Facile Graphene Oxide Modification Method via Hydroxyl-yne Click Reaction for Ultrasensitive and Ultrawide Monitoring Pressure Sensors

Hu, Zhipeng; Lu, Wanlong; Zheng, Youbin; Liu, Jiamei; Haick, Hossam; Bu, Laju

doi:10.1021/acsami.3c17172

ACS Appl. Mater. Interfaces

2024

DOI: 10.1021/acsami.3c17172

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Facile Graphene Oxide Modification Method via Hydroxyl-yne Click Reaction for Ultrasensitive and Ultrawide Monitoring Pressure Sensors

Zhipeng Hu,

Wanlong Lu,

Youbin Zheng

et al.

Abstract: Enhancing the durability and functionality of existing materials through sustainable pathways and appropriate structural design represents a time-and costeffective strategy for the development of advanced wearable devices. Herein, a facile graphene oxide (GO) modification method via the hydroxyl-yne click reaction is present for the first time. By the click coupling between propiolate esters and hydroxyl groups on GO under mild conditions, various functional molecules are successfully grafted onto the GO. The … Show more

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Cited by 2 publications

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Rise of graphene in novel piezoresistive sensing applications: A review on recent development and prospect

Khalid,

Umer,

Zweiri

et al. 2025

Materials Science and Engineering: R: Reports

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Rise of graphene in novel piezoresistive sensing applications: A review on recent development and prospect

Khalid,

Umer,

Zweiri

et al. 2025

Materials Science and Engineering: R: Reports

View full text Add to dashboard Cite

Leather-Based Shoe Soles for Real-Time Gait Recognition and Automatic Remote Assistance Using Machine Learning

Zhang,

Teng

et al. 2024

ACS Appl. Mater. Interfaces

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Real-time monitoring of gait characteristics is crucial for applications in health monitoring, patient rehabilitation feedback, and telemedicine. However, the effective and stable acquisition and automatic analysis of gait information remain significant challenges. In this study, we present a flexible sensor based on a carbon nanotube/graphene composite conductive leather (CGL), which uses collagen fiber with a three-dimensional network structure as the flexible substrate. The CGL-based sensor demonstrates a high dynamic range, with notable pressure responses ranging from 0.6 to 14.5 kPa and high sensitivity (S = 0.2465 kPa −1 ). We further developed a device incorporating the CGL-based sensor to collect foot characteristic signals from human motion and designed smart sports shoes to facilitate effective human− computer interaction. Machine learning was employed to collect and process gait characteristic information in various states, including standing, sitting, walking, and falling. For real-time monitoring of falls, we optimized the K-Nearest Time Series Classifier (KNTC) algorithm, achieving an accuracy of 0.99 and a prediction time of only 13 ms, which highlights the system's excellent intelligent response capabilities. The system maintained a gait recognition accuracy of 90% across diverse populations, with low false-positive (3.3%) and false-negative (3.3%) rates. This work demonstrates stable gait recognition capabilities and provides valuable methods and insights for plantar behavior monitoring and data analysis, contributing to the development of advanced real-time gait monitoring systems.

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Facile Graphene Oxide Modification Method via Hydroxyl-yne Click Reaction for Ultrasensitive and Ultrawide Monitoring Pressure Sensors

Cited by 2 publications

References 55 publications

Rise of graphene in novel piezoresistive sensing applications: A review on recent development and prospect

Rise of graphene in novel piezoresistive sensing applications: A review on recent development and prospect

Leather-Based Shoe Soles for Real-Time Gait Recognition and Automatic Remote Assistance Using Machine Learning

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