Wang et al., 2022 - Google Patents
Intrinsically stretchable electronics with ultrahigh deformability to monitor dynamically moving organsWang et al., 2022
View HTML- Document ID
- 527450405763800581
- Author
- Wang S
- Nie Y
- Zhu H
- Xu Y
- Cao S
- Zhang J
- Li Y
- Wang J
- Ning X
- Kong D
- Publication year
- Publication venue
- Science advances
External Links
Snippet
Intrinsically stretchable electronics represent an attractive platform for next-generation implantable devices by reducing the mechanical mismatch and the immune responses with biological tissues. Despite extensive efforts, soft implantable electronic devices often exhibit …
- 210000000056 organs 0 title abstract description 10
Classifications
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61N—ELECTROTHERAPY; MAGNETOTHERAPY; RADIATION THERAPY; ULTRASOUND THERAPY
- A61N1/00—Electrotherapy; Circuits therefor
- A61N1/02—Details
- A61N1/04—Electrodes
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Wang et al. | Intrinsically stretchable electronics with ultrahigh deformability to monitor dynamically moving organs | |
| Lim et al. | Tissue-like skin-device interface for wearable bioelectronics by using ultrasoft, mass-permeable, and low-impedance hydrogels | |
| Someya et al. | The rise of plastic bioelectronics | |
| Fu et al. | Functional conductive hydrogels for bioelectronics | |
| Jiang et al. | Topological supramolecular network enabled high-conductivity, stretchable organic bioelectronics | |
| Lee et al. | Nonthrombogenic, stretchable, active multielectrode array for electroanatomical mapping | |
| Zhang et al. | Climbing-inspired twining electrodes using shape memory for peripheral nerve stimulation and recording | |
| Choi et al. | Highly conductive, stretchable and biocompatible Ag–Au core–sheath nanowire composite for wearable and implantable bioelectronics | |
| Sunwoo et al. | Advances in soft bioelectronics for brain research and clinical neuroengineering | |
| Decataldo et al. | Stretchable low impedance electrodes for bioelectronic recording from small peripheral nerves | |
| Xu et al. | Materials and fractal designs for 3D multifunctional integumentary membranes with capabilities in cardiac electrotherapy | |
| Jeong et al. | Soft materials in neuroengineering for hard problems in neuroscience | |
| Koo et al. | Unconventional device and material approaches for monolithic biointegration of implantable sensors and wearable electronics | |
| Choi et al. | Adhesive bioelectronics for sutureless epicardial interfacing | |
| Wu et al. | Electrode materials for brain–machine interface: A review | |
| Lienemann et al. | Stretchable gold nanowire-based cuff electrodes for low-voltage peripheral nerve stimulation | |
| Sunwoo et al. | Stretchable low-impedance conductor with Ag–Au–Pt core–shell–shell nanowires and in situ formed pt nanoparticles for wearable and implantable device | |
| Green et al. | Novel neural interface for implant electrodes: improving electroactivity of polypyrrole through MWNT incorporation | |
| Jastrzebska-Perfect et al. | Mixed-conducting particulate composites for soft electronics | |
| Yang et al. | Robust neural interfaces with photopatternable, bioadhesive, and highly conductive hydrogels for stable chronic neuromodulation | |
| Yu et al. | Design of highly conductive, intrinsically stretchable, and 3D printable PEDOT: PSS hydrogels via PSS-chain engineering for bioelectronics | |
| Deo et al. | Nanoengineered ink for designing 3D printable flexible bioelectronics | |
| Carvalho et al. | Nondrying, sticky hydrogels for the next generation of high-resolution conformable bioelectronics | |
| Jimbo et al. | Ultraflexible transparent oxide/metal/oxide stack electrode with low sheet resistance for electrophysiological measurements | |
| Dong et al. | Highly stretchable metal–polymer conductor electrode array for Electrophysiology |