Bioengineers have developed biocompatible self-assembling “piezoelectric wafers,” which can be made rapidly and inexpensively to enable broad use of implantable muscle-powered electromechanical therapies.
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A team has developed a new brain stimulation technique using focused ultrasound that is able to turn specific types of neurons in the brain on and off and precisely control motor activity without surgical device implantation.
New research demonstrates that noninvasive neuromodulation via low-intensity ultrasound can have cell-type selectivity in manipulating neurons.
A new study lays out a large medical analytics framework that can be used in neuroscience and neurology to study brain connectivity in living organisms.
Researchers have designed a skin-like device that can be attached to the face and measure small movements such as a twitch or a smile. With this approach, patients with amyotrophic lateral sclerosis (ALS) could communicate a variety of sentiments with small movements that are measured and interpreted by the device.
Marking a major milestone on the path to meeting the objectives of the NIH BRAIN initiative, researchers advance high-density electroencephalography (EEG) as the future paradigm for dynamic functional neuroimaging.
Medical physicists at the Mayo Clinic have just made a unique library of computed tomography (CT) data publicly available so that imaging researchers can study, develop, validate, and optimize algorithms and enhance imaging hardware to produce peak-quality CT images using low radiation doses.
Grace C.Y. Peng, Ph.D., Director of the NIBIB Program in Mathematical Modeling, Simulation and Analysis, has been elected to the American Institute for Medical and Biological Engineering (AIMBE College of Fellows).
With the help of photolithography and programmable DNA, researchers have created a new technique that can rapidly 'print' two-dimensional arrays of cells and proteins that mimic a wide variety of cellular environments in the body. This technique could help scientists develop a better understanding of the complex cell-to-cell messaging that dictates a cell's final fate.
Ranu Jung designs neural engineering projects that drive the process of transforming basic discoveries into clinical applications. In this interview she explains how collaborative projects can at once advance the understanding of the brain and the development of medical devices.