Bioinspired Tactile Sensation Based on Synergistic Microcrack-Bristle Structure Design toward High Mechanical Sensitivity and Direction-Resolving Capability

zhang, Yiqun; Liu, Q. H.; Ren, Wenjuan; Song, Yangyang; Luo, Hua; Han, Yangyang; Lin, He; Wu, Xiaodong; Wang, Zhuqing

doi:10.34133/research.0172

Cited by 11 publications

(6 citation statements)

References 57 publications

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“…A cracked elastomer or nano-/microcrack has been intentionally generated on elastomers to bring ultrasensitivity for subtle strain detection. − The disconnection/reconnection between adjacent zip-like nanoscale crack junctions enabled sensitive resistivity responses to external mechanical stimuli achieving extremely large gauge factor and low signal-to-noise ratio (SNR) . The mechanical crack-based strain sensor was first inspired by the spider sensory system with a slit organ geometry .…”

Section: Low-dimensional Nanomaterialsmentioning

confidence: 99%

“…245−249 The disconnection/reconnection between adjacent zip-like nanoscale crack junctions enabled sensitive resistivity responses to external mechanical stimuli achieving extremely large gauge factor and low signalto-noise ratio (SNR). 250 The mechanical crack-based strain sensor was first inspired by the spider sensory system with a slit organ geometry. 251 The electrical conductance across the stiff and ultrathin (20 nm) sputter-deposited Pt layer could be measured by the controlled cracks (both density and direction) formed by mechanically bending the elastomers under various radii of curvatures.…”

Section: Other Nanostructured Designsmentioning

confidence: 99%

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Materials-Driven Soft Wearable Bioelectronics for Connected Healthcare

Gong,

Lu,

Yin

et al. 2024

Chem. Rev.

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In the era of Internet-of-things, many things can stay connected; however, biological systems, including those necessary for human health, remain unable to stay connected to the global Internet due to the lack of soft conformal biosensors. The fundamental challenge lies in the fact that electronics and biology are distinct and incompatible, as they are based on different materials via different functioning principles. In particular, the human body is soft and curvilinear, yet electronics are typically rigid and planar. Recent advances in materials and materials design have generated tremendous opportunities to design soft wearable bioelectronics, which may bridge the gap, enabling the ultimate dream of connected healthcare for anyone, anytime, and anywhere. We begin with a review of the historical development of healthcare, indicating the significant trend of connected healthcare. This is followed by the focal point of discussion about new materials and materials design, particularly low-dimensional nanomaterials. We summarize material types and their attributes for designing soft bioelectronic sensors; we also cover their synthesis and fabrication methods, including top-down, bottom-up, and their combined approaches. Next, we discuss the wearable energy challenges and progress made to date. In addition to front-end wearable devices, we also describe back-end machine learning algorithms, artificial intelligence, telecommunication, and software. Afterward, we describe the integration of soft wearable bioelectronic systems which have been applied in various testbeds in real-world settings, including laboratories that are preclinical and clinical environments. Finally, we narrate the remaining challenges and opportunities in conjunction with our perspectives.

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Section: Low-dimensional Nanomaterialsmentioning

confidence: 99%

Section: Other Nanostructured Designsmentioning

confidence: 99%

Materials-Driven Soft Wearable Bioelectronics for Connected Healthcare

Gong,

Lu,

Yin

et al. 2024

Chem. Rev.

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“…In recent years, with the development of flexible electronics, flexible pressure sensors have shown great potential in motion monitoring 1 – 3 , human‒machine interaction (HMI) 4 – 6 , personalized medicine 7 – 9 , and soft intelligent robots 10 – 12 . Perceiving and detecting multidirectional mechanical stimuli is crucial for pressure sensing and can provide comprehensive, complete, and accurate information about pressure distributions and interactions to realize motion direction detection 13 , slip detection 14 , and grasp detection 15 . Numerous studies have been conducted to achieve multidirectional force response and a wide sensing range in pressure sensors for various applications.…”

Section: Introductionmentioning

confidence: 99%

Flexible wide-range multidimensional force sensors inspired by bones embedded in muscle

Zhang,

Hou,

Qian

et al. 2024

Microsyst Nanoeng

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Flexible sensors have been widely studied for use in motion monitoring, human‒machine interactions (HMIs), personalized medicine, and soft intelligent robots. However, their practical application is limited by their low output performance, narrow measuring range, and unidirectional force detection. Here, to achieve flexibility and high performance simultaneously, we developed a flexible wide-range multidimensional force sensor (FWMFS) similar to bones embedded in muscle structures. The adjustable magnetic field endows the FWMFS with multidimensional perception for detecting forces in different directions. The multilayer stacked coils significantly improved the output from the μV to the mV level while ensuring FWMFS miniaturization. The optimized FWMFS exhibited a high voltage sensitivity of 0.227 mV/N (0.5–8.4 N) and 0.047 mV/N (8.4–60 N) in response to normal forces ranging from 0.5 N to 60 N and could detect lateral forces ranging from 0.2–1.1 N and voltage sensitivities of 1.039 mV/N (0.2–0.5 N) and 0.194 mV/N (0.5–1.1 N). In terms of normal force measurements, the FWMFS can monitor finger pressure and sliding trajectories in response to finger taps, as well as measure plantar pressure for assessing human movement. The plantar pressure signals of five human movements collected by the FWMFS were analyzed using the k-nearest neighbors classification algorithm, which achieved a recognition accuracy of 92%. Additionally, an artificial intelligence biometric authentication system is being developed that classifies and recognizes user passwords. Based on the lateral force measurement ability of the FWMFS, the direction of ball movement can be distinguished, and communication systems such as Morse Code can be expanded. This research has significant potential in intelligent sensing and personalized spatial recognition.

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“…In the construction of the aforementioned wearable touch sensors, a variety of novel materials (e.g., flexible polymers [ 23 ], stretchable elastomers [ 24 ], soft hydrogels [ 25 ], etc.) and unique structures (e.g., pyramid [ 26 ], hemisphere [ 27 ], cylinder [ 28 ], cilia [ 29 ], crack [ 30 , 31 ], etc.) have played an importance role in the enhancement and realization of high sensing performance and unique device functionalities.…”

Section: Introductionmentioning

confidence: 99%

Construction of Wearable Touch Sensors by Mimicking the Properties of Materials and Structures in Nature

Geng,

Zeng,

Luo

et al. 2023

Biomimetics

Self Cite

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Wearable touch sensors, which can convert force or pressure signals into quantitative electronic signals, have emerged as essential smart sensing devices and play an important role in various cutting-edge fields, including wearable health monitoring, soft robots, electronic skin, artificial prosthetics, AR/VR, and the Internet of Things. Flexible touch sensors have made significant advancements, while the construction of novel touch sensors by mimicking the unique properties of biological materials and biogenetic structures always remains a hot research topic and significant technological pathway. This review provides a comprehensive summary of the research status of wearable touch sensors constructed by imitating the material and structural characteristics in nature and summarizes the scientific challenges and development tendencies of this aspect. First, the research status for constructing flexible touch sensors based on biomimetic materials is summarized, including hydrogel materials, self-healing materials, and other bio-inspired or biomimetic materials with extraordinary properties. Then, the design and fabrication of flexible touch sensors based on bionic structures for performance enhancement are fully discussed. These bionic structures include special structures in plants, special structures in insects/animals, and special structures in the human body. Moreover, a summary of the current issues and future prospects for developing wearable sensors based on bio-inspired materials and structures is discussed.

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Bioinspired Tactile Sensation Based on Synergistic Microcrack-Bristle Structure Design toward High Mechanical Sensitivity and Direction-Resolving Capability

Cited by 11 publications

References 57 publications

Materials-Driven Soft Wearable Bioelectronics for Connected Healthcare

Materials-Driven Soft Wearable Bioelectronics for Connected Healthcare

Flexible wide-range multidimensional force sensors inspired by bones embedded in muscle

Construction of Wearable Touch Sensors by Mimicking the Properties of Materials and Structures in Nature

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