Stretchable Encapsulation Materials with High Dynamic Water Resistivity and Tissue-Matching Elasticity

Shao, Yan; Yan, Shan; Li, Jun; Silva-Pedraza, Zulmari; Zhou, Ting; Hsieh, Marvin L; Liu, Bo; Li, Tong; Gu, Long; Zhao, Yunhe; Dong, Yutao; Yin, Bo; Wang, Xudong

doi:10.1021/acsami.2c03110

Cited by 7 publications

(6 citation statements)

References 35 publications

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“…However, behaviors such as chewing and grinding when eating solid food may wear down the encapsulation layer of the system, leading to acid corrosion, electrical shorts, and even battery leakage. Better biocompatibility may be achieved by introducing adaptively deformable encapsulations, such as cellular microstructures [ 42 ], microfluidic suspensions [ 43 ], and tissue-like materials [ 44 , 45 ] to minimize package degradation. Thereafter, the mean values of the corresponding parameters during sleep and wakefulness were calculated ( Figure 5(d) ).…”

Section: Resultsmentioning

confidence: 99%

Continuously Quantifying Oral Chemicals Based on Flexible Hybrid Electronics for Clinical Diagnosis and Pathogenetic Study

Ling

Wang

et al. 2022

Research

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Simultaneous monitoring of diverse salivary parameters can reveal underlying mechanisms of intraoral biological processes and offer profound insights into the evolution of oral diseases. However, conventional analytical devices with bulky volumes, rigid formats, and discrete sensing mechanisms deviate from the requirements of continuous biophysiological quantification, resulting in huge difficulty in precise clinical diagnosis and pathogenetic study. Here, we present a flexible hybrid electronic system integrated with functional nanomaterials to continuously sense Ca2+, pH, and temperature for wireless real-time oral health monitoring. The miniaturized system with an island-bridge structure that is designed specifically to fit the teeth is only 0.4 g in weight and 31.5×8.5×1.35 mm3 in dimension, allowing effective integration with customized dental braces and comfort attachment on teeth. Characterization results indicate high sensitivities of 30.3 and 60.6 mV/decade for Ca2+ and pH with low potential drifts. The system has been applied in clinical studies to conduct Ca2+ and pH mappings on carious teeth, biophysiological monitoring for up to 12 h, and outcome evaluation of dental restoration, providing quantitative data to assist in the diagnosis and understanding of oral diseases. Notably, caries risk assessment of 10 human subjects using the flexible system validates the important role of saliva buffering capacity in caries pathogenesis. The proposed flexible system may offer an open platform to carry diverse components to support both clinical diagnosis and treatment as well as fundamental research for oral diseases and induced systemic diseases.

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Section: Resultsmentioning

confidence: 99%

Continuously Quantifying Oral Chemicals Based on Flexible Hybrid Electronics for Clinical Diagnosis and Pathogenetic Study

Ling

Wang

et al. 2022

Research

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“…181 As a result, less free space is available for small molecules to transfer through the film. Butyl rubbers have been applied to protect stretchable organic electronic materials, 182,183 triboelectric nanogenerators, 184 alternating current electroluminescence devices 185 and iongels. 186 However, few of the aforementioned strategies have been applied to printed stretchable electronics.…”

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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Section: Materials For Membrane and Encapsulationmentioning

confidence: 99%

“…Shao et al reported a polyisobutylene blend-based elastomer with high stretchability and high water resistivity, which could potentially be used for packing materials of implantable electrodes (Figure 5e). [179] However, the permeability of many elastomers is higher in comparison with metal and/or non-stretchable polymers, and the issue could be solved by increasing the thickness of the elastomer layer. [180] Natural materials, such as collagen, are conventional materials as the membrane for the implantable electrode.…”

Section: Polymersmentioning

confidence: 99%

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Materials and Biomedical Applications of Implantable Electronic Devices

Liu

et al. 2022

Adv Materials Technologies

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The implantable electronic devices have attracted great attention for solving clinical problems ranging from monitoring psychological states to electro‐organ transplantation. The ongoing challenges are the selection of suitable materials in a target device configuration for biomedical applications. To address the ongoing challenges, there are several interesting questions: what types of electronic materials can be used as the implantable electrodes? What types of materials can be used as the substrates for the implantable electronic devices? What types of materials can be used as membranes and encapsulations? What types of device configurations are there for implantable biomedical applications? What types of applications are for implantable electronic devices? This review will highlight the attempts for addressing these questions. This review will explore the fundamentals and practical aspects of a variety of materials and their biomedical applications in implantable electronic devices. It is anticipated that this review could provide new opportunities for the construction of future implantable electronic devices, as well as related applications for disease diagnosis and therapy.

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Stretchable Encapsulation Materials with High Dynamic Water Resistivity and Tissue-Matching Elasticity

Cited by 7 publications

References 35 publications

Continuously Quantifying Oral Chemicals Based on Flexible Hybrid Electronics for Clinical Diagnosis and Pathogenetic Study

Continuously Quantifying Oral Chemicals Based on Flexible Hybrid Electronics for Clinical Diagnosis and Pathogenetic Study

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

Materials and Biomedical Applications of Implantable Electronic Devices

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