TY  - GEN
AU  - Jeong,Jae-Woong
AU  - Yeo,W.Hong
TI  - Soft Material-Enabled Electronics for Medicine, Healthcare, and Human-Machine Interfaces
SN  - books978-3-03928-283-8
PY  - 2020///
PB  - MDPI - Multidisciplinary Digital Publishing Institute
KW  - graphene oxide
KW  - biodegradable
KW  - swallowing
KW  - liquid-metal
KW  - freeze-thaw method
KW  - low-profile bioelectronics
KW  - biodegradable electronics
KW  - conductive textile
KW  - capacitive pressure sensor
KW  - soft biomedical electronics
KW  - soft materials
KW  - hybrid transparent conductive electrode
KW  - implantable electronics
KW  - hardening sponge
KW  - superelastic
KW  - stretchable electronics
KW  - RMIS (robot-assisted minimally invasive surgery)
KW  - stretchable
KW  - polydimethylsiloxane
KW  - dysphagia
KW  - miniaturization
KW  - biocompatible
KW  - electroactive hydrogel
KW  - human-machine interfaces
KW  - monitoring
KW  - phase coordination index
KW  - MR sponge
KW  - flexible hybrid electronics
KW  - 6 degrees-of-freedom (6-DOF) MR haptic master
KW  - bioresorbable electronics
KW  - smartphone-based biosensor
KW  - conductive inks
KW  - gait
KW  - micro/nanofabrication
KW  - prosthesis
KW  - implantable materials
KW  - actuation
KW  - wearable electronics
KW  - point-of-care testing
KW  - chromogenic biochemical assay
KW  - implantable devices
KW  - health monitoring
KW  - tongue
KW  - optical fibers
KW  - transient electronics
KW  - healthcare
KW  - carbon-based nano-materials
KW  - silver nanowire
KW  - PDMS optical filter
KW  - bio-integrated electronics
KW  - soft material-based channel
KW  - flexible electronics
KW  - medicine
KW  - optical waveguides
KW  - capacitor
KW  - smart window
KW  - biodegradable materials
KW  - diagnostics
KW  - naked-eye detection
KW  - medical devices
KW  - polyvinyl alcohol
KW  - nitinol
KW  - printing electronics techniques
KW  - polymer-dispersed liquid crystal
KW  - cellulose nanocrystals
N1  - Open Access
N2  - Soft material-enabled electronics offer distinct advantage, over conventional rigid and bulky devices, for numerous wearable and implantable applications. Soft materials allow for seamless integration with skin and tissues due to enhanced mechanical flexibility and stretchability. Wearable devices, such as sensors, offer continuous, real-time monitoring of biosignals and movements, which can be applied in rehabilitation and diagnostics, among other applications. Soft implantable electronics offer similar functionalities, but with improved compatibility with human tissues. Biodegradable soft implantable electronics are also being developed for transient monitoring, such as in the weeks following surgery. To further advance soft electronics, materials, integration strategies, and fabrication techniques are being developed. This paper reviews recent progress in these areas, toward the development of soft material-enabled electronics for medicine, healthcare, and human-machine interfaces
UR  - https://mdpi.com/books/pdfview/book/2082
UR  - https://directory.doabooks.org/handle/20.500.12854/59641
ER  -