The Neuroscience of Free Will: A Q & A with Robyn Repko Waller – Scientific American

Who are you and howdid you become interested in free will?

I am an Assistant Professor of Philosophy at Iona College where I also serve as a faculty member for the Iona Neuroscience program. I have previously worked in the Scientific and Philosophical Studies of Mind program at Franklin and Marshall College as well as previous appointments as a Lecturer at Kings College London and University of Alabama. My recent and forthcoming publications focus on issues of autonomy in terms of philosophical accounts of free will as well as how it intersects with neuroscience and psychiatry. One of the main questions I investigate is what neuroscience can tell us about meaningful agency (see here for my recent review of the topic as part of an extended review of research on agency, freedom, and responsibility for the John Templeton Foundation).

I became interested in free will via an interdisciplinary route. As an undergraduate at Grinnell College, I majored in psychology with a strong emphasis on experimental psychology and clinical psychology. During my senior year at Grinnell I realized that I was fascinated by the theoretical issues operating in the background of the psychological studies that we read and conducted, especially issues of how the mind is related to the brain, prospects for the scientific study of consciousness, and how humans as agents fit into a natural picture of the world. So I followed these interests to the study of philosophy of psychology and eventually found my way to the perfect fusion of these topics: the neuroscience of free will.

What is free will?

Free will seems to be a familiar feature of our everyday lives most of us believe that (at least at times) what we do is up to usto some extent. For instance, that I freely decided to take my job or that I am acting freely when I decide to go for a run this afternoon. Free will is not just that I move about in the world to achieve a goal, but that I exercise meaningful control over what I decide to do. My decisions and actions are up to mein the sense that they are mine a product of my values, desires, beliefs, and intentions. I decided to take this job because I valued the institutions mission or I believed that this job would be enriching or a good fit for me.

Correspondingly, it seems to me that at least at times I could have decided to and done something else than what I did. I decided to go for a run this afternoon, but no one made meand I wasnt subject to any compulsion; I could have gone for a coffee instead, at least it seems to me.

Philosophers take these starting points and work to construct plausible accounts of free will. Broadly speaking, there is a lot of disagreement as to the right view of free will, but most philosophers believe that a person has free will if they have the ability to act freely, and that this kind of control is linked to whether it would be appropriate to hold that person responsible (e.g., blame or praise them) for what they do. For instance, we dont typically hold people responsible for what they do if they were acting under severe threat or inner compulsion.

How do neuroscientists study free will?

There are plenty of sensational claims about the brain science of free will out there and lots of back and forth about whether or not science disproves free will (e.g., My brain made me do it). Given the strong link between free will and systems of moral and legal responsibility, like punishment, the stakes are high not just for our conception of human nature, but also for our everyday practices that matter.

The current neuroscience of free will traces its lineage back to an influential experiment by Benjamin Libet and his colleagues. The majority of our actions begin with bodily movements, and most of us think that when we decide to move (e.g., decide to pick up my cup of tea), first I, the agent or person, decides and then I hand off control, so to speak, to the brain circuits for motor control to execute the action.

It was known since the 1960s from work by Kornhuber and Deecke that there is slow buildup of negative brain activity in the supplementary motor area (SMA) and pre-SMA measurable by electoencephalography (EEG) just prior to voluntary (i.e., movement initiated by the participant) bodily movement. This brain activity, called the readiness potential (RP), was taken to be neural preparation to move for spontaneous movements and starts about a half second before time of the movement (here).

So Libet and his fellow researchers ask when does the agent appear in relation to the RP? The agents decision has to be something measurable in the lab, so Libet asked participants to make movements (of the finger or wrist) at a time of their choosing and then report after the fact when they were first aware of their decision or urge to move using a modified clock (termed W time).

Libet found, contra the commonsense expectation, that the average reported time of first awareness of decision to move, W-time, occurred almost a third of a second after the start of the RP. So Libet (and select others since) concluded that the RP is the brains unconscious decision to move with the agents decision occurring later (here).

Libet took this as evidence that the conscious agent or self doesnt initiate, or kick off, preparation to act, the unconscious brain does. He argued that this result is representative of how all of our voluntary movements are produced, and, if so, then the agents conscious decision to act doesnt initiate the process leading to movement. But if the agent doesnt play this initiating role in acting, how can it be up to mehow I act?

These results have worried a lot of folks and inspired a booming research enterprise in cognitive neuroscience and philosophy. One shouldnt jump to the depressing conclusion, though, that we dont act freely or dont really deserve any of the moral reactions others have to our actions; there is a healthy discussion on how the original Libet results can be interpreted as consistent with that picture of us humans as self-governing and free and moral persons.

W-time is taken to indicate moment of awareness of a decision. Can we capture "moments of conscious awareness"scientifically?

Since the initial publication of Libet and colleagues study, worries about whether we could measure time of conscious awareness have been voiced. After all, we are talking here about the timeframe of milliseconds. In these studies all of the events measured prior to movement in the lab are happening within one second before the participant wiggles a finger or hand (now button presses are the preferred movement). Libet argued that W-time within a reasonable range was reliable since we can see how accurately participants in the lab estimate the time of other events, such as skin shocks. The reliability of W-time has recently been challenged yet again with a new study that concludes that depending on the order in which participants complete certain tasks in the experiment, W-time can be strikingly different (i.e., there is an order effect; seehere).

Other researchers are currently exploring alternative ways to measure a decision to move in the lab, including work by Pars-Pujolrs and co-authors, who have been using an online(i.e., pre-movement) measure of the agents awareness of a decision to move (here).

In these studies participants watch a continuous stream of letters on a computer while spontaneously pressing a button. Every now and then, though, the letters change color. When this happens participants are told to press the button just then if they were already aware of their preparing to press the button soon. These kinds of onlinemeasures of awareness may yet prove to be more reliable ways of getting at whether people have conscious intentions to act in the lab.

Whats the latest work on neuroscience of free will?

Two of the hottest topics seem to be, first, what exactly the RP, that negative build-up of brain activity pre-movement, really signifies and, second, how we can make our voluntary actions in the lab more ecologically valid.As to the first, the past decade has seen researchers investigating if we have evidence that the RP really does stand for a decision to move or, alternatively, if the RP just is the brains being biased to move in some way (say, left, instead of right) without the commitment to do so.

Others test the possibility that the RP isnt really movement specific activity at all (e.g., general cognitive preparation to perform a task voluntarily). Others, such as Schurger and colleagues, have argued via empirical studies that the RP is the neural signature that we pick up when are actions are generated by neural noise crossing some threshold (here). That possibility would be alarming as then our actions, which we take to be undertaken by me for reasons, may really just be the passive result of fluctuating brain activity.

As to the second hot issue, researchers are now attempting to design tasks in the lab that are closer to the kind of decisions and action that we engage in daily. Libet argued that a simple movement like a wrist flex or button press could stand in for the more complex actions, as the RP has been shown to occur prior to more complex movements in the lab. Hence we could give a unified explanation of the timing of events involving practical decisions and bodily movements.

But many, myself included, have voiced concern that when to press a button or whether to press a left or right button, just isnt the right kind of action to stake a claim that we as agents dont initiate our actions via our conscious intentions to act. Hence, some of the ongoing work involves making the choice of which button to press or when to press it meaningful via rewards or penalties for skipping ahead or value-laden options, such as charity donations.*

And, of course, there are plenty of neuroimaging tools at the disposal of cognitive neuroscientists. Some of the most interesting replications and extensions of the Libet findings have been done using singe-cell recording and fMRI among other technologies (see here and here, respectively). In fact, the neuroscience of free will has been and currently isthe focus of some major research grants, such as the Big Questions in Free Will project (2010-2014, Principal Investigator Dr. Alfred Mele) and the Consciousness and Free Will project (2019-, a collaboration across 17 PIs), each of which involves philosophers and numerous neuroscientific labs worldwide. From these grants I think we should expect further clarity on whats going on under the hood, so to speak, when we decide what to do and act voluntarily.

Are there any other results in neuroscience that tell us something intriguing about our agential control?

Yes, one of the aspects of our lives that seems the most undeniable is that we really do experience ourselves as in control of our movements and their effects in the world. There is a large body of work in cognitive neuroscience which focuses on this sense of agency via research on whats been termed intentional binding (for a recent academic review see here).

Basically, if you ask participants in clever experimental set-ups to judge whether some event (e.g., icon moving on a computer screen) was the outcome of their agency or someone elses (i.e., I did that judgments), participants tend to misjudge an outcome to be a result of their own agency if it is a positive one and misjudge an outcome to be the result of anothers agency if it is a negative one. That is, there is a self-serving biasto explicit sense of agency judgments (For interesting results in this regard see Wegner and Wheatleys 1999 paper here and other earlier work in psychology on attribution theory).

Cognitive neuroscientists have found a methodology to study our sense that we are in control of our actions and actional outcomes without surveying participants explicit I did that judgments. Instead, experimenters ask participants to judge the time of various events, including their movements (e.g., a button press) and the sensory outcomes of those movements (e.g., a beep following the button press). What researchers have found is that if you voluntarily press a button and hear a tone as a consequence, you are going to judge that the time of the movement and the time of the tone are much closer together in perceived space than if you are caused to move (via neural stimulation) and hear a tone as a consequence.

In other words, the perceived time of the action and the tone bind together in perceptual space when you act voluntarily as opposed to when you are caused to move or simply judge the time of events without acting (here). Whats intriguing about this research on agency, then, is that our perceptual judgments about the world seem to distinguish when we act from when something is done to us. Research work on intentional binding has tackled more ecologically valid issues of sense of agency when acting under emotional distress, due to coercion, and in the face of options.*

* Neuroscientists working on more representative kinds of decisions and/or sense of agency in more ecologically valid contexts include researchers in the UCL Action and Body Lab at University College London and The Brain Institute at Chapman University, among others.

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The Neuroscience of Free Will: A Q & A with Robyn Repko Waller - Scientific American

Fox Cities Stadium will be closed until at least April 6 because of coronavirus – Post-Crescent

USA TODAY NETWORK-Wisconsin Published 3:08 p.m. CT March 16, 2020 | Updated 3:09 p.m. CT March 16, 2020

Neuroscience Group Field at Fox Cities Stadium will be closed until at least April 6, the Wisconsin Timber Rattlers announced Monday.(Photo: Chris Kohley/USA TODAY NETWORK-Wisconsin)

GRAND CHUTE - The Wisconsin Timber Rattlers announced Monday that they will close Neuroscience Group Field at Fox Cities Stadium due to the coronavirus outbreak.

The closing is effective immediately and will continue until at least April 6.The business office, the Snake Pit team storeand the Fox Club are affected by the closure.

Timber Rattlers president Rob Zerjav released the following letter in conjunction with the announcement:

"Dear Timber Rattlers Fans,

"With the recent closure of Spring Training camps and the delay to the start of the Major League Baseball season, the Minor League Baseball season, including the Wisconsin Timber Rattlers, will also not start as previously planned on April 9.At this time, there has been no determination as to when the season might begin.

"With the health and well-being of the players, coaches, umpires, team employees and our fans in mind, we will continue to monitor the developments and follow guidelines set forth by public health agencies and our partners at Major League Baseball.

"Once the public health experts and agencies have decided it is safe to begin the 2020 season, and the players are physically ready to begin the season, we will do so.For now, we ask all fans to follow the protocols set forth by public health officials, including the Centers for Disease Control and Prevention (CDC), the World Health Organization (WHO) and the Wisconsin Department of Health Services.

"As of today, the state of Wisconsin has placed a ban on all mass gatherings of 50 or more people.As such, all events scheduled in the Fox Club banquet facility at the stadium through May 11 will be postponed.This will include Fan Fest, the Welcome Home Banquet and Easter Brunch, which was scheduled for Sunday, April 12.In addition, the entire stadium and facility will be closed to the general public until at least April 6, 2020.Please visit timberrattlers.com or our social media channels to stay connected with the most up to date information.

"Your health and safety are the top priority right now and our thoughts are with those around the world who have been affected by this outbreak."

The Timber Rattlers were scheduled to open the season April 9 at 6:35 p.m. against the Burlington Bees at Fox Cities Stadium.

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Fox Cities Stadium will be closed until at least April 6 because of coronavirus - Post-Crescent

Davis Project for Peace Winners to Initiate Menstrual Help for Refugees in Uganda – Colby College

When premed students Sravya Bahudodda 21 and Faiza Qazi 21 think back to Jan Plan of their sophomore year, they immediately recall their Ugandan host sisters. During their short homestay in Kikuube, a village in western Uganda, the girls often stayed up listening to music, dancing, and chattingconversations that sometimes caught all of them off guard.

With our interest in healthcare, we started asking them questions like, How do you get to the hospital in such a remote area? What is access to those kinds of resources like here? said Bahudodda. And we saw the shock in one of the girls faces when she said, Im really worried that I wont be able to go to school once I get my period.

Spending more time in different communities, Bahudodda and Qazi realized that what their host sister voiced was a serious, widespread concern, impacting countless Ugandan girls and refugees.

SravyaBahudodda 21, left, andFaizaQazi 21 have been awarded a $10,000 Project for Peace award, which theyll use to help young girls in Nakivale Refugee Settlement in western Uganda better handle challenges relating to menstruation. (Photo by Naomi Williams)

Through their Jan Plan course Field Study in African Development, taught by Assistant Professor of Government Laura Seay, the Colby pair learned about the work of NGOs tackling this problem. There are people trying to help a lot of populations out, but that population did not include the refugees, said Qazi, a Posse Scholar from Houston, Texas, double majoring in psychology: neuroscience and government. To Bahudodda and Qazi that was concerning, especially because Uganda is one of the largest refugee-hosting nations in the world.

We learned a lot from the class, but we wanted to act on it, said Bahudodda, a biology: neuroscience and science, technology, and society double major from Farmington, Conn. The pair, with support from Seay, developed Sew in Peace: A Menstrual Health Initiative for Refugees in Uganda, one of the 125 Davis Projects for Peace winners for 2020.

With the $10,000 award, Bahudodda and Qazi will spend the summer at the Nakivale Refugee Settlement in western Uganda to implement their three-fold project.

First, they will introduce reusable sanitary pads to the community. Then, together with a local NGO called Raising Teenagers Uganda, they will set up a permanent space with sewing machines, where women will learn to make their own menstrual pads and anything else they need.

Thats where the sustainability part comes in, said Qazi. These machines are a way to not only just start up their own lives, but also start up a business of their own. In the long run, the two are hoping that women can start selling their handmade products, allowing them to regain control over their lives and have economic independence.

The final component will be education, teaching girls about menstrual health. I think a large part of our curriculum is going to be the stigmas, because thats a huge, huge barrier, said Bahudodda.

Said Qazi: Women are our focus because were women. If were not going to empower each other, I dont know how its supposed to happen.

-

Projects for Peace was the vision of philanthropist Kathryn W. Davis on the occasion of her 100th birthday in 2007. The initiative, open to all undergraduate students at the partner schools of the Davis UWC Scholars Program, challenges students to create summer projects that would tackle causes of conflict and contribute to creating lasting peace. Since its creation, the initiative has funded more than 700 projects in over 100 countries. To learn more about Projects for Peace, visit davisprojectsforpeace.org.

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Davis Project for Peace Winners to Initiate Menstrual Help for Refugees in Uganda - Colby College

Neuroscience Market Size and Shares, Industry Research Report | GE Healthcare, Siemens Healthineers, Noldus Information Technology – 3rd Watch News

Neuroscience Market Research Report provides in-depth information and professional study 2020-2025 of Neuroscience Market. This report is segmented into Manufactures, Types, Applications, and Regions. The keyword market report also shares details of upstream raw materials, downstream demand, and production value with some important factors that can lead to market growth.

The Global Neuroscience Market Report provides Insightful information to the clients enhancing their basic leadership capacity identified with the worldwide Neuroscience Market business. Utilizing figures, charts, and flowcharts in the report, the specialists represented the analyzed information in a superior acceptable manner. This report identifies that in this rapidly changing and competitive landscape with growth significant CAGR during Forecast, the latest marketing facts are essential to monitor performance and make crucial decisions for progress and profitability.

To Get PDF Broucher of Neuroscience Market 2020, Click Here @https://www.reportsmonitor.com/request_sample/889730

The Major Players Covered in this Report:GE Healthcare, Siemens Healthineers, Noldus Information Technology, Mightex Bioscience, Thomas RECORDING GmbH, Blackrock Microsystems, Tucker-Davis Technologies, Plexon, Phoenix Technology Group, NeuroNexus, Alpha Omega & More.

Segmentation by product type:Whole Brain ImagingNeuro-MicroscopyElectrophysiology TechnologiesNeuro-Cellular ManipulationStereotaxic SurgeriesAnimal BehaviorOthers

Segmentation by application:HospitalsDiagnostic LaboratoriesResearch InstitutesOthers

Regional Analysis For Neuroscience Market:

North America (United States, Canada, and Mexico)Europe (Germany, France, UK, Russia, and Italy)Asia-Pacific (China, Japan, Korea, India, and Southeast Asia)South America (Brazil, Argentina, Colombia, etc.)The Middle East and Africa (Saudi Arabia, UAE, Egypt, Nigeria, and South Africa)

In this Report, the Years Considered to Estimate the Market Size of the Neuroscience are as Follows:

History Year: 2015-2020 | Base Year: 2019 | Estimated Year: 2020 | Forecast Year 2020 to 2025

Market Segments:

The global Neuroscience market is segmented on the basis of the type of product, application, and region. The analysts authoring the report provide a meticulous evaluation of all of the segments included in the report. The segments are studied keeping in view their market share, revenue, market growth rate, and other vital factors. The segmentation study equips interested parties to identify high-growth portions of the global Neuroscience market and understand how the leading segments could grow during the forecast period.

Avail discount while purchasing this report, Click [emailprotected]https://www.reportsmonitor.com/check_discount/889730

The research report covers size, share, trends and growth analysis of the Neuroscience Market on the global and regional levels.

This report considers the below mentioned key questions:

Q.1. What are some of the most favorable, high-growth prospects for the global Neuroscience market?

Q.2. Which product segments will grow at a faster rate throughout the forecast period and why?

Q.3. Which geography will grow at a faster rate and why?

Q.4. What are the major factors impacting market prospects? What are the driving factors, restraints, and challenges in this Neuroscience market?

Q.5. What are the challenges and competitive threats to the market?

Q.6. What are the evolving trends in this Neuroscience market and the reasons behind their emergence?

Q.7. What are some of the changing customer demands in the Neuroscience Industry market?

Q.8. What are the new growth prospects in the Neuroscience market and which competitors are showing prominent results in these prospects?

Q.9. Who are the leading pioneers in this Neuroscience market? What tactical initiatives are being taken by major companies for growth?

Q.10. What are some of the competing products in this Neuroscience market and how big of a threat do they pose for loss of market share by product substitution?

Q.11. What M&A activity has taken place in the historical years in this Neuroscience market?

Click to view the full report details, Reports TOC, Figure and [emailprotected]https://www.reportsmonitor.com/report/889730/Neuroscience-Market

To conclude, the Neuroscience Industry report mentions the key geographies, market landscapes alongside the product price, revenue, volume, production, supply, demand, market growth rate, and forecast, etc. This report also provides SWOT analysis, investment feasibility analysis, and investment return analysis.

Contact UsJay MatthewsDirect: +1 513 549 5911 (U.S.)+44 203 318 2846 (U.K.)Email: [emailprotected]

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Neuroscience Market Size and Shares, Industry Research Report | GE Healthcare, Siemens Healthineers, Noldus Information Technology - 3rd Watch News

Intraoperative Neuromonitoring Market in the US 2020-2024 | Evolving Opportunities with Accurate Neuromonitoring LLC and Cadwell Industries Inc. |…

The intraoperative neuromonitoring market in US is poised to grow by USD 955.33 million during 2020-2024, progressing at a CAGR of over 10% during the forecast period. Request free sample pages

This press release features multimedia. View the full release here: https://www.businesswire.com/news/home/20200316005573/en/

Technavio has announced its latest US research report titled Intraoperative Neuromonitoring Market in US 2020-2024 (Graphic: Business Wire)

Read the 120-page report with TOC on "Intraoperative Neuromonitoring Market In US Analysis Report by Type (Insourced IONM and Outsourced IONM), Application (Orthopedic and neurosurgeries, Cardiovascular surgeries, ENT surgeries, and Other surgeries), Methodology (Evoked potential (EP) monitoring, Electroencephalogram (EEG), and Electromyography (EMG), End-user (Hospitals, Ambulatory surgical centers (ASG), and Other end-users), and the Segment Forecasts, 2020-2024".

https://www.technavio.com/report/intraoperative-neuromonitoring-market-in-us-industry-analysis

The market is driven by the increasing number of surgeries that require IONM. In addition, the rising adoption of remote IONM is anticipated to boost the growth of the intraoperative neuromonitoring market in the US.

The number of high-risk surgeries such as cardiovascular procedure, musculoskeletal, and spinal is increasing. Many people in the US, suffering from this condition experience severe long-term pain and disabilities. In addition, patients suffering from cervical or neck pain and lumbar or low back pain require medical attention. IONM are extensively used by surgeons because these medical conditions are often associated with neurological complications. For instance, surgeons use IONM while performing spine surgery because it allows the early identification of electrophysiologic changes. It is also used to identify hemodynamic and other abnormalities. Thus, the increasing number of surgeries that require IONM is expected to drive market growth during the forecast period.

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Major Five Intraoperative Neuromonitoring Companies in the US:

Accurate Neuromonitoring LLC

Accurate Neuromonitoring LLC operates the business under the Services segment. The company offers various services including motor strip mapping, cranial nerve monitoring, pedicle screw stimulations, and more. It also offers intraoperative neuromonitoring for performing neuro-surgical and other procedures.

Cadwell Industries Inc.

Cadwell Industries Inc. offers products through the following business units: EEG, EMG, IONM, Sleep, CADLINK, and Electrodes and accessories. The company offers Cascade IOMAX, Cascade PRO, Arc Alterna, and Arc Essentia.

Computational Diagnostics Inc.

Computational Diagnostics Inc. operates under various business segments, namely NeuroNet and Services. The company offers NeuroNet VII, NN600, and NN650. NN650 is a durable and easy to use IOM system, whereas, NN600 is a portable multi-modality capable system.

IntraNerve Neuroscience Holdings LC

IntraNerve Neuroscience Holdings LC offers products through the Services business segment. The company offers neuroscience services such as remote professional interpretation services, neurotelemetry/cEEG services, and intraoperative neuromonitoring services.

Story continues

Medtronic Plc

Medtronic Plc offers products through the following business segments: Cardiac and Vascular Group, Minimally Invasive Therapies Group, Restorative Therapies Group, and Diabetes Group. The company offers NIM-RESPONSE 3.0, BIS Complete 2-Channel Monitor, BIS Complete 4-Channel Monitor, and NIM-Neuro 3.0.

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Intraoperative Neuromonitoring Market in US: Type Outlook (Revenue, USD Billion, 2020-2024)

Intraoperative Neuromonitoring Market in US: Application Outlook (Revenue, USD Billion, 2020-2024)

Intraoperative Neuromonitoring Market in US: Methodology Outlook (Revenue, USD Billion, 2020-2024)

Intraoperative Neuromonitoring Market in US: End-user Outlook (Revenue, USD Billion, 2020-2024)

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Related Reports on Health Care Include:

Neurodiagnostic and Monitoring Devices Market Global Neurodiagnostic and Monitoring Devices Market by product (electroencephalograph (EEG) devices, intracranial pressure (ICP) devices, electromyography (EMG) devices, and others) and geography (Asia, Europe, North America, and ROW).

Diabetic Neuropathy Drugs Market Global Diabetic Neuropathy Drugs Market by action (calcium channel alpha-2-delta ligand, SNRIs and TCAs, and others) and geography (Asia, Europe, North America, and ROW).

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Intraoperative Neuromonitoring Market in the US 2020-2024 | Evolving Opportunities with Accurate Neuromonitoring LLC and Cadwell Industries Inc. |...

Global Neuroscience Market 2020 | Increasing Demand With Leading Key Players : Alpha Omega, Axion Biosystems, Blackrock Microsystems LLC, Femtonics…

The Global Neuroscience Market report gives future prospects and detailed prognosis of the Neuroscience market. The report features the major market events including latest trends, technological advancements, growth opportunities and market players such as (Alpha Omega, Axion Biosystems, Blackrock Microsystems LLC, Femtonics Ltd., Intan Technologies, LaVision Biotec GmbH, Mediso Medical Imaging Systems, Neuralynx Inc., NeuroNexus Technologies, Neurotar Ltd., Newport Corporation, Plexon Inc., Scientifica Ltd., Sutter Instrument Corporation, Thomas Recording GmbH, and Trifoil Imaging Inc.) in the global market that helps investors and industry experts to make crucial business decisions. Additionally, this report focuses on the interest of Neuroscience is developing and all the vital factors that contribute to overall market growth.

The Neuroscience market report provides successfully marked contemplated policy changes, favorable circumstances, industry news, developments, and trends. The association can prepare the entirety of this information to fortify their market existence it packs various parts of information gathered from secondary sources including press releases, web, magazines, and journals as numbers, tables, pie-charts, and graphs. The information is verified and validated through primary interviews and questionnaires. The data on growth and trends focuses on new technologies, market capacities, markets and materials, CAPEX cycle and the dynamic structure of the Neuroscience market.

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This study analyzes the growth of Neuroscience based on the present, past and futuristic data and will render entire information about the Neuroscience industry to the market-leading industry players that will guide the direction of the Neuroscience market through the forecast period. All of these players are analyzed in detail so as to get details concerning their recent announcements and partnerships, product/services, investment strategies and so on.

The Neuroscience market report highlights the region particularly in the United States, Europe, China, Japan, South-east Asia, India, Central & South America.

The Prominent Key Players in Neuroscience Market:Alpha Omega, Axion Biosystems, Blackrock Microsystems LLC, Femtonics Ltd., Intan Technologies, LaVision Biotec GmbH, Mediso Medical Imaging Systems, Neuralynx Inc., NeuroNexus Technologies, Neurotar Ltd., Newport Corporation, Plexon Inc., Scientifica Ltd., Sutter Instrument Corporation, Thomas Recording GmbH, and Trifoil Imaging Inc.

Key Highlights from Neuroscience Market Study:

Sales Forecast:The report contains historical revenue and volume that backing information about the market capacity and it helps to evaluate conjecture numbers for key areas in the Neuroscience market. Additionally, it includes a share of each and every segment of the Neuroscience market giving methodical information about types and applications of the market.

Industrial Analysis:The Neuroscience market report is extensively categorized into different product types and applications. The report has also featured a section highlighting the crucial information about the raw materials and manufacturing process used in the market.

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This report gives a forward-looking prospect of various factors driving or restraining market growth. It renders an in-depth analysis for changing competitive dynamics. It presents an in-depth analysis of changing competition dynamics and puts you ahead of competitors. It gives a six-year forecast evaluated on the basis of how the market is predicted to grow. It assists in making informed business decisions by making a pin-point analysis of market segments and by having complete insights of the Neuroscience market. This report assists in comprehending the key product segments and their future.

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In the end, the Neuroscience market is analyzed for revenue, sales, price, and gross margin. These points are examined for companies, types, applications, and regions.

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Brain Awareness Week 2020: Cognitive function and commercial video games – On Biology – BMC Blogs Network

This year, Brain Awareness Week falls between 16th and 22nd March. The campaign, organised by the Dana Foundation, aims to foster public enthusiasm and support for brain science while making research accessible for all.

Amy Joint 16 Mar 2020

Kerkez / Getty Images / iStock

In the spirit of the campaign, were taking an insight into a recent review by Min-Hyeon Park et al. published in Behavioral and Brain Functions, considering the different genres of commercial video games available, and how they are associated with cognitive function.

The study aimed to lean away from the negative picture of video games presented by research into compulsive engagements and addiction, and present a more balanced view. The commercial video games included in this study were split into five main genres, which in turn could be split down into sub-genres:

Across the different studies examined in this review, several improvements in cognitive function were identified. Frequent video game players were found to be better at sustaining attention, with Action Video Games in particular associated with improvement in selective attention. Changes in brain activation suggest that action game players are better at filtering information and efficiently allocating attention toimportant information.

Another improved cognitive function reported was visuo-spatial function. Playing Tetris was discovered to enhance spacial cognition, and ten hours of action game play resulted in improved navigational skills.

Adolescents who more regularly played specifically strategic video games across a four-year period during high school have shown improved problem solving skills in comparison to their peers.

The last cognitive function found to be positively associated with gameplay was second language development. In mass multiplayer online games, opportunities for interaction in the target language are frequent, and an efficient method for acquisition and use of new vocabulary.

krung99 / Getty Images / iStock

However, individual differences between players modulate the extent to which commercial video gaming can lead to cognitive enhancement. After peaking at the age of 13-14 years, time spent playing video games decreases over time, so the effect of gaming on cognitive function is likely to decrease with age. Age is also linked to cognitive function itself, with neuroplasticity the ability for the brain to form and reorganize connections in response to learning decreasing with time.

Gender is also reported as a modulating factor. While male and female-identifying players experience similar cognitive benefits in terms of attentional advantage, males have been found to play video games for longer stints, influencing overall effect on cognitive function.

On balance, this review provides a counterpart to gamings reputation within neuroscience as the worlds fastest growing addiction which shares neurobiological abnormalities with other addictive disorders.

Through relating to the 2.2 billion gamers across the planet and asking the right questions about how neuroscience permeates our day to day lives, this study encapsulates Brain Awareness Weeks purpose of sharing the impact brain science has on the wider world.

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Brain Awareness Week 2020: Cognitive function and commercial video games - On Biology - BMC Blogs Network

A neuroscientist’s take on synthetic telepathy, electrified ESP, and mind control – Boing Boing

Telepathy. ESP. The ability to communicate thoughts, feelings, or experiences without using our known sensory channels is a timeless superpower. Soon, advances in neuroscience, molecular biology, and computer science will make some kinds of synthetic telepathy possible. Meanwhile though, methods to treat brain disorders through magnetic stimulation of brain circuits could enable crude (or eventually not-so-crude) mind control. National Institutes of Health neuroscientist R. Douglas Fields -- author of Electric Brain: How the New Science of Brainwaves Reads Minds, Tells Us How We Learn, and Helps Us Change for the Better -- wrote a brief essay for Scientific American surveying the present, past, and possible future of this strange field. From Scientific American:

Neuroscientist Marcel Just and colleagues at Carnegie Mellon University are using fMRI brain imaging to decipher what a person is thinking. By using machine learning to analyze complex patterns of activity in a persons brain when they think of a specific number or object, read a sentence, experience a particular emotion or learn a new type of information, the researchers can read minds and know the persons specific thoughts and emotions. Nothing is more private than a thought, Just says, but that privacy is no longer sacrosanct....

...The prospect of mind control frightens many, and brain stimulation to modify behavior and treat mental illness has a sordid history. In the 1970s neuropsychologist Robert Heath at Tulane University inserted electrodes into a homosexual mans brain to cure him of his homosexual nature by stimulating his brains pleasure center. Spanish neuroscientist Jos Delgado used brain stimulation in monkeys, people and even a charging bull to understand how, at a neural circuit level, specific behaviors and functions are controlledand to control them at will by pushing buttons on his radio-controlled device energizing electrodes implanted in the brain. Controlling movements, altering thoughts, evoking memories, rage and passion were all at Delgados fingertips. Delgados goal was to relieve the world of deviant behavior through brain stimulation and produce a psychocivilized society.

Electric Brain: How the New Science of Brainwaves Reads Minds, Tells Us How We Learn, and Helps Us Change for the Better (Amazon)

image: illustration by Rob Beschizza/Boing Boing

In 1960 during the early days of the search for extraterrestrial intelligence, theoretical physicist Freeman Dyson, who died last month, wrote an article titled Search for Artificial Stellar Sources of Infrared Radiation for the journal Science. He posited that if extraterrestrial intelligent beings exist and have reached a high level of technical development, one by-product []

On the planet Wasp-76b, it rains iron. Researchers from the University of Geneva (UNIGE) and colleagues observed the planet, 650 light years from Earth, using the European Southern Observatorys Very Large Telescope in northern Chile. On the planets hot side that faces it star, temperatures can be above 2,400C. Its a good thing the residents []

The tiny skull, about the size of a thumbnail, trapped in amber may belong to the smallest dinosaur scientists have ever discovered. Paleontologist Lida Xing of the China University of Geosciences spotted the skull in a 99-million-year-old chunk of amber from northern Myanmar. From the New York Times: [Xing, Chinese Academy of Sciences paleontologist Jingmai []

There are few experiences that match the sheer raw power of being front and center for a huge rock concert. It can be exhilarating. But without sounding too much like your mom, it can also be far more dangerous than you realize. Hearing damage often happens from exposure to prolonged loud noises over 85 decibels []

As a parent, you likely start feeling a little guilty whenever you let your kid play video games for too long. Gaming is fun and most kids get completely enraptured, but you inevitably start thinking about all the more enriching and educational ways they could fill those hours spent rampaging through digital worlds and blasting []

When it comes to DIY electronics, there are few brand names that carry more weight these days than Arduino and the Raspberry Pi. Over the past 15 years, Arduino has grown from a tool to teach electronics to the uninitiated into an environment of startling innovation where creative minds fashion their own Arduino slow-drip coffee []

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A neuroscientist's take on synthetic telepathy, electrified ESP, and mind control - Boing Boing

The Truth About Bodybuilding Genetics | T Nation

How the Mutants Do It

World-record deadlifter Andy Bolton squatted 500 and deadlifted 600 the very first time he tried the lifts.

Former Mr. Olympia Dorian Yates bench-pressed 315 pounds on his first attempt as a teen.

Metroflex Gym owner Brian Dobson tells the story of his first encounter with then-powerlifter and future Mr. Olympia Ronnie Coleman. He describes Ronnie's enormous thighs with veins bulging through the spandex, despite the fact that Ronnie had never used an anabolic steroid at that time.

Arnold Schwarzenegger looked more muscular after one year of lifting than most people do after ten.

It's just plain obvious that some individuals respond much better to training than others. But what makes the elite respond so much better than us regular folks?

This probably isn't what you want to hear, but your progress is largely dependent on your genetics.

Recent research shows that some individuals respond very well to strength training, some barely respond, and some don't respond at all. You read that correctly. Some people don't show any noticeable results. Researchers created the term "non-responders" for these individuals.

A landmark study by Hubal used 585 male and female human subjects and showed that twelve weeks of progressive dynamic exercise resulted in a shockingly wide range of responses.

The worst responders lost 2% of their muscle cross-sectional area and didn't gain any strength whatsoever. The best responders increased muscle cross-sectional area by 59% and increased their 1RM strength by 250%. Keep in mind these individuals were subjected to the exact same training protocol.

The Hubal study isn't the only study showing these types of results. Petrella showed that 16 weeks of progressive dynamic exercise involving 66 human subjects failed to yield any measurable hypertrophy in 26% of subjects. Wow, sucks to be them!

Now, the question is, what mechanisms explain this? Let's dig into the current research.

Strong evidence suggests that the results you see in the gym are highly dependent on the efficacy of satellite cell-mediated myonuclear addition. In laymen's terms, your muscles won't grow unless the satellite cells surrounding your muscle fibers donate their nuclei to your muscles so they can produce more genetic material to signal the cells to grow.

Petralla showed that the difference between excellent responders in comparison to average and non-responders in strength training was mostly due to satellite cell activation. Excellent responders have more satellite cells that surround their muscle fibers, as well as a remarkable ability to expand their satellite cell pool via training.

In this study, excellent responders averaged 21 satellite cells per 100 fibers at baseline, which rose to 30 satellite cells per 100 fibers by week sixteen. This was accompanied by a 54% increase in mean fiber area. The non-responders averaged 10 satellite cells per 100 myofibers at baseline, which did not change post-training, nor did their hypertrophy.

A different article by Bamman using the same researchers involving the exact same experiment showed that out of 66 subjects, the top 17 responders experienced a 58% gain in cross-sectional area, the middle 32 responders gained 28% cross-sectional area, and the bottom 17 responders didn't gain in cross-sectional area. In addition:

Research by Timmons indicates that there are several highly expressed miRNAs that are selectivity regulated in subjects representing the lowest 20% of responders in a longitudinal resistance training intervention study.

Research by Dennis showed that individuals who have high expression of key hypertrophy genes have a distinct adaptive advantage over normal individuals. Individuals with lower baseline expression of key hypertrophy genes showed less adaptations to strength training, despite the fact that training did increase their gene expression in response to exercise.

Some folks hit the genetic jackpot, while others have gotten the genetic shaft. Genetically-speaking, anything that negatively impacts the ability of the myofibers to increase their number of myonuclei in response to mechanical loading will reduce hypertrophy and strength potential.

This ranges from the number of signaling molecules, to the cell's sensitivity to the signals, to satellite cell availability, to satellite cell pool expansion, to miRNA regulation. Nutrition and optimal programming play a role in hypertrophy of course, and certain genotypes may be associated with hypertrophy too.

Genes can affect fat storage and fat loss by influencing energy intake, energy expenditure, or nutrient partitioning. Researchers have coined the term "obesogenic environment" to describe the manner in which our changes in lifestyle over the past century has exposed our underlying genetic risk factors for excessive adiposity.

Natural selection may have favored those who possessed genes associated with thrifty metabolisms, which would have allowed for survival during times of nutrient scarcity. Now that much of the world has adopted a modern lifestyle characterized by sedentarism and excessive caloric intake, these same genes now contribute to poor health and obesity.

Bouchard took twelve pairs of twins and subjected them to 84 days over a 100-day period of overfeeding by 1,000 calories per day, for a total of 84,000 excess calories. Subjects maintained a sedentary lifestyle during this time. The average weight gain was 17.86 pounds, but the range went from 9.48 pounds to 29.32 pounds!

Even though each subject adhered to the same feeding schedule, the most metabolically cursed individual gained more than triple the weight than the most metabolically blessed individual, stored 100% of excess calories in his tissues (compared to only 40% tissue storage for the most-blessed individual), and increased abdominal visceral fat by 200% (compared to 0% in the case of the most-blessed individual).

Similar variances were shown by Bouchard with twins consuming constant energy intake while exercising frequently.

Perusse showed that heritability accounts for 42% of subcutaneous fat and 56% of abdominal visceral fat. This means that genetics greatly influence where you store fat, and some individuals have an alarming predisposition to store fat in their abdominal region.

Bouchard and Tremblay estimate that 40% of the variability in resting metabolic rate, thermic effect of food, and energy cost of low-to-moderate intensity exercise is genetically related. They also reported that levels of habitual physical activity are highly influenced by heredity.

Loos and Bouchard proposed that obesity has a genetic origin, and that sequence variations in adrenergic receptors, uncoupling proteins, the peroxisome proliferator-activated receptor, and lepton receptor genes were of particular relevance.

O'Rahilly and Farooqi add that the insulin VNTR and IGF-1 SNPs may be implicated in obesity as well, and Cotsapas showed 16 different loci that affect body mass index (BMI) which are all linked to extreme obesity as well. Rankinen mapped out hundreds of possible gene candidates that could promote obesity.

Fawcett and Barroso showed that the fat mass and obesity-associated gene (FTO) is the first universally accepted locus unequivocally associated with adiposity. FTO deficiency protects against obesity, and elevated levels increase adiposity most likely due to increased appetite and decreased energy expenditure.

Tercjak adds that FTO may affect insulin resistance too, and suggests that over 100 genes influence obesity. Herrerra and Lindgren list 23 genes that are associated with obesity, and suggest that heredity accounts for 40-70% of BMI!

Faith found evidence for genetic influences on caloric intake. Similar conclusions were drawn by Choquette, who examined 836 subjects' eating behaviors and found six genetic links to increased caloric and macronutrient consumption, including the adiponectin gene.

What's all that mean? It mans that some individuals are genetically predisposed to adiposity and abdominal fat storage.

But are some folks born to be great athletes while others are born to warm the bench? Let's find out.

While we still have much to learn about genetics as it relates to human performance, we do know that many different genes can affect performance.

Bray et al. (2009) mapped out the current knowledge of human genes that affect performance as of 2007 and concluded that 214 autosomal genes and loci as well as 18 mitochondrial genes appear to influence fitness and performance.

There are two alpha-actin proteins: ACTN2 and ACTN3. Alpha actins are structural proteins of the z-lines in muscle fibers, and while ACTN2 is expressed in all fiber types, ACTN3 is preferentially expressed in type IIb fiber types. These fibers are involved in force production at high velocities, which is why ACTN3 is associated with powerful force production.

Approximately 18% of individuals, or one billion people worldwide, are completely deficient in ACTN3 and their bodies create more ACTN2 to make up for the absence. These individuals just can't explode as quickly as their alpha-actin-3-containing counterparts, as elite sprinters are almost never alpha-actin-3 deficient (Yang).

The ACE gene, also known as the antiotensin converting enzyme, has also been implicated in human performance. An increase in the frequency of the ACE D allele is associated with power and sprint athletes, while an increased frequency of the ACE I allele is associated with endurance athletes (Nazarov).

Cauci showed that the variants of the VNTR IL-1RN gene is associated with improved athleticism. This gene affects the interleukin family of cytokines and enhances the inflammatory response and repair process following exercise. The work of Reichman lends support to this research, as they found that the interleukin-15 protein and receptor were associated with increased muscle hypertrophy.

Plenty of other genes exhibit potential to improve athletic performance, such as the myostatin gene, but conclusive evidence doesn't yet exist, or we just don't possess a clear enough understanding of the entire puzzle.

Although the research in this article is pretty scary, I have something to say about it.

First, we all have issues with genetics that we have to work around. Some of us are predisposed to carrying excess fat, some of us are lean but have stubborn areas of fat deposition, some have trouble building muscle, and some are muscular but have weak body parts. Some of us have all of this combined, and nobody has perfect genetics!

My list of genetic curses is a mile long, but despite this I've managed to develop a pretty respectable physique and somewhat impressive strength levels.

Second, the protocols used in the research didn't involve any experimentation, tweaking, and auto-regulatory training. We all need to tweak the variables and figure out our optimal programming methodology.

Some people respond best to variety, some to volume, some to intensity, some to frequency, and some to density. You have to discover the best stimulis for your body, which evolves over time.

And third, I've spoken to my colleagues about this issue and we're all in agreement: we've never trained any individuals who didn't look better after a couple of months of training, assuming they stick with the program. All of them lose fat and gain some muscular shape.

While some individuals have a much easier time than others developing an impressive physique, I've yet to see a lifter who trained in an intelligent manner fail to see any results.

So even if you're a "hard gainer" and you don't respond well, you can and will see results as long as you're consistent and as long as you continue to experiment. Of course, the rate and amount of adaptation is highly influenced by genetics, but sound training methods will always account for a large portion of training effects.

The lesson: Genetics make a difference, but smart training, diet, and supplements can help you maximize what your parents gave you!

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The Truth About Bodybuilding Genetics | T Nation

Graduate Program in Genetics, Genomics & Bioinformatics …

13 Mar

Biochemist spins out joint venture company with Atomwise

Over the past few years, biochemist John Jefferson Perry at the University of California, Riverside, has collaborated on a number of projects with Atomwise Inc., a company that uses artificial intelligence, or AI, for drug discovery. Now Perry and the company have formed a joint venture called Theia Biosciences.

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Graduate Program in Genetics, Genomics & Bioinformatics ...