Ultra‐Thin Flexible Encapsulating Materials for Soft Bio‐Integrated Electronics

Sang, Mingyu; Kim, Kyubeen; Shin, Jongwoon

doi:10.1002/advs.202202980

Cited by 55 publications

(53 citation statements)

References 331 publications

(463 reference statements)

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“…Recent remarkable advances in bioelectronic devices have facilitated the growth of the healthcare industry. [ 1 ] Accordingly, demands for practical bioelectronics enabling daily healthcare monitoring have surged. These so‐called smart healthcare devices require long‐term functionality within the human body.…”

Section: Introductionmentioning

confidence: 99%

Intrinsically Nonswellable Multifunctional Hydrogel with Dynamic Nanoconfinement Networks for Robust Tissue‐Adaptable Bioelectronics

et al. 2023

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Developing bioelectronics that retains their long-term functionalities in the human body during daily activities is a current critical issue. To accomplish this, robust tissue adaptability and biointerfacing of bioelectronics should be achieved. Hydrogels have emerged as promising materials for bioelectronics that can softly adapt to and interface with tissues. However, hydrogels lack toughness, requisite electrical properties, and fabrication methodologies. Additionally, the water-swellable property of hydrogels weakens their mechanical properties. In this work, an intrinsically nonswellable multifunctional hydrogel exhibiting tissue-like moduli ranging from 10 to 100 kPa, toughness (400-873 J m −3 ), stretchability (≈1000% strain), and rapid self-healing ability (within 5 min), is developed. The incorporation of carboxyland hydroxyl-functionalized carbon nanotubes (fCNTs) ensures high conductivity of the hydrogel (≈40 S m −1 ), which can be maintained and recovered even after stretching or rupture. After a simple chemical modification, the hydrogel shows tissue-adhesive properties (≈50 kPa) against the target tissues. Moreover, the hydrogel can be 3D printed with a high resolution (≈100 μm) through heat treatment owing to its shear-thinning capacity, endowing it with fabrication versatility. The hydrogel is successfully applied to underwater electromyography (EMG) detection and ex vivo bladder expansion monitoring, demonstrating its potential for practical bioelectronics.

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Section: Introductionmentioning

confidence: 99%

Intrinsically Nonswellable Multifunctional Hydrogel with Dynamic Nanoconfinement Networks for Robust Tissue‐Adaptable Bioelectronics

et al. 2023

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“…The commonly utilized elastomeric binders face challenges in serving as hermetic seals, though most of the reported works have applied them as encapsulations. 178 An ideal encapsulation can simultaneously maintain stretchability and protect the inner materials from the attack of ions and oxygen, thus enabling the wide selection of stretchable conductive materials in harsh working environments, for example, human biofluids. Unfortunately, the stretchability and permeability of small molecules are highly linked.…”

Section: Instability Of Stretchable Materialsmentioning

confidence: 99%

Reliability of printed stretchable electronics based on nano/micro materials for practical applications

Thangavel

Lee

2023

Nanoscale

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“…[83] Therefore, the reliability of encapsulation is indispensable for practical applications of FEs-based products. [40] In this case, coaxial 3D printing and packaging can be performed simultaneously. [84] However, the DIW printed LMs features are commonly placed in the refrigerator for freezing and curing, and then packaged with PDMS.…”

Section: Encapsulationmentioning

confidence: 99%

“…[37][38][39] 4) The fluidity of LMs easily instigate leakage due to insufficient encapsulation. [40] In principle, flexible conductive lines play the key role to interconnect electronic components in FE devices, and flexible substrate/packaging materials are the prerequisite for the final realization of the functions of FEs. Therefore, to stimulate the huge potential of 3D printing of LMs, discussion on the material modification and printing technologies of LMs is extremely necessary.…”

Section: Introductionmentioning

confidence: 99%

3D Printing of Liquid Metals: Recent Advancements and Challenges

Zou

Chen

Yuan

et al. 2022

Adv Funct Materials

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The development of flexible electronics (FEs) has rapidly accelerated in numerous fields due to their exceptional deformability, bending, and stretchability. Room‐temperature gallium‐based liquid metals (LMs) are considered as efficient conductive materials for FEs due to their outstanding electrical conductivity and intrinsic flexibility. Recently, 3D printing has become a promising technique for fabricating FEs. However, the poor printability due to high surface tension and fluidity offers huge challenges in the 3D printing of LMs. This review summarizes the effective strategies to address these challenges. It primarily focuses on three points: 1) how to improve the printability of LM and its wettability with the substrate, 2) how to select the appropriate printing method to improve the printing speed and ensure the resolution of printing structure, and 3) how to provide perfect encapsulation for LM‐based FEs with 3D printing. Following a brief introduction, the mainstream printing technologies and recent developments in the 3D printing of LMs are provided, with an emphasis on the selection of printing method, improvement of printability, encapsulation, and conductivity activation. Then, the revolutionary changes attained after 3D printing of LMs are specifically focused upon. Finally, opinions and potential directions for this thriving discipline are explored.

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Ultra‐Thin Flexible Encapsulating Materials for Soft Bio‐Integrated Electronics

Cited by 55 publications

References 331 publications

Intrinsically Nonswellable Multifunctional Hydrogel with Dynamic Nanoconfinement Networks for Robust Tissue‐Adaptable Bioelectronics

Intrinsically Nonswellable Multifunctional Hydrogel with Dynamic Nanoconfinement Networks for Robust Tissue‐Adaptable Bioelectronics

Reliability of printed stretchable electronics based on nano/micro materials for practical applications

3D Printing of Liquid Metals: Recent Advancements and Challenges

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