Feedback-controlled hydrogels with homeostatic oscillations and dissipative signal transduction

Hang Zhang; Hao Zeng; Amanda Eklund; Hongshuang Guo; Arri Priimagi; Olli Ikkala

doi:10.1038/s41565-022-01241-x

Feedback-controlled hydrogels with homeostatic oscillations and dissipative signal transduction

Hang Zhang, Hao Zeng, Amanda Eklund, Hongshuang Guo, Arri Priimagi, Olli Ikkala

Materials Science and Environmental Engineering

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

35 Citations (Scopus)

16 Downloads (Pure)

Abstract

Driving systems out of equilibrium under feedback control is characteristic for living systems, where homeostasis and dissipative signal transduction facilitate complex responses. This feature not only inspires dissipative dynamic functionalities in synthetic systems but also poses great challenges in designing novel pathways. Here we report feedback-controlled systems comprising two coupled hydrogels driven by constant light, where the system can be tuned to undergo stable homeostatic self-oscillations or damped steady states of temperature. We demonstrate that stable temperature oscillations can be utilized for dynamic colours and cargo transport, whereas damped steady states enable signal transduction pathways. Here mechanical triggers cause temperature changes that lead to responses such as bending motions inspired by the single-touch mechanoresponse in Mimosa pudica and the frequency-gated snapping motion inspired by the plant arithmetic in the Venus flytrap. The proposed concepts suggest generalizable feedback pathways for dissipative dynamic materials and interactive soft robotics.

Original language	English
Pages (from-to)	1303-1310
Number of pages	8
Journal	Nature Nanotechnology
Volume	17
Issue number	12
DOIs	https://doi.org/10.1038/s41565-022-01241-x
Publication status	Published - Dec 2022
Publication type	A1 Journal article-refereed

Publication forum classification

Publication forum level 3

ASJC Scopus subject areas

Bioengineering
Atomic and Molecular Physics, and Optics
Biomedical Engineering
General Materials Science
Condensed Matter Physics
Electrical and Electronic Engineering

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10.1038/s41565-022-01241-xLicence: CC BY

Feedback-controlled hydrogelsFinal published version, 7.68 MBLicence: CC BY

https://urn.fi/URN:NBN:fi:tuni-202301161413Licence: CC BY

Red Labs for soft photonic, robotic and energy materials
Priimägi, A. (Contact), Vivo, P. (Contact) & Nonappa, N. (Contact)
Materials Science and Environmental Engineering
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Cite this

@article{029fb592101240e1b45b4f8a2fc047f4,

title = "Feedback-controlled hydrogels with homeostatic oscillations and dissipative signal transduction",

abstract = "Driving systems out of equilibrium under feedback control is characteristic for living systems, where homeostasis and dissipative signal transduction facilitate complex responses. This feature not only inspires dissipative dynamic functionalities in synthetic systems but also poses great challenges in designing novel pathways. Here we report feedback-controlled systems comprising two coupled hydrogels driven by constant light, where the system can be tuned to undergo stable homeostatic self-oscillations or damped steady states of temperature. We demonstrate that stable temperature oscillations can be utilized for dynamic colours and cargo transport, whereas damped steady states enable signal transduction pathways. Here mechanical triggers cause temperature changes that lead to responses such as bending motions inspired by the single-touch mechanoresponse in Mimosa pudica and the frequency-gated snapping motion inspired by the plant arithmetic in the Venus flytrap. The proposed concepts suggest generalizable feedback pathways for dissipative dynamic materials and interactive soft robotics.",

author = "Hang Zhang and Hao Zeng and Amanda Eklund and Hongshuang Guo and Arri Priimagi and Olli Ikkala",

note = "Funding Information: We thank Henri Savolainen for the help with AuNPs synthesis, Jaakko Timonen for the help with numerical simulation, Olena Khoruzhenko for the help with figure illustrations, Haotian Pi for the discussion on heat transfer processes, and the provision of facilities and technical support by Aalto University at OtaNano - Nanomicroscopy Center (Aalto-NMC). We acknowledge funding from Academy of Finland (Postdoctoral Researcher No. 331015 to H. Zhang, Research Fellow No. 340263 to H. Zeng, Center of Excellence in Life-Inspired Hybrid Materials - LIBER No. 346107 to A.P. and No. 346108 to O.I. the PREIN Flagship Programme No. 320165), and the European Research Council (Advanced Grant DRIVEN No. 742829 to O.I. and Starting Grant PHOTOTUNE No. 679646 to A.P.). Funding Information: We thank Henri Savolainen for the help with AuNPs synthesis, Jaakko Timonen for the help with numerical simulation, Olena Khoruzhenko for the help with figure illustrations, Haotian Pi for the discussion on heat transfer processes, and the provision of facilities and technical support by Aalto University at OtaNano - Nanomicroscopy Center (Aalto-NMC). We acknowledge funding from Academy of Finland (Postdoctoral Researcher No. 331015 to H. Zhang, Research Fellow No. 340263 to H. Zeng, Center of Excellence in Life-Inspired Hybrid Materials - LIBER No. 346107 to A.P. and No. 346108 to O.I. the PREIN Flagship Programme No. 320165), and the European Research Council (Advanced Grant DRIVEN No. 742829 to O.I. and Starting Grant PHOTOTUNE No. 679646 to A.P.). Publisher Copyright: {\textcopyright} 2022, The Author(s).",

year = "2022",

month = dec,

doi = "10.1038/s41565-022-01241-x",

language = "English",

volume = "17",

pages = "1303--1310",

journal = "Nature Nanotechnology",

issn = "1748-3387",

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number = "12",

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AU - Zhang, Hang

AU - Zeng, Hao

AU - Eklund, Amanda

AU - Guo, Hongshuang

AU - Priimagi, Arri

AU - Ikkala, Olli

N1 - Funding Information: We thank Henri Savolainen for the help with AuNPs synthesis, Jaakko Timonen for the help with numerical simulation, Olena Khoruzhenko for the help with figure illustrations, Haotian Pi for the discussion on heat transfer processes, and the provision of facilities and technical support by Aalto University at OtaNano - Nanomicroscopy Center (Aalto-NMC). We acknowledge funding from Academy of Finland (Postdoctoral Researcher No. 331015 to H. Zhang, Research Fellow No. 340263 to H. Zeng, Center of Excellence in Life-Inspired Hybrid Materials - LIBER No. 346107 to A.P. and No. 346108 to O.I. the PREIN Flagship Programme No. 320165), and the European Research Council (Advanced Grant DRIVEN No. 742829 to O.I. and Starting Grant PHOTOTUNE No. 679646 to A.P.). Funding Information: We thank Henri Savolainen for the help with AuNPs synthesis, Jaakko Timonen for the help with numerical simulation, Olena Khoruzhenko for the help with figure illustrations, Haotian Pi for the discussion on heat transfer processes, and the provision of facilities and technical support by Aalto University at OtaNano - Nanomicroscopy Center (Aalto-NMC). We acknowledge funding from Academy of Finland (Postdoctoral Researcher No. 331015 to H. Zhang, Research Fellow No. 340263 to H. Zeng, Center of Excellence in Life-Inspired Hybrid Materials - LIBER No. 346107 to A.P. and No. 346108 to O.I. the PREIN Flagship Programme No. 320165), and the European Research Council (Advanced Grant DRIVEN No. 742829 to O.I. and Starting Grant PHOTOTUNE No. 679646 to A.P.). Publisher Copyright: © 2022, The Author(s).

PY - 2022/12

Y1 - 2022/12

N2 - Driving systems out of equilibrium under feedback control is characteristic for living systems, where homeostasis and dissipative signal transduction facilitate complex responses. This feature not only inspires dissipative dynamic functionalities in synthetic systems but also poses great challenges in designing novel pathways. Here we report feedback-controlled systems comprising two coupled hydrogels driven by constant light, where the system can be tuned to undergo stable homeostatic self-oscillations or damped steady states of temperature. We demonstrate that stable temperature oscillations can be utilized for dynamic colours and cargo transport, whereas damped steady states enable signal transduction pathways. Here mechanical triggers cause temperature changes that lead to responses such as bending motions inspired by the single-touch mechanoresponse in Mimosa pudica and the frequency-gated snapping motion inspired by the plant arithmetic in the Venus flytrap. The proposed concepts suggest generalizable feedback pathways for dissipative dynamic materials and interactive soft robotics.

AB - Driving systems out of equilibrium under feedback control is characteristic for living systems, where homeostasis and dissipative signal transduction facilitate complex responses. This feature not only inspires dissipative dynamic functionalities in synthetic systems but also poses great challenges in designing novel pathways. Here we report feedback-controlled systems comprising two coupled hydrogels driven by constant light, where the system can be tuned to undergo stable homeostatic self-oscillations or damped steady states of temperature. We demonstrate that stable temperature oscillations can be utilized for dynamic colours and cargo transport, whereas damped steady states enable signal transduction pathways. Here mechanical triggers cause temperature changes that lead to responses such as bending motions inspired by the single-touch mechanoresponse in Mimosa pudica and the frequency-gated snapping motion inspired by the plant arithmetic in the Venus flytrap. The proposed concepts suggest generalizable feedback pathways for dissipative dynamic materials and interactive soft robotics.

U2 - 10.1038/s41565-022-01241-x

DO - 10.1038/s41565-022-01241-x

M3 - Article

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AN - SCOPUS:85142913241

SN - 1748-3387

VL - 17

SP - 1303

EP - 1310

JO - Nature Nanotechnology

JF - Nature Nanotechnology

IS - 12

ER -

Feedback-controlled hydrogels with homeostatic oscillations and dissipative signal transduction

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