Results 281 to 290 of about 1,018,658 (375)

Autonomous Implants

Advanced Materials, EarlyView.
An ideal implant should mimic native tissues such that it can integrate, sense, heal, and continue to function, i.e., be autonomous. Although early, there are good steps taken in this way, e.g., the development of stimuli‐responsive, self‐powering, self‐actuating, self‐healing, self‐regenerating, and self‐aware implants.
Jagan Mohan Dodda, Marcel F. Kunrath, Ling Zhou Zhao, Mahdi Bodaghi, Armin Yousefi, Nureddin Ashammakhi   +5 more
wiley   +1 more source

MRI of neuronal network structure, function, and plasticity [PDF]

, 2009
Henning U. Voss, Nicholas D. Schiff
openalex   +1 more source

Thermally Drawn Multifunctional All‐Hydrogel Fibers for Anti‐Fibrotic and Multimodal Neural Interfaces

Advanced Materials, EarlyView.
Hydrogels demonstrate material properties that mimic the mechanical and chemical environments of biological tissues. Yet, they face challenges during their integration into 3D interfaces. By identifying a class of thermoplastic hydrogels, a strategy is developed to pattern hydrogels in thermally drawn fibers.
Changhoon Sung, Kum Seok Nam, Yeji Kim, Honey Kang, Kanghyeon Kim, Chanwoong Yoon, Somin Lee, Ain Chung, Jiheong Kang, Young‐Gyun Park, Alan Jung Park, Haider Butt, Hyunwoo Yuk, Seongjun Park   +13 more
wiley   +1 more source

Importance of magnetic information for neuronal plasticity in desert ants. [PDF]

Proc Natl Acad Sci U S A
Grob R, Müller VL, Grübel K, Rössler W, Fleischmann PN.   +4 more
europepmc   +1 more source

Neuronal plasticity in animal models and the epileptic human hippocampus [PDF]

, 2009
Günther Sperk, Meinrad Drexel, Susanne Pirker   +2 more
openalex   +1 more source

Linear and Symmetric Artificial Synapses Driven by Hydrogen Bonding for Accurate and Reliable Neuromorphic Computing

Advanced Materials, EarlyView.
Hydrogen‐bond‐driven interface engineering enables highly linear and symmetric artificial synapses based on CsPbI3–PVA hybrids. This strategy suppresses trap states and guides directional ion migration, yielding stable optoelectronic plasticity. The devices achieve ultralow power operation and human‐like learning in neuromorphic networks, offering a ...
Min Jong Lee, Sang Heon Lee, Dong Gyu Lee, Tae Hyuk Kim, Yubhin Cho, Gyeong Min Lee, Sung Su Yoon, Seon Joong Kim, Hyungju Ahn, Tae Kyung Lee, Jae Won Shim   +10 more
wiley   +1 more source

Hypothermia effects on neuronal plasticity post spinal cord injury. [PDF]

PLoS One
Al-Nashash H, Wong KL, All AH.
europepmc   +1 more source

Chromatin Regulation of Neuronal Maturation and Plasticity

Trends in Neurosciences, 2018
David A. Gallegos, Urann Chan, Liang-Fu Chen, A. West   +3 more
semanticscholar   +1 more source

Soft and Strong: Elastic Conductors with Bio‐Inspired Self‐Protection

Advanced Materials, EarlyView.
A general reverse‐engineering approach is demonstrated for designing functional yarns that uses woven fabric architecture as a structural framework. The fabric‐based stretchable conductive yarns combine flexibility, high elasticity, low stiffness, self‐protection, and weavability with conventional textile processes. By fine‐tuning the number of elastic
Chenglong Zhang, Xiulun Yin, Chris Zhou, Xin Lu, Siying Wu, Ying Li, Addie Bahi, Sukhneet Kaur Dhillon, Orlando J. Rojas, Jinhua Jiang, Nanliang Chen, Frank K. Ko, John D. W. Madden   +12 more
wiley   +1 more source

Effect of combined training in water on hippocampal neuronal Plasticity and memory function in healthy elderly rats. [PDF]

AIMS Neurosci
Askari R, NasrAbadi M, Haghighi AH, Mahin MJ, Somayeh R, Pusceddu M.   +5 more
europepmc   +1 more source