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Like buoys bobbing on the ocean, many receptors float on the surface of a cell’s membrane with a part sticking above the water and another underwater, inside the cell’s cytoplasm. But for cells to function, these receptors must be docked at specific regions of the cell. Most research has focused on the ‘underwater’ portions. That’s where the cell’s molecular machines swarm and interact with a receptor’s underwater tails, with those interactions then fueling signals that dive deep into the nucleus, changing the cell’s course.

New work by a team of Thomas Jefferson University researchers reveals new activity above the surface, in brain-cell receptors that govern learning and chronic pain. In the study, the authors show that the ‘above water’ portion of proteins can help dock the proteins at synapses, where neurons mediate flow of information throughout the brain. This discovery opens the possibility of using this docking site as a target to develop treatments for chronic pain and other diseases more effectively. The study was published January 29th in Nature Communications.

“The extracellular spaces — the parts ‘above the water’ — have been largely overlooked,” says senior author Matthew Dalva, PhD, professor and vice chair of the Department of Neuroscience and director of the Jefferson Synaptic Biology Center in the Vickie & Jack Institute for Neuroscience — Jefferson Health. Dr. Dalva and his team looked at the NMDAR receptor on brain cells and pinpointed the spot where this receptor interacts with a neighbor to initiate signaling. “When trying to develop new therapy, finding the bullseye is half the problem,” says Dr. Dalva.

The idea is to use AI to develop a platform for detecting biomarkers from neural data. Then long-life neural interfaces (connections that allow computers to read and write neural data directly to and from the body) could be combined with a deep intelligence system trained to assess biomarkers directly from neural data.

If the AI platform is able to understand the “language” of the nervous system it could be used in closed-loop experiments to test neuromodulation therapy on new targets. This could accelerate the development of treatments for a number of chronic conditions and would also be a big step closer to real-world clinical applications of AI within the body. This progress could create a new way to investigate medical conditions, accelerate the detection of neural biomarkers, and open the door to a new generation of AI-based neural medical procedures.

NeuroTech is one of the most promising areas of BioTech. In the last 20 years private capital funds invested more than $19 billion in the sector, and annual growth of investment in the sector is 31%. Some NeuroTech subsectors are already well-established with practical implementations and products on the market. Over the next several years, many early-stage startups will evolve into mature companies and bring new NeuroTech products to market. Advances in AI and increased integration of computers and biology could lead to improved brain health for people all over the world.

https://youtube.com/watch?v=OMxfffqyDtc

Last week, U.S. Senator Richard Blumenthal grilled wireless industry representatives, who admitted the industry has done ZERO health & safety studies on 5G technology. Meanwhile, dozens of independent studies indicates that 5G is a risk to all biological life. Watch the video above, on YouTube here, or on Facebook here.

Scientific studies continue to show us how exercise can bring a range of cognitive benefits, from limiting the risk of Alzheimer’s to giving an immediate boost to our learning capabilities. Researchers working in this area at the University of South Australia have turned their attention to neuroplasticity, finding two styles of workout in particular that give this key brain function the biggest boost.

Neuroplasticity refers to the brain’s ability to rewire the neural connections as we go through life, whether that be in response to certain experiences, building memories, learning new skills or adapting to new environments. In this way, it is seen as critical to the development of a healthy brain from infancy all the way through to adulthood, and the authors of this new study set out to dig into how exercise can influence these vital pathways.

“We already know that engaging in regular aerobic exercise is good for the brain, improving memory, attention and learning,” says co-author Dr Ashleigh Smith. “However, we need to understand why it is so beneficial and what the best exercise, intensity and duration is.”

University of Bayreuth researchers, together with scientists from Italy and China, have for the first time systematically investigated under which conditions, and to what extent, sulphur-containing arsenic compounds are formed in rice-growing soils. To date, these thioarsenates have not been taken into account in assessments of the health effects of rice consumption. In the journal Nature Geoscience the scientists present their results and identify the urgent need for research with a view to protecting consumers from health risks.

A new measuring method for thioarsenates

The research team, headed by the Bayreuth environmental geochemist Prof. Dr. Britta Planer-Friedrich, has developed a measuring method by means of which thioarsenates in soils can be reliably detected. Up to now, the methods routinely used to monitor in rice fields have not been sufficient for this purpose. This is because they are not able to identify sulphur-containing arsenic compounds as such, or to distinguish them from oxygen-containing arsenic compounds. This shortcoming is highly problematic in terms of possible . At least one organic sulphur-containing arsenic compound discovered in rice fields is already known to be carcinogenic. This makes it all the more important to specifically detect organic sulphur-containing arsenic compounds, and to examine them for their toxicity. Presumably, these compounds have been confused with non-toxic organic oxygenated arsenic compounds up to now due to inadequate measurement procedures.

SANTA CLARA COUNTY, Calif. (KRON) — County officials have extended their declaration of a local health emergency in Santa Clara County due to the coronavirus outbreak.

Interactive Map: Track the coronavirus outbreak in real-time

Officials stressed that this does not mean there is an increased risk to the public.

https://www.youtube.com/watch?v=G6ZRmAtj6l8&t=1s

Santa Cruz, CA February 7, 2020 —Research into the novel Wuhan seafood market pneumonia virus, the deadly “coronavirus” that has forced the Chinese government to quarantine more than 50 million people in the country’s dense industrial heartland, will be facilitated by the UC Santa Cruz Genomics Institute. The Genomics Institute’s Genome Browser team has posted the complete biomolecular code of the virus for researchers all over the world to use.

“When we display coronavirus data in the UCSC Genome Browser, it lets researchers look at the virus’ structure and more importantly work with it so they can research how they want to attack it,” said UCSC Genome Browser Engineer Hiram Clawson.

Samples of the virus have been processed in labs all over the world, and the raw information about its genetic code has been sent to the worldwide repository of genomic information at the National Institutes of Health’s National Center for Bioinformatics (NCBI) in Bethesda, Maryland.