NBC News reporter Maggie Fox writes that MIT researchers have developed a noninvasive brain stimulation technique that could eventually offer relief to patients with diseases like Parkinson’s and epilepsy without requiring surgery. Fox explains that the method allows for sending, “electrical signals deep into the brain without affecting the layers in between.”
MIT researchers have developed a noninvasive method to stimulate specific neurons deep in the brain that could be used to help treat patients with diseases such as Parkinson’s, reports Meredith Wadman for Science. This new method could also allow scientists to “selectively prod deep-brain neurons into action,” explains Wadman.
Writing for Wired, Abigail Beal highlights how MIT researchers have developed a noninvasive technique to trigger reactions in deep brain cells using low frequency electrical signals. “If we could noninvasively stimulate deep regions, without hitting overlying regions, we might be able to help more people because we could stimulate deep regions selectively, without needing surgery,” explains Prof. Ed Boyden.
MIT researchers have developed a non-invasive technique for deep brain stimulation, which could be used to help patients with brain diseases, reports Mo Costandi for The Guardian. “Targets for disorders such as depression, Alzheimer’s, PTSD, and so forth, are deep in the brain, and they might be more selectively stimulatable with our method,” says Prof. Ed Boyden.
Meg Tirrell of CNBC spotlights research by Prof. Li-Huei Tsai that shows that flashing lights could be used as a non-invasive treatment method for Alzheimer’s disease. Tsai and her colleagues found that flashing light could potentially be used to restore gamma rhythms in the brain, which are often impaired in people with Alzheimer’s.
Inside Higher Ed reporter Colleen Flaherty writes that researchers from MIT and around the world are publicly defending the late Prof. Suzanne Corkin’s work with patient H.M. in response to a highly critical publication. When “so many scholars rise to defend the reputation of a deceased colleague,” says Arthur Caplan, head of NYU’s Division of Bioethics, “that speaks volumes both about her and the problems that exist in the book.”
MIT researchers have discovered that a bacterium found in the human mouth can be used to form a new CRISPR gene-editing system that can target RNA, reports Carl Zimmer for The New York Times. The development “may open up a new front in gene engineering, gaining the ability to precisely adjust the proteins in cells, for instance, or to target cancer cells."
New Scientist reporter Colin Barras writes that MIT researchers have found they can program C2c2, an enzyme found in bacteria, to serve as an RNA-editing tool. Barras writes that the tool “promises to transform our understanding of RNA’s role in our growth and development, and provide a new avenue for treating infectious diseases and cancer.”
Prof. Feng Zhang has been named a recipient of the 2016 Canada Gairdner International Award for his work on the development of the CRISPR gene-editing system, reports CBC News. CRISPR "may prove to be a ‘powerful therapeutic’ for treating human diseases by editing out harmful genetic mutations.”
Globe and Mail reporter Ivan Semeniuk spotlights Prof. Feng Zhang and his role in developing the CRISPR-Cas9 gene-editing system, for which he was honored as a recipient of the 2016 Canada Gairdner International award. “CRISPR genome editing technology is a really powerful platform,” says Zhang. “It think it will advance both our ability to understand disease and to develop treatments.”
MIT researchers have found a possible link between attention deficit disorders and autism, reports Lindsay Kalter for The Boston Herald. “One of the long-term goals is gene therapy where we can actually introduce genetic material that might be missing from the human,” explains grad. student Michael Wells.
Popular Science reporter Claire Maldarelli writes that researchers from MIT have identified how sensory overload occurs for people with neurodevelopmental disorders. Based off their findings, the researchers hope they can "classify these disorders in a better way, but also develop therapies that alleviate or diminish the symptoms.”
A study by MIT researchers illustrates how the brain responds to music, writes Jill Suttie for The Huffington Post. "You want to know what is it about bluegrass music that makes it sound like bluegrass? We think that finding this neural population will help us to answer that question going forward,” explains postdoc Sam Norman-Haignere.
Boston Magazine reporter Jamie Ducharme writes that MIT researchers have found that they can reverse some of the behavioral symptoms association with autism. Ducharme explains that, “the discovery may open the door to developing more universal approaches to treating autism, like identifying and targeting the specific circuits that cause each patient’s behavioral gaps.”
New York Times reporter Natalie Angier writes that MIT researchers have identified regions of the brain that react to music. “Why do we have music? Why do we enjoy it so much and want to dance when we hear it?” says Prof. Nancy Kanwisher. “These are the really cool first-order questions we can begin to address.”