY - 2025/3/25

Y1 - 2025/3/25

N2 - Interfacing artificial devices with the human brain is the central goal of neurotechnology. Yet, our imaginations are often limited by currently available paradigms and technologies. Suggestions for brain-machine interfaces have changed over time, along with the available technology. Mechanical levers and cable winches were used to move parts of the brain during the mechanical age. Sophisticated electronic wiring and remote control have arisen during the electronic age, ultimately leading to plug-and-play computer interfaces. Nonetheless, our brains are so complex that these visions, until recently, largely remained unreachable dreams. The general problem, thus far, is that most of our technology is mechanically and/or electrically engineered, whereas the brain is a living, dynamic entity. As a result, these worlds are difficult to interface with one another. Nanotechnology, which encompasses engineered solid-state objects and integrated circuits, excels at small length scales of single to a few hundred nanometers and, thus, matches the sizes of biomolecules, biomolecular assemblies, and parts of cells. Consequently, we envision nanomaterials and nanotools as opportunities to interface with the brain in alternative ways. Here, we review the existing literature on the use of nanotechnology in brain-machine interfaces and look forward in discussing perspectives and limitations based on the authors’ expertise across a range of complementary disciplines─from neuroscience, engineering, physics, and chemistry to biology and medicine, computer science and mathematics, and social science and jurisprudence. We focus on nanotechnology but also include information from related fields when useful and complementary.

AB - Interfacing artificial devices with the human brain is the central goal of neurotechnology. Yet, our imaginations are often limited by currently available paradigms and technologies. Suggestions for brain-machine interfaces have changed over time, along with the available technology. Mechanical levers and cable winches were used to move parts of the brain during the mechanical age. Sophisticated electronic wiring and remote control have arisen during the electronic age, ultimately leading to plug-and-play computer interfaces. Nonetheless, our brains are so complex that these visions, until recently, largely remained unreachable dreams. The general problem, thus far, is that most of our technology is mechanically and/or electrically engineered, whereas the brain is a living, dynamic entity. As a result, these worlds are difficult to interface with one another. Nanotechnology, which encompasses engineered solid-state objects and integrated circuits, excels at small length scales of single to a few hundred nanometers and, thus, matches the sizes of biomolecules, biomolecular assemblies, and parts of cells. Consequently, we envision nanomaterials and nanotools as opportunities to interface with the brain in alternative ways. Here, we review the existing literature on the use of nanotechnology in brain-machine interfaces and look forward in discussing perspectives and limitations based on the authors’ expertise across a range of complementary disciplines─from neuroscience, engineering, physics, and chemistry to biology and medicine, computer science and mathematics, and social science and jurisprudence. We focus on nanotechnology but also include information from related fields when useful and complementary.

KW - brain-on-a-chip

KW - brain−machine interfaces

KW - control of ion channels

KW - deep brain stimulation

KW - electrode arrays

KW - extracellular recordings

KW - Nanoneuro interface

KW - nanostructured interface

KW - neuro-implants

KW - neuronal communication

UR - http://www.scopus.com/inward/record.url?scp=105001207103&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=105001207103&partnerID=8YFLogxK

U2 - 10.1021/acsnano.4c10525

DO - 10.1021/acsnano.4c10525

M3 - Review article

AN - SCOPUS:105001207103

SN - 1936-0851

VL - 19

SP - 10630

EP - 10717

JO - ACS Nano

JF - ACS Nano

IS - 11

ER -

Interfacing with the Brain: How Nanotechnology Can Contribute

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

UN SDGs

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