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Neuroscience

Marcus Neuroscience Institute names Khalid A. Hanafy, M.D., Ph.D., Medical Director of Neurocritical Care and Research – Baptist Health South Florida

October 13th, 2020 Baptist Health South Florida

Boca Raton, FL October 13, 2020 Khalid A. Hanafy, M.D., Ph.D., has joined Marcus Neuroscience Institute at Boca Raton Regional Hospital, part of Baptist Health, as medical director of neurocritical care and director of research. He specializes in the care of subarachnoid hemorrhage patients and the study of neuroinflammation. He also serves as associate professor of neurology at Florida Atlantic University Charles E. Schmidt College of Medicine in Boca Raton. He is board certified in neurology and neurocritical care.

Dr. Hanafy joined Marcus Neuroscience Institute from Beth Israel Deaconess Medical Center/Harvard Medical School in Boston, Mass., where he served as the director of the neurological intensive care unit and was an assistant professor of neurology at Harvard Medical School.

We are pleased to welcome Dr. Hanafy to Marcus Neuroscience Institute, said Frank D. Vrionis, M.D., MPH, Ph.D., Institute director and chief of neurosurgery. His clinical skills, research acumen and leadership in the field of neurology will greatly benefit our team and our patients.

As the Institutes director of research, Dr. Hanafy is principal investigator of cutting-edge studies that seek to bring the most advanced, personalized treatments to subarachnoid hemorrhage patients and improve their survival rates and health outcomes. His groundbreaking work in neuroinflammation has been funded by the National Institutes of Health, American Heart Association, American Academy of Neurology, and Massachusetts Institute of Technology. Marcus Neuroscience Institute is at the forefront of stem cell therapeutics, and Dr. Hanafy and Dr. Vrionis have already initiated clinical trials using stem cells in critically ill COVID patients. Together, they will expand research and clinical trials using stem cells for the treatment of other neurological conditions, such as stroke and brain tumors.

Dr. Hanafy has authored more than 40 articles, book chapters and invited editorials in peer-reviewed scientific publications and serves on the editorial boards of scholarly journals in his field. He is a member of several professional societies, including the American Academy of Neurology, Society for Neuroscience Research, Society of Critical Care Medicine, and Neurocritical Care Society.

Dr. Hanafy earned his medical degree and doctorate degree in molecular biology at the University of Texas Medical Scientist Training Program at Houston, a dual degree program of the University of Texas McGovern Medical School and MD Anderson Cancer Center UTHealth Graduate School of Biomedical Sciences. He did his thesis graduate work under Dr. Ferid Murad, the 1998 Nobel laureate. He returned to these Houston facilities to complete a neurology residency following an internal medicine internship at the University of Texas Southwestern at Parkland Memorial Hospital in Dallas. He concluded his medical training with a two-year fellowship in neurological critical care at Columbia University Medical Center in New York City.

About the Marcus Neuroscience InstituteThe Marcus Neuroscience Institute at Boca Raton Regional Hospital is an innovative nexus for neurologic and neurosurgical care. The 57,000-square-foot facility houses a 20-bed Neuro Intensive Care and Step-Down Unit, four dedicated operating rooms including one equipped with intraoperative MRI and two with intraoperative CT capability and a biplane angiography suite, a crucial component in the diagnosis and care of neurological conditions. The Institute has a staff of five neurosurgeons and nine neurologists who represent some of the most respected clinicians in their fields and is affiliated with Florida Atlantic Universitys Charles E. Schmidt College of Medicine.

About Boca Raton Regional HospitalBoca Raton Regional Hospital is part of Baptist Health South Florida, the largest healthcare organization in the region, with 11 hospitals, nearly 23,000 employees, more than 4,000 physicians and more than 100 outpatient centers, urgent care facilities and physician practices spanning across Miami-Dade, Monroe, Broward and Palm Beach counties. Baptist Health has internationally renowned centers of excellence in cancer, cardiovascular care, orthopedics and sports medicine, and neurosciences. In addition, it includes Baptist Health Medical Group; Baptist Health Quality Network; and Baptist Health Care On Demand, a virtual health platform. A not-for-profit organization supported by philanthropy and committed to our faith-based charitable mission of medical excellence, Baptist Health has been recognized by Fortune as one of the 100 Best Companies to Work For in America and by Ethisphere as one of the Worlds Most Ethical Companies. For more information, visit BaptistHealth.net/Newsroom and connect with us on Facebook, Instagram, Twitter and LinkedIn.

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Marcus Neuroscience Institute names Khalid A. Hanafy, M.D., Ph.D., Medical Director of Neurocritical Care and Research - Baptist Health South Florida

Neuroscience

Neurochemicals Dopamine and Serotonin Have Unexpected Role in Perception – Technology Networks

In first-of-their-kind observations in the human brain, an international team of researchers has revealed two well-known neurochemicals -- dopamine and serotonin -- are at work at sub-second speeds to shape how people perceive the world and take action based on their perception.

The discovery shows researchers can continually and simultaneously measure the activity of both dopamine and serotonin -- whose receptor and uptake sites are therapeutic targets for disorders ranging from depression to Parkinson's disease -- in the human brain.

Furthermore, the neurochemicals appear to integrate people's perceptions of the world with their actions, indicating dopamine and serotonin have far more expansive roles in the human nervous system than previously known.

Known as neuromodulators, dopamine and serotonin have traditionally been linked to reward processing -- how good or how bad people perceive an outcome to be after taking an action.

The study online today in the journal Neuron opens the door to a deeper understanding of an expanded role for these systems and their roles in human health.

"An enormous number of people throughout the world are taking pharmaceutical compounds to perturb the dopamine and serotonin transmitter systems to change their behavior and mental health," said P. Read Montague, senior author of the study and a professor and director of the Center for Human Neuroscience Research and the Human Neuroimaging Laboratory at the Fralin Biomedical Research Institute at Virginia Tech Carilion. "For the first time, moment-to-moment activity in these systems has been measured and determined to be involved in perception and cognitive capacities. These neurotransmitters are simultaneously acting and integrating activity across vastly different time and space scales than anyone expected."

Better understanding of the underlying actions of dopamine and serotonin during perception and decision-making could deliver important insight into psychiatric and neurological disorders, the researchers said.

"Every choice that someone executes involves taking in information, interpreting that information, and making decisions about what they perceived," said Kenneth Kishida, a corresponding author of the study and an assistant professor of physiology and pharmacology, and neurosurgery, at Wake Forest School of Medicine. "There's a whole host of psychiatric conditions and neurological disorders where that process is altered in the patients, and dopamine and serotonin are prime suspects."

Lack of chemically specific methods to study neuromodulation in humans at fast time scales has impeded understanding of these systems, according to Montague, who is an honorary professor at the Wellcome Center for Human Neuroimaging at University College London and a professor of physics at the Virginia Tech College of Science.

But now, in first-ever measurements, scientists used an electrochemical method called "fast scan cyclic voltammetry," which employs a small carbon fiber microelectrode that has low voltages ramped across it for real-time detection of dopamine and serotonin activity.

In the study, researchers recorded fluctuations in dopamine and serotonin using specially designed electrodes in five patients undergoing deep brain stimulation electrode implantation surgery to treat essential tremor or Parkinson's disease. Patients were awake during surgery, playing a computer game designed to quantify aspects of thought and behavior while the measurements were taken.

On each round of the game, patients briefly viewed a cloud of dots and were asked to judge the direction they were moving. The method, designed by corresponding author Dan Bang, a Sir Henry Wellcome Postdoctoral Fellow, and Steve Fleming, a Sir Henry Dale/Royal Society Fellow, both at the Wellcome Center for Human Neuroimaging at University College London, helped indicate that dopamine and serotonin were involved in simple perceptual decisions, outside of the traditional context of rewards and losses.

"These neuromodulators play a much broader role in supporting human behavior and thought, and in particular they are involved in how we process the outside world," Bang said. "For example, if you move through a room and the lights are off, you move differently because you're uncertain about where objects are. Our work suggests these neuromodulators -- serotonin in particular-- are playing a role in signaling how uncertain we are about the outside environment."

Montague and Kishida, along with Terry Lohrenz, a research assistant professor, and Jason White, a senior research associate, now both at the Fralin Biomedical Research Institute, started working on a new statistical approach to identify dopamine and serotonin signals while still at the Baylor College of Medicine in Houston, Texas.

"Ken rose to the challenge of doing fast neurochemistry in human beings during active cognition," Montague said. "A lot of other good groups of scientists were not able to do it. Aside from the computation of enormous amounts of data, there are complicated issues to solve, including great, fundamental algorithmic tasks."

Until recently, only slow methodologies such as PET scanning could measure the impact of neurotransmitters, but they were nowhere near the frequency or volume of the second-to-second measurements of fast scan cyclic voltammetry.

The measurements in the new study were taken at the Wake Forest Baptist Medical Center, and involved neurosurgical teams led by Adrian W. Laxton and Stephen B. Tatter.

"The enthusiasm the neurosurgeons have for this research is derived from the same reasons that drove them to be doctors -- first and foremost, they want to do the best for their patients, and they have a real passion for understanding how the brain works to improve patient outcomes," said Kishida, who oversaw the data collection in the operating room during the surgeries. "Both are collaborative scientists along with Charles Branch, the chair of the neurosurgery department at Wake Forest, who has been an amazing advocate for this work."

Likewise, Montague said, "You can't do it without the surgeons being real, shoulder-to-shoulder partners, and certainly not without the people who let you make recordings from their brains while they are having electrodes implanted to alleviate the symptoms of a neurological disorder."

Montague had read a study in the Proceedings of the National Academy of Sciences that prompted him to approach colleagues Bang and Fleming at University College London to tailor a task for patients to perform during surgery that would reveal sub-second dopamine and serotonin signaling in real-time inference about the external world - separate from their often-reported roles in reward-related processes.

"I said I have this new method to measure dopamine and serotonin, but I need you to help with the task," Montague said. "They ended up in the study. The research really took a lot of hard work and an integrated a constellation of people to obtain these results."

The research was funded by grants to various researchers from the Wellcome Trust, the National Institutes of Health including the National Institute on Drug Abuse, the National Institute of Mental Health, the National Institute of Neurological Disorders and Stroke.Reference: Bang D, Kishida KT, Lohrenz T, et al.Sub-second Dopamine and Serotonin Signaling in Human Striatum during Perceptual Decision-Making. Neuron. 2020.doi:10.1016/j.neuron.2020.09.015

This article has been republished from the following materials. Note: material may have been edited for length and content. For further information, please contact the cited source.

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Neurochemicals Dopamine and Serotonin Have Unexpected Role in Perception - Technology Networks

Neuroscience

Free sessions on legal and financial issues for those with neurological conditions – Norton Healthcare

The 2020 Neuroscience Expo will host a morning of free online sessions with legal and financial advisers, tailored exclusively to those dealing with a neurological condition and their caregivers.

Living a happy, fulfilling life goes beyond exceptional medical care. It includes caring for the whole person and their day-to-day struggles.

This Norton Neuroscience Institute event gives individuals living with a neurological condition and their family, caregivers, support care providers and others a way to collect valuable information.

Friday, Oct. 23, 9 a.m. to 12:30 p.m.

This years Norton Neuroscience Institute conference will be livestreamed, but space is limited.

Register Today

This years track for legal and financial resources features the following sessions:

Learn how to create a life care plan for you or a loved one.

Jefferey Yussman and Gordon Homes

Living with a disability can be challenging and requires planning for future needs. Youll learn ways you can financially prepare for the future.

Jefferey Yussman and Gordon Homes

If you wanted to know about the importance of having your affairs in order, this presentation will outline the various legal documents that would ensure your peace of mind.

Victor E. Tackett Jr.

Is it time to apply for disability? Where do I begin? Learn the latest on Social Security disability applications and the process of filing a disability claim.

Sam Schad

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Free sessions on legal and financial issues for those with neurological conditions - Norton Healthcare

Neuroscience

Recovering from a stroke and preventing another at the free 2020 Neuroscience Expo – Norton Healthcare

As you or a loved one recover from stroke, changing needs can present new challenges or require adjustments in the care plan, especially since patients whove had a stroke are at higher risk for another. The 2020 Neuroscience Expo will offer an afternoon of exclusively online sessions for those who have had a stroke or care for someone who has.

This free event allows individuals living with a neurological condition, family or caregivers, support care providers and others a way to connect with speakers from Norton Neuroscience Institute and other stroke-related specialties for live presentations.

This years track for life after stroke features the following sessions:

Youll hear uplifting messages as two stroke survivors share their experiences of life after stroke.

Thursday, Oct. 22, 1 to 5 p.m.Neuroscience Expo will be livestreamed, but space is limited.

Register Today

A stroke specialist will discuss what you can do to prevent another stroke.

Jeanette Lanoire, DPT, NCS

Neuroplasticity and Rehabilitation After Stroke

The recovery process relies on the ability of the brain to heal itself. Learn about neuroplasticity, as well as the importance and benefits of rehabilitation

Colin Hulls, DPT, NCS

Keegan Humphrey, MSOT, OTR/L, CDI, CLVT, DPAM

A neurologist will discuss the benefits of Botox injections for post-stroke spasticity muscle stiffness or tightness.

Mohammad S. Alsorogi, M.D.

After a stroke, survivors often experience emotional and behavioral changes. A mental health therapist will share strategies to manage your feelings.

Cheryl L. Young, MAMFT, MSCS

Eating well after a stroke is key to recovery. A registered dietitian will discuss diet changes and healthy food options.

Sarah Frederickson, R.D., L.D.

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Recovering from a stroke and preventing another at the free 2020 Neuroscience Expo - Norton Healthcare

Neuroscience

Middlebury Welcomes 33 New Faculty – Middlebury College News and Events

MIDDLEBURY, Vt. Middlebury College welcomes 33 new faculty members this fall, including 13 in tenure-track positions. The new teachers and researchers participated in orientation sessions that were conducted weekly throughout August via Zoom. As a group, they represent 19 academic disciplines.

Middlebury is fortunate to be able to hire some of the best faculty emerging in their fields, said Sujata Moorti, vice president for academic affairs and dean of the faculty. They come from a wide array of institutions and offer expertise in research topics ranging from ethnic violence in India to pain processing in the spinal cord.

We are excited to welcome them to Middlebury, said Moorti.

The following will join Middlebury this fall as tenure-track faculty members, with the exception of Alexis Mychajliw, who will join in the spring.

Kathryn Crawford, assistant professor of environmental studies, comes to Middlebury from the Geisel School of Medicine at Dartmouth, where she was a postdoctoral research associate in epidemiology. Crawford earned her PhD in environmental health at Boston University, and an MS in natural resources and a BS in environmental science at the University of Vermont.

Jennifer Crodelle, assistant professor of mathematics, was most recently a postdoctoral research fellow at the Courant Institute of Mathematical Sciences at New York University. Crodelle earned her PhD in mathematics and her MS in applied mathematics at Rensselaer Polytechnic Institute, and her BS from Marist College. Her research interests include the dynamics of neuronal networks during development and mechanisms underlying pain processing in the spinal cord.

John Foley, assistant professor of computer science, earned his PhD and MS in computer science at the University of Massachusetts Amherst and his BS in computer engineering at the University of Massachusetts Lowell. Before teaching at Middlebury, he was a visiting assistant professor at Smith.

Raphaelle Gauvin-Coulombe, assistant professor of economics, earned her PhD and MA in economics at Queens University in Kingston, Ontario, and her BA in economics at the University of Ottawa in Ottawa, Ontario.

Kara Karpman, assistant professor of mathematics, earned her PhD and MS in applied mathematics at Cornell and her BS in mathematics at Duke University.

Niwaeli Kimambo, assistant professor of geography, was previously a GIS teaching fellow at Middlebury beginning in 2019. She earned her PhD and MS in geography from the University of WisconsinMadison. She also holds a BA in geologic sciences and history from Brown.

Alexis Mychajliw, assistant professor of biology and environmental studies, will join the faculty this spring. She is a postdoctoral research fellow at Hokkaido University in Japan. Mychajliw earned her PhD in biology at Stanford and her BS in biological sciences at Cornell. Her areas of interest include the study of genomes, bones, and sediments to determine how organisms responded to anthropogenic and climatic changes in the past.

Gregory Pask, assistant professor of biology, comes to Middlebury from Bucknell University, where he was an assistant professor of biology. He earned his PhD in biological sciences at Vanderbilt University and his BS in biochemistry at Muhlenberg College. His area of research includes the powerful sense of smell insects use to locate food, find mates, and communicate with others.

Olga Sanchez-Saltveit, assistant professor of theatre, earned her PhD in theatre arts from the University of Oregon, her MA in human and bicultural development from Pacific Oaks College, and her BA in theatre at Hunter College. Most recently she was a visiting assistant professor of theatre at Franklin and Marshall College. Virginia Thomas, assistant professor of psychology, arrived at Middlebury from Wilmington College, where she held the same position. She earned her PhD in developmental psychology with an emphasis on feminist studies at the University of California, Santa Cruz; MA in depth psychology at Sonoma State University; and BS in psychology at the University of Evansville.

Ajay Verghese, assistant professor of political science, served in the same role at the University of California, Riverside, prior to coming to Middlebury. He earned his PhD in political science at George Washington University and BA in political science and French at Temple University. His first book, The Colonial Origins of Ethnic Violence in India, was published in 2016 by Stanford University Press.

Zu Wei Zhai 07, assistant professor of neuroscience, joined the Middlebury faculty as a visiting assistant professor of psychology in 2017. He received his PhD in pharmaceutical sciences from the University of Pittsburgh and his BA in neuroscience from Middlebury.

Gyula Zsombok, assistant professor of French and Francophone studies, earned his PhD and MA in French linguistics at the University of Illinois Urbana-Champaign and his BA in French philology atEtvs Lornd Tudomnyegyetem in Budapest.

Middlebury is also pleased to welcome the following visiting faculty, professors of the practice, instructors, lecturers, and teaching assistants:

Visiting Assistant Professors

Cole Dovey 06, PhD, University of California, San Francisco, visiting assistant professor of chemistry and biochemistry

Alla Fil, PhD, Georgetown University, visiting assistant professor of Luso-Hispanic studies

Michael French, PhD, Northwestern University, visiting assistant professor of chemistry and biochemistry

Alena Giesche 11, PhD, University of Cambridge, UK, visiting assistant professor of geology

Robert Izsak, PhD, Cardiff University, visiting assistant professor of chemistry and biochemistry

Allison Jacobel, PhD, Columbia University, visiting assistant professor of geology

Joshua Nelson, PhD, Fordham University, visiting assistant professor of psychology

Shelly Pottorf, MArch, Rice University, visiting assistant professor of architecture

Roger Russi, PhD, University of North Carolina, visiting assistant professor of first-year seminar

Tessa Wegener, PhD, Georgetown University, visiting assistant professor of German

Roger White, MFA, Columbia University, visiting assistant professor of studio art

Visiting Instructors

Tina Donaldson, MA, University at AlbanyState University of New York, visiting instructor in psychology

Mon Zabala, BA, University of Puerto Rico, visiting instructor in Luso-Hispanic studies

Lecturers and Teaching PositionsCatherine Canavan, MA, Castleton State College, lecturer in education studies, will join the faculty in the spring.

Carolyn Dash, PhD, University of Illinois Urbana-Champaign, visiting assistant laboratory professor

Daniel Fram, PhD, Michigan State University, postdoctoral fellow in political science

Emily French 19, assistant in instruction, geography

James Gallagher, PhD, Princeton University, visiting assistant laboratory professor, chemistry and biochemistry

Emily Malcolm-White, MS, University of Victoria, lecturer in mathematics

Ori Tzuriel, BA, Bar-Ilan University, Israel, lecturer in modern Hebrew

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Neuroscience

Instinct and Training Both Count When Responding to Infant Cries, Says Mouse Study – Technology Networks

Caregivers learn to decipher differences in newborn cries through a combination of hard-wired instincts and on-the-job experience, a new study in rodents shows.

Understanding the specific meaning of a baby's vocal expressions is critical in childcare for humans and other animals, experts say. However, every infant has its own unique set of cries, so the most successful parents must quickly learn to recognize subtle variations of distress and other kinds of calls.

Led by researchers at NYU Grossman School of Medicine, the study showed that female mice instinctively hurried to fetch crying infants, even if they'd never had pups of their own before. In addition, certain nerve cells in the auditory cortex, the part of the brain that processes sound, became active when the mice heard the wails.

The study, published online Oct. 7 inNature, also showed that experienced "babysitter" mice recognized more variations of cries that were calls for attention than mice with little caregiving experience. The latter group only responded to a narrow range of cries.

As the unexperienced animals spent more time living with a veteran caregiver, however, they were able to recognize a wider variety of cries and would quickly retrieve the babies.

"Our findings show that while some parenting skills are innate, there is a significant learning curve," says study lead author Jennifer Schiavo, a predoctoral fellow in the Skirball Institute of Biomolecular Medicine at NYU Langone Health. "For mother mice, and possibly for humans too, hard-earned experience matters."

The investigation also affirmed the role of the hormone oxytocin in learning parenting behavior. Extra amounts of the chemical, best known for its role in breastfeeding and parent-infant bonding, was previously shown by the team to improve recognition of barely audible pup distress calls. In the new study, when the researchers instead blocked oxytocin, experienced babysitters only retrieved crying pups as little as 40 percent of the time, compared with well over 80 percent when the hormone levels were left alone.

Similarly, without oxytocin, cells in the auditory cortex did not respond to a broader range of distress calls, even after the mice observed more experienced mothers parenting. According to Schiavo, this suggests that oxytocin helps rewire the brain and prepare it to learn new skills more easily.

For the study, the investigators measured the average number of syllables in the "come get me" cries of dozens of mouse pups to determine the standard version of the call. Then, the team sped up or slowed down recordings of the cries to create alterations that fell outside the typical range. These modified audio clips were dubbed over the pups' natural cries.

The study authors only compared expert and inexperienced caregivers, neither groups having had their own pups, in order to tease apart instinctive versus learned elements of parenting, without pregnancy complicating the matter.

They found that seasoned babysitters' brain cells became active in response to normal calls, and those mice accordingly retrieved the pups over 80 percent of the time. Meanwhile, the new babysitters' brain cells did not respond to normal calls, and these mice only picked up the pups about 33 percent of the time.

The study also showed that novices could learn to recognize altered calls over time, with pup retrieval rates as much as 75 percent. By comparison, experienced babysitters who heard the altered calls for the first time had a retrieval rate of just 14 percent.

"Our study provides new insight into how the brain learns new skills," says senior study author Robert Froemke, PhD, an associate professor in the Skirball Institute of Biomolecular Medicine at NYU Langone. "There is a built-in understanding that serves as a foundation for developing more complex behaviors in rodents."

He adds that next, the research team plans to investigate whether the inexperienced mice learn by passively observing mothers or if they are actively trained to respond to unusual calls. Froemke also serves as an associate professor in the departments of Otolaryngology-Head and Neck Surgery, and Neuroscience and Physiology at NYU Langone.

Reference: Schiavo JK, Valtcheva S, Bair-Marshall CJ, Song SC, Martin KA, Froemke RC. Innate and plastic mechanisms for maternal behaviour in auditory cortex. Nature. Published online October 7, 2020:1-6. doi:10.1038/s41586-020-2807-6

This article has been republished from the following materials. Note: material may have been edited for length and content. For further information, please contact the cited source.

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Instinct and Training Both Count When Responding to Infant Cries, Says Mouse Study - Technology Networks

Neuroscience

Traveling Brain Waves Reveal Hard-To-See Objects – Technology Networks

Imagine that you're late for work and desperately searching for your car keys. You've looked all over the house but cannot seem to find them anywhere. All of a sudden you realize your keys have been sitting right in front of you the entire time. Why didn't you see them until now?

Now, a team of Salk Institute scientists led by Professor John Reynolds has uncovered details of the neural mechanisms underlying the perception of objects. They found that patterns of neural signals, called traveling brain waves, exist in the visual system of the awake brain and are organized to allow the brain to perceive objects that are faint or otherwise difficult to see. The findings were published inNatureon October 7, 2020.

"We've discovered that faint objects are much more likely to be seen if visualizing the object is timed with the traveling brain waves. The waves actually facilitate perceptual sensitivity, so there are moments in time when you can see things that you otherwise could not," says Reynolds, senior author of the paper and holder of the Fiona and Sanjay Jha Chair in Neuroscience. "It turns out that these traveling brain waves are an information-gathering process leading to the perception of an object."

Scientists have studied traveling brain waves during anesthesia but dismissed the waves as an artifact of the anesthesia. Reynolds' team, however, wondered if these waves exist in the visual part of the brain while awake and if they play a role in perception. They combined recordings in the visual cortex with cutting-edge computational techniques that enabled them to detect and track traveling brain waves.

"In order to understand the neural mechanisms of perception, we needed to develop new computational techniques to track neuronal activity in the visual cortex moment by moment," says co-first author Lyle Muller, BrainsCAN-funded assistant professor in the Department of Applied Mathematics and the Brain and Mind Institute at Western University in Ontario, Canada, and previously a postdoctoral fellow in the Sejnowski lab at Salk. "We then used these computational methods to uncover what change was occurring in the nervous system to suddenly allow for object recognition."

The scientists recorded the activity of the neurons from an area of the brain that contained a complete map of the visual world. They then tracked the trajectories of the traveling brain waves during a visual perception task. The scientists held an onscreen target at the threshold of visibility, so that observers could only detect the object 50 percent of the time, and recorded when the target was spotted. Since the target was not changing, the researchers reasoned that the observer's ability to perceive the object only half of the time had to be due to some change in the neural signals inside the brain.

They found that the brain's ability to recognize targets was directly related to when and where the traveling brain waves occurred in the visual system: when the traveling waves aligned with the stimulus, the observer could detect the target more easily. These traveling brain waves, which occurred several times per second, were similar to a stadium of sports fans successively standing up and raising their arms, then lowering them and sitting down again. It appears that the visual system is actively sensing the external environment, according to the team.

"There is a spontaneous level of activity in the brain that appears to be regulated by these traveling waves," says Salk Professor Terrence Sejnowski, an author of the paper and holder of the Francis Crick Chair. "We think the waves are the product of the activity that is propagating around the brain, driven by local neurons firing."

"We go about our everyday lives thinking that we are accurately seeing the world, but, in fact, our brains are filling in details that are difficult to see," says Zac Davis, co-first and corresponding author of the paper and a Salk postdoctoral fellow in the Reynolds lab. "Now, we have discovered how the brain weaves together hard-to-see information to perceive an object."

In the future, the scientists plan to examine whether these brain waves are coordinated across different brain regions devoted to vision. The researchers theorize that the brain waves could serve as a gate between the sensory processing and conscious perception that emerges from the brain as a whole.

Reference:Davis ZW, Muller L, Martinez-Trujillo J, Sejnowski T, Reynolds JH. Spontaneous travelling cortical waves gate perception in behaving primates. Nature. Published online October 7, 2020:1-5. doi:10.1038/s41586-020-2802-y

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Traveling Brain Waves Reveal Hard-To-See Objects - Technology Networks

Neuroscience

The brilliant mind of Oliver Sacks – Ockham’s Razor – ABC News

Who was Oliver Sacks?

He's best known as the author of case histories on neurology among them the tale of the man who mistook his wife for a hat.

But how did he get the nickname Dr Squats? What was his relation to the Fern Society? And why did he remain celibate for more than 30 years?

Neuroscience PhD student Samuel Mills reflects and shares a few stories about the brilliant neurologist and author at Melbourne's Laborastory.

This program first aired on April 22, 2018.

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The brilliant mind of Oliver Sacks - Ockham's Razor - ABC News

Neuroscience

The Clever Combination of Neuroscience and Ancient Wisdom That Is Re-Writing the Rule Book on Success and Happiness – Press Release – Digital Journal

Passion and purpose coach Andrew Low teaches tools to create harmony between your conscious and unconscious mind so you can live your life on purpose.

Life can suck for us at times! We face stressors that take their toll on our wellbeing. Uncertainty in the world around us can trigger anxiety and even depression. We find ourselves disempowered and reacting to the world around us. We lash out, our relationships suffer. We suffer!

What can we learn from the ancient wisdom of ages past? Could the latest developments in neuroscience unlock secrets to personal transformation lost to the ages?

After toiling and struggling in a corporate job of more than 16-hour workdays, Low had been working nights and weekends when one day, he fell asleep behind the wheel and crashed his car. His accident made him realize that things had to change. He has been on a journey ever since, and now, his mission is to help you uncover your life's passion and purpose.

Low describes his pioneering approach to transformation:

"Combining ancient wisdom with the latest in neuroscience and coaching to help us let go of the past so we can live in the present with passion and purpose this is the secret to earning a great income from doing what we love. Many personal development gurus tell us what we need to do - let go, find our passions, live our purpose. But how do we do them? There are proven tools that create harmony between your conscious and unconscious minds that give you deep, cathartic and sustainable results."

Engaging with Low allows a client access to a collection of three courses that gives the formula for achieving the trifecta of success, love, and happiness. It is an immersive, practical, and experiential program that gives the whys, whats, and how-tos of the eight principles of success, love, and happiness.

According to Low, this approach empowers you to imagine the full experience of mental, emotional, and tangible breakthroughs to discover answers that are in line with your passion and purpose. If youve always dreamed of living a full, enriched, and joyful life, while earning income from doing what you love; this training can be a journey of transformation like nothing else youve ever experienced.

Low also trains individuals interested in becoming life coaches themselves. The key to serving others is first to work on yourself to heal your own past. This way, you become a shining example to others. Then, get certified in the processes to help others on a deep level, and learn and apply a blueprint to transition to full-time coaching.

For more information, visithttps://andrewlow.coach.

About Andrew Low Coaching and Training

Andrew Low is a transformation coach and trainer who focuses on helping others live their passion and purpose. Andrew is internationally certified as neuro-linguistic programming (NLP) trainer, Archetypal Coaching trainer for Passion and Purpose Coaching, Masculine and Feminine Coaching and Matrix Therapies Coaching. He holds a Diploma in Life Coaching. He has over 20 years experience in training, mentoring, and coaching in both private and public sectors and is known for his fun and effective workshop facilitation skills. He specializes in helping entrepreneurs, business professionals and everyday people discover their passions and purpose, earn a good income from it, while having fun and laughter on their journeys.

Media ContactCompany Name: Andrew Low Coaching and TrainingContact Person: Andrew Ee-Kuan LowEmail: Send EmailPhone: +61-413-885339Country: AustraliaWebsite: https://andrewlow.coach/

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The Clever Combination of Neuroscience and Ancient Wisdom That Is Re-Writing the Rule Book on Success and Happiness - Press Release - Digital Journal