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Neuroscience

Bat study reveals secrets of the social brain – EurekAlert

image:A new study by neuroscientists at the University of California, Berkeley, used wireless neural recordings of Egyptian fruit bats to provide a glimpse into how the brains of social animals process complex group interactions. view more

Credit: Photo courtesy Michael Yartsev

Berkeley Whether chatting with friends at a dinner party or managing a high-stakes meeting at work, communicating with others in a group requires a complex set of mental tasks. Our brains must track who is speaking and what is being said, as well as what our relationship to that person may be because, after all, we probably give the opinion of our best friend more weight than that of a complete stranger.

A study published today in the journal Science provides the first glimpse into how the brains of social mammals process these types of complex group interactions.

In the study, neuroscientists at the University of California, Berkeley, used wireless neural recording devices to track the brain activity of Egyptian fruit bats as they freely interacted in groups and occasionally vocalized to each other through high-pitched screeches and grunts.

Most studies of communication, particularly vocalization, are typically performed with single animals or with pairs of animals, but basically none have been conducted in actual group settings, said study co-first author Maimon Rose, a graduate student in the NeuroBat Lab at UC Berkeley. However, many social mammals, including humans, typically interact in groups. Egyptian fruit bats, specifically, like to interact within large colonies.

By tracking which of the bats vocalized, while simultaneously measuring the real-time neural activity in both the vocalizing and the listening bats, the researchers were able to decode how neurons in the bats frontal cortices distinguished among vocalizations made by themselves and by others, as well how the bats distinguished among different individuals in the group.

When they compared the neural recordings among the different bats, they also found that brain activity became highly correlated when a bat made a vocalization. Surprisingly, they found that communication produced by bats that were friendlier those that spent more time in close proximity to others induced a higher degree of correlations across the brains of the group members.

Other neuroscience studies have tried to examine small pieces of these interactions individually. For example, one study might examine how neurons respond when somebody else speaks, and then a separate study might look at how neurons respond when that individual speaks, said study senior author Michael Yartsev, an assistant professor of neurobiology and bioengineering at UC Berkeley. This study is the first to really put all of these pieces together to get a full picture of communication within a social group.

Thousands of squabbling roommates

Like humans, Egyptian fruit bats are highly social creatures. After long nights spent flying 10 miles or more in search of ripe fruit, these nocturnal animals pass the daylight hours packed into tight caves and crevices alongside hundreds or thousands of other bats. Not surprisingly, studies suggest that these bats typically vocalize to squabble over food, sleeping space and mating attempts.

These bats are very long-lived they live about 25 years and basically their entire lives are spent in this group social living, Yartsev said. So, the ability to live together in a group and communicate with each other is an inherent feature of their lives.

Even in laboratory settings, bats seem to prefer the comfort of a crowd, typically spending most of their time physically pressed against each other in a tight cluster. Notably, aside from making clicking noises for echolocation, Egyptian fruit bats do not engage in any long-distance form of communication and appear to vocalize to other bats only when clustered together.

If you visit these bat caves, you can just look up and see tens of thousands of animals, Yartsev said. So, it really wouldnt make sense for a bat to shout across to the cave to another bat.

Bats habit of only vocalizing within tight social clumps makes them ideal subjects for studying group communication because, if a bat does call out while in a cluster, that call is most likely an indicator that social communication is taking place. However, this behavior also posed one of many technical challenges for the research team, said study co-first author Boaz Styr, a postdoctoral researcher in the NeuroBat Lab.

One big problem was trying to identify which bat made a vocalization, because they spend their time in tight clusters and sometimes obscure each other, Styr said. Even though we had high resolution cameras recording at different angles, and lots of microphones around, it could be hard to pinpoint which bat was making a call at exactly which point.

During the experiments, four to eight bats were allowed to freely interact in a darkened enclosure in the lab, and allowed to spontaneously vocalize. To accurately identify which bat made each vocalization, the team developed wireless vibration sensors that the bats could wear around their necks, almost like necklaces, and which could detect the vibrations created when a bat made a call.

These vibration sensors, paired with our ability to wirelessly record neural data from multiple bats at the same time, allowed us to create this experiment in which the bats could freely behave and spontaneously communicate, Styr said. Getting all of these technical things to work together was extremely challenging, but it allowed us to ask these very important questions.

Neurons for self and others

In one set of experiments, the researchers allowed groups of four or five bats to freely interact within a darkened enclosure in the lab, while carefully monitoring each bats vocalizations and brain activity.

They found that, within each bats frontal cortex an area known to be involved in mediating social behaviors in animals and humans separate sets of neurons were activated, depending on which bat in the group vocalized; in other words, a vocalization from one bat would stimulate activity in one set of neurons, while a vocalization from a different bat would stimulate a different set of neurons. These correlations were so strong that, after identifying which sets of neurons corresponded to which bat, the researchers could identify which bat had vocalized purely by looking at the neural activity of the other bats.

What these individual neurons cared about was, Am I making the call? Or is somebody else making the call? no matter what type of vocalization it was, Styr said. Other neurons were only sensitive to when one specific bat within the group was talking.

Earlier work from the NeuroBat Lab has demonstrated that the brains of bat pairs tend to sync up when they socialize. In this study, the authors discovered that during vocal communication, the whole group syncs up together. This effect was not observed when the bats simply heard playback of the same sounds, suggesting that this phenomenon was specific to active communication taking place among the group members.

Intriguingly, the degree of correlation among the group members brains appeared to depend on which bat was talking, with some bats having stronger synchronization with specific individuals. Remarkably, these inter-brain patterns lasted for weeks, presumably representing stable social relationships among the individuals.

To better understand how social dynamics impact brain activity, the researchers conducted a separate set of experiments in which eight bats were allowed to freely interact in a larger enclosure. In addition to monitoring the vocalizations and neural activity of each bat, they also tracked each bats spatial position relative to the other bats in the group.

Bats can recognize and have stable social relationships with other individual bats, even over long periods of time and in different circumstances, Rose said. And because we had this group of bats, we decided to track their positions in a larger area to see if that would tell us anything about their social relationships who likes whom, and who are more sociable bats and the less sociable bats.

They found that, while most in-cluster bats spent nearly all their time clumped together with other bats, a couple of out-of-cluster bats spent more time off to the side, separate from the group. Surprisingly, the team also found that the in-cluster or out-of-cluster status of a bat impacted the neural activity of the other bats during vocalizations.

We found that when the in-cluster bats vocalized, they elicited a much more accurate neural representation of their identity in the other bats and also elicited a much higher level of brain synchrony within the group, Rose said. So, while its not entirely clear what exactly is going on, it seems that the behavior of the out-of-cluster bats really shifts their neural representation in the brains of the other bats.

Understanding the neural underpinnings of why some individuals can navigate almost any social situation with ease, while others are consistently ostracized or misunderstood, could have major implications for improving human mental health, Yartsev said. He hopes the study inspires neuroscientists to take a more comprehensive look at group communication within other social mammals.

Often, in neuroscience, we like to take a simplified approach and focus on one component of a complex process at a time, Yartsev said. But in reality, the social world is complex. When we spend time with our friends, there's a lot of relationship history and baggage that comes with each interaction: what happened yesterday, who that person is friends with, how each person feels in the moment. And so, breaking things down and looking at them individually can give an illusion of control but, in fact, make it very difficult to get the complete picture.

Our brains, and those of animals, have evolved for and constantly struggle with the complexity of real life, Yartsev added. I personally believe that to truly understand the brain, we need to embrace this complexity, rather than fear it, and, indeed, every time we did so, we found out something new and exciting. I hope that this, as well as our other studies, demonstrate that we need to study the brain in all its complexity.

Co-authors of the paper include Tobias A. Schmid and Julie E. Elie of UC Berkeley. This research was supported by the National Institutes of Health (Award DP2-DC016163), the National Institute of Mental Health (Award 1-R01MH25387-01), the New York Stem Cell Foundation (Award NYSCF-R-NI40), the Alfred P. Sloan Foundation (Award FG-2017-9646), the Brain Research Foundation (Award BRFSG-2017-09), the Packard Fellowship (Award 2017-66825), the Klingenstein Simons Fellowship, the Human Frontiers Science Program, the Pew Charitable Trust (Award 00029645), the McKnight Foundation, the Dana Foundation and the Human Frontiers Science Program postdoctoral fellowship.

Experimental study

Animals

Cortical representation of group social communication in bats

21-Oct-2021

Excerpt from:
Bat study reveals secrets of the social brain - EurekAlert

Neuroscience

Cerevel Therapeutics to Report Third Quarter 2021 Financial Results on Wednesday, November 10, 2021 – Yahoo Finance

CAMBRIDGE, Mass., Oct. 20, 2021 (GLOBE NEWSWIRE) -- Cerevel Therapeutics (Nasdaq: CERE), a company dedicated to unraveling the mysteries of the brain to treat neuroscience diseases, today announced it will report third quarter 2021 financial results and pipeline updates on Wednesday, November 10, 2021, before the U.S. financial markets open.

Management will host a conference call to discuss third quarter 2021 financial results and recent pipeline updates on Wednesday, November 10, 2021 at 8:00 a.m. ET. To access the call, please dial 833-665-0655 (domestic) or 702-495-1044 (international) and refer to conference ID 9784674.

A live webcast of the call, along with supporting slides, will be available on the investors section of Cerevels website here. Following the live webcast, an archived version of the call will be available on the website.

About Cerevel TherapeuticsCerevel Therapeutics is dedicated to unraveling the mysteries of the brain to treat neuroscience diseases. The company is tackling diseases with a targeted approach to neuroscience that combines expertise in neurocircuitry with a focus on receptor selectivity. Cerevel Therapeutics has a diversified pipeline comprising five clinical-stage investigational therapies and several pre-clinical compounds with the potential to treat a range of neuroscience diseases, including Parkinsons, epilepsy, schizophrenia, and substance use disorder. Headquartered in Cambridge, Mass., Cerevel Therapeutics is advancing its current research and development programs while exploring new modalities through internal research efforts, external collaborations, or potential acquisitions. For more information, visit http://www.cerevel.com.

Special Note Regarding Forward-Looking StatementsThis press release contains forward-looking statements that are based on managements beliefs and assumptions and on information currently available to management. In some cases, you can identify forward-looking statements by the following words: may, will, could, would, should, expect, intend, plan, anticipate, believe, estimate, predict, project, potential, continue, ongoing or the negative of these terms or other comparable terminology, although not all forward-looking statements contain these words. These statements involve risks, uncertainties and other factors that may cause actual results, levels of activity, performance, or achievements to be materially different from the information expressed or implied by these forward-looking statements. Although we believe that we have a reasonable basis for each forward-looking statement contained in this press release, we caution you that these statements are based on a combination of facts and factors currently known by us and our projections of the future, about which we cannot be certain. Forward-looking statements in this press release include, but are not limited to, statements about our upcoming financial results and pipeline update announcement and the potential attributes and benefits of our product candidates. We cannot assure you that the forward-looking statements in this press release will prove to be accurate. Furthermore, if the forward-looking statements prove to be inaccurate, the inaccuracy may be material. Actual performance and results may differ materially from those projected or suggested in the forward-looking statements due to various risks and uncertainties, including, among others: clinical trial results may not be favorable; uncertainties inherent in the product development process (including with respect to the timing of results and whether such results will be predictive of future results); the impact of COVID-19 on the timing, progress and results of ongoing or planned clinical trials; other impacts of COVID-19, including operational disruptions or delays or to our ability to raise additional capital; whether and when, if at all, our product candidates will receive approval from the FDA or other regulatory authorities, and for which, if any, indications; competition from other biotechnology companies; uncertainties regarding intellectual property protection; and other risks identified in our SEC filings, including those under the heading Risk Factors in our Quarterly Report on Form 10-Q filed with the SEC on August 11, 2021 and our subsequent SEC filings. In light of the significant uncertainties in these forward-looking statements, you should not regard these statements as a representation or warranty by us or any other person that we will achieve our objectives and plans in any specified time frame, or at all. The forward-looking statements in this press release represent our views as of the date of this press release. We anticipate that subsequent events and developments will cause our views to change. However, while we may elect to update these forward-looking statements at some point in the future, we have no current intention of doing so except to the extent required by applicable law. You should, therefore, not rely on these forward-looking statements as representing our views as of any date subsequent to the date of this press release.

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Media Contact:Kate ContrerasReal Chemistrykcontreras@realchemistry.com

Investor Contact:Matthew CalistriCerevel Therapeuticsmatthew.calistri@cerevel.com

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Cerevel Therapeutics to Report Third Quarter 2021 Financial Results on Wednesday, November 10, 2021 - Yahoo Finance

Neuroscience

Study of Mice Watching Movies Reveals Brain Circuit That Ensures Vision Remains Reliable – SciTechDaily

By David Orenstein, MIT Picower Institute for Learning and MemoryOctober 21, 2021

A new study finds that our brain cells rely on a circuit of inhibitory neurons to help ensure that the same images are represented consistently.

A study of mice watching movies shows our brain cells rely on a circuit of inhibitory neurons to help ensure that the same images are represented consistently.

When it comes to processing vision, the brain is full of noise. Information moves from the eyes through many connections in the brain. Ideally, the same image would be reliably represented the same way each time, but instead different groups of cells in the visual cortex can become stimulated by the same scenes. So how does the brain ultimately ensure fidelity in processing what we see? A team of neuroscientists in the Picower Institute for Learning and Memory at MIT found out by watching the brains of mice while they watched movies.

What the researchers discovered is that while groups of excitatory neurons respond when images appear, thereby representing them in the visual cortex, activity among two types of inhibitory neurons combines in a neatly arranged circuit behind the scenes to enforce the needed reliability. The researchers were not only able to see and analyze the patterns of these neurons working, but once they learned how the circuit operated they also took control of the inhibitory cells to directly manipulate how consistently excitatory cells represented images.

The question of reliability is hugely important for information processing and particularly for representation in making vision valid and reliable, says Mriganka Sur, the Newton Professor of Neuroscience in MITs Department of Brain and Cognitive Sciences and senior author of the new study in the Journal of Neuroscience. The same neurons should be firing in the same way when I look at something, so that the next time and every time I look at it, its represented consistently.

Research scientist Murat Yildirim and former graduate student Rajeev Rikhye led the study, which required a number of technical feats. To watch hundreds of excitatory neurons and two different inhibitory neurons at work, for instance, they needed to engineer them to flash in distinct colors under different colors of laser light in their two-photon microscope. Taking control of the cells using a technology called optogenetics required adding even more genetic manipulations and laser colors. Moreover, to make sense of the cellular activity they were observing, the researchers created a computer model of the tripartite circuit.

It was exciting to be able to combine all these experimental elements, including multiple different laser colors, to be able to answer this question, Yildirim says.

The teams main observation was that as mice watched the same movies repeatedly, the reliability of representation among excitatory cells varied along with the activity levels of two different inhibitory neurons. When reliability was low, activity among parvalbumin-expressing (PV) inhibitory neurons was high and activity among somatostatin-expressing (SST) neurons was low. When reliability was high, PV activity was low and SST activity was high. They also saw that SST activity followed PV activity in time after excitatory activity had become unreliable.

PV neurons inhibit excitatory activity to control their gain, Sur says. If they didnt, excitatory neurons would become saturated amid a flood of incoming images and fail to keep up. But this gain suppression apparently comes at the cost of making representation of the same scenes by the same cells less reliable, the study suggests. SST neurons meanwhile, can inhibit the activity of PV neurons. In the teams computer model, they represented the tripartite circuit and were able to see that SST neuron inhibition of PV neurons kicks in when excitatory activity has become unreliable.

This was highly innovative research for Rajeevs doctoral thesis, Sur says.

The team was able to directly show this dynamic by taking control of PV and SST cells with optogenetics. For instance, when they increased SST activity they could make unreliable neuron activity more reliable. And when they increased PV activity, they could ruin reliability if it was present.

Importantly, though, they also saw that SST neurons cannot enforce reliability without PV cells being in the mix. They hypothesize that this cooperation is required because of differences in how SST and PV cells inhibit excitatory cells. SST cells only inhibit excitatory cell activity via connections, or synapses, on the spiny tendrils called dendrites that extend far out from the cell body, or soma. PV cells inhibit activity at the excitatory cell body itself. The key to improving reliability is enabling more activity at the cell body. To do that, SST neurons must therefore inhibit the inhibition provided by PV cells. Meanwhile, suppressing activity in the dendrites might reduce noise coming into the excitatory cell from synapses with other neurons.

We demonstrate that the responsibility of modulating response reliability does not lie exclusively with one neuronal subtype, the authors wrote in the study. Instead, it is the co-operative dynamics between SST and PV [neurons] which is important for controlling the temporal fidelity of sensory processing. A potential biophysical function of the SSTPV circuit may be to maximize the signal-to-noise ratio of excitatory neurons by minimizing noise in the synaptic inputs and maximizing spiking at the soma.

Sur notes that the activity of SST neurons is not just modulated by automatic feedback from within this circuit. They might also be controlled by top-down inputs from other brain regions. For instance, if we realize a particular image or scene is important, we can volitionally concentrate on it. That may be implemented by signaling SST neurons to enforce greater reliability in excitatory cell activity.

Reference: Reliable Sensory Processing in Mouse Visual Cortex through Cooperative Interactions between Somatostatin and Parvalbumin Interneurons by Rajeev V. Rikhye, Murat Yildirim, Ming Hu, Vincent Breton-Provencher and Mriganka Sur, 20 October 2021, JNeurosci.DOI: 10.1523/JNEUROSCI.3176-20.2021

In addition to Sur, Yildirim, and Rikhye, the papers other authors are Ming Hu and Vincent Breton-Provencher.

The National Eye Institute, The National Institute of Biomedical Imaging and Bioengineering of the National Institutes of Health, and the JPB Foundation funded the study.

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Study of Mice Watching Movies Reveals Brain Circuit That Ensures Vision Remains Reliable - SciTechDaily

Neuroscience

Charles Lafitte Foundation’s $5 Million Gift Furthers a Shared Goal of Solving Challenges through Innovation – Duke Today

A new $5 million gift from the Charles Lafitte Foundation will bolster Duke Science and Technology, the universitys signature effort to elevate excellence in the sciences, and support students aspirations in pursuing the study of artificial intelligence, fintech, cybersecurity, neuroscience and more.

This is the second major gift to Duke from the family foundation of Duke parents and philanthropists Jeffrey and Suzanne Citron of Hobe Sound, Fla., who donated another $5 million to Duke in 2018.

The largest portion of the gift will endow a new professorship for the Pratt School of Engineering. The Charles Lafitte Foundation Professor of the Practice/Executive in Residence will make it possible for the school to recruit experienced leaders in fields such as fintech, cybersecurity, artificial intelligence and cryptographic computing to teach engineering students and prepare them for careers in industry-related computing fields.

FinTech and other fields built on cutting edge technology evolve at a rate faster than traditional academic practices can support,said Jeffrey Citron, founder of the foundation and high-speed Internet and broadband device company Vonage. Providing students direct access to industry leaders will not only serve to educate them in the academic sense but will enable them to be an active part of developing future innovations. Innovative solutions and change are essential elements of the Charles Lafitte Foundation and partnering with Duke to endow this professorship will ensure the foundation can continue achieving our mission in perpetuity.

The gift also enables the Pratt School to hire an expert to serve as a liaison with the universitys Office of Research and Innovation. The goal is to accelerate new discoveries and create new companies, therapies and products in part by building fruitful collaborations with corporate partners.

Further, the gift will help create a big-tech internship training program, will expand offerings of advanced courses that align with the needs of big-tech firms and will give students the practical knowledge to apply their skills to industry-focused challenges.

We know one of the great strengths of a Duke education is putting students in direct contact with experts who can help them take their next steps, said Jeff Glass, interim dean of engineering. By enabling us to recruit thought leaders and connect students with industry partners in cutting-edge tech fields, the Citrons gift will help shape the next great innovators and entrepreneurs at Duke.

As part of the gift, the Citrons also renewed $2.3 million of wide-ranging funding from their foundations 2018 gift. This includes $750,000 added to its endowed incubation fund to support turning ideas into solutions to societys challenges. Another $750,000 adds to the Charles Lafitte Foundation Program in Psychological Research, which gives seed grants for research by faculty, postdocs, graduate students and undergraduates through the Psychology & Neuroscience department.

In addition to Duke University, the Charles Lafitte Foundation supports organizations working in the fields of education, childrens advocacy, medical research and issues, and the arts and underwrites programs it feels can become self-sustaining with long-term commitment and measurable impact.

Support from the Charles Lafitte Foundation has provided new opportunities for action, said Scott Huettel, chair of Psychology & Neuroscience. Our students and faculty have sparked new projects on topics from how COVID changes attitudes toward risks to how identity shapes individual social behavior. They have risen to the challenge of the times by doing research that matters not only for the advancement of science, but also for the advancement of our society. We are extraordinarily grateful that the Foundation believes in the value of that research.

Additional Duke support renewed by the foundation included operating gifts to the Annual Funds of the Pratt School of Engineering, Trinity College of Arts & Sciences, Jewish Life at Duke and Duke Gardens.

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Charles Lafitte Foundation's $5 Million Gift Furthers a Shared Goal of Solving Challenges through Innovation - Duke Today

Neuroscience

What Can Mapping the Whole Brain Tell Us About Ourselves? – Walter Bradley Center for Natural and Artificial Intelligence

The worm and fly brains have been mapped. The mouse brain has, in part, been mapped. But the human brain offers the real challenge for the researchers working around the clock. Our brains are not just more complex; they are more complex on a number of dimensions:

To truly understand how the brain works, neuroscientists also need to know how each of the roughly 1,000 types of cell thought to exist in the brain speak to each other in their different electrical dialects. With that kind of complete, finely contoured map, they could really begin to explain the networks that drive how we think and behave.

We hear about these new types of cells as they are identified (there is even a census in the works) . The hope is that a complete map will enable new therapies for cognitive disorders like Alzheimer. But the brain mapping projects, begun nearly a decade ago, are still in the early stages:

The consortium [BRAIN Initiative Cell Census Network (BICCN)] has mapped the cell types in around 1% of the mouse brain, and has some preliminary data on primate brains, including humans. It plans to complete the whole mouse brain by 2023. The maps already hint at some small differences between species that could help to explain our susceptibility to some human-specific conditions such as Alzheimers disease.

Its a big job:

In 2006, the Allen Institute created a gene-expression atlas showing where in the mouse brain each of its roughly 21,000 genes are expressed. It took 3 years for around 50 staff to build the Allen Brain Atlas one gene at a time and its value was instantly recognized by the neuroscience community. It is updated regularly and continues to be widely used as a reference, helping scientists to locate where their gene of interest is expressed or to study the role of a particular gene in a disease.

Still, the community wanted more. We wanted to be able to see every gene that is expressed in every cell at the same time, says Hongkui Zeng, director of the Allen Institute for Brain Science. The different patterns of gene expression in individual cells would allow researchers to define which type of cell they were an ambitious task because the mouse brain contains more than 100 million cells, two-thirds of which are neurons. (The human brain is three orders of magnitude larger, with more than 170 billion cells, of which half are neurons.)

Human brains differ from mouse brains in more than just size. We have more different cell types and a different balances in types of neurons. Neuroscientist Ed Lein of the Allen Institute offers, These cumulative differences could lead to profound changes in how the human cortex is organized and functions.

So then, what makes the human brain special?

What makes the human brain special will come down to differences in the cellular diversity, the proportions of the cell types, the wiring of the brain and probably much more, says neuroscientist John Ngai at the University of California, Berkeley, who heads the US BRAIN Initiative. Theres no simple answer to this age-old question.

No simple answer indeed! The brain is full of surprises. Much that happens is not what we might expect. Here are some of the situations brain mappers must confront to provide the rest of us with insight:

A computer model of the brain wont really work. Our brains are not like computers although they do have some resemblance to billions of them working together. Even the axons in our nerve cells are smart PCs. As a result, we are told, far-flung regions (thousands of cell body widths from their nucleus) can even make independent decisions.

A complete DNA map of the brain wont be a Big Answer either. Our brains break DNA in order to learn more quickly: to express learning and memory genes more quickly, brain cells snap their DNA into pieces at many key points, and then rebuild their fractured genome later Quanta

The brain is both eclectic and orderly at the same time. For example, gray matter isnt the simple big big explanation many of us have assumed: Connectionthe connectomeis the astonishing feature of the brain. Mapping the connectome all the connections in the brainresearchers expected a huge, random tangle. They found a street map.

In the brain, things may not be in one place or in a place we expect. Most parts of the brain are involved in processing signals. Mouse studies found brain waves that can bypass synapses and gaps and even communicate with severed nerves. Our conscious visual perception lies outside our visual field. And memories can drift from neuron to neuron.

Damaged or deficient brains can work well in ways that are just baffling at present. People with brains that have been split in half to control epilepsy function normally. Some people think and speak with only half a brain or even less.

The proposed whole brain map will probably shed light on many of these situations. Those it doesnt shed light on are probably a new frontier.

You may also wish to read:

Study: The human brain and the universe are remarkably similar. It looks as though the universe is not random but rather patterned in the way it unfolds. When an astrophysicist and a neurosurgeon compared notes, they were surprised by the way the brain follows the same pattern as the universe.

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What Can Mapping the Whole Brain Tell Us About Ourselves? - Walter Bradley Center for Natural and Artificial Intelligence

Neuroscience

Global Neuroscience Market Analysis 2021 to 2027 Top Key Players are GE Healthcare, Siemens Healthineers, Noldus Information Technology EcoChunk -…

The complete study Global Neuroscience Market from 2021 to 2027, the MarketsandResearch.biz gives an in-depth examination of the present situation and key elements in the given industry. It provides accurate information and conducts in-depth research to assist in the creation of the best business plan and the identification of the best path for market participants to achieve maximum growth.

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Key Features of Global Neuroscience market report are, growth rate, regional bifurcation, new product, major manufacturers, market problemsandRevenue forecasts.Further, based on primary research and extensive secondary research, the report was produced based on recent trends, pricing analysis, potential and historic demand and supply, economic conditions, COVID-19 influence, and other aspects.

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Global Neuroscience Market Analysis 2021 to 2027 Top Key Players are GE Healthcare, Siemens Healthineers, Noldus Information Technology EcoChunk -...

Biochemistry

What is biochemistry? | Biochemistry

Biochemistry is the branch of science that explores the chemical processes within and related to living organisms. It is a laboratory based science that brings together biology and chemistry. By using chemical knowledge and techniques, biochemists can understand and solve biological problems.

Biochemistry focuses on processes happening at a molecular level. It focuses on whats happening inside our cells, studying components like proteins, lipids and organelles. It also looks at how cells communicate with each other, for example during growth or fighting illness. Biochemists need to understand how the structure of a molecule relates to its function, allowing them to predict how molecules will interact.

Biochemistry covers a range of scientific disciplines, including genetics, microbiology, forensics, plant science and medicine. Because of its breadth, biochemistry is very important and advances in this field of science over the past 100 years have been staggering. Its a very exciting time to be part of this fascinating area of study.

To find out more about careers in biochemistry read our bookletsBiochemistry: the careers guideandNext Steps.

The life science community is a fast-paced, interactive network with global career opportunities at all levels. The Government recognizes the potential that developments in biochemistry and the life sciences have for contributing to national prosperity and for improving the quality of life of the population. Funding for research in these areas has been increasing dramatically in most countries, and the biotechnology industry is expanding rapidly.

The Biochemical Societyaims to inspire and engage people in the molecular biosciences. We offer study and careers advice toschool students,higher education studentsandteachersas well as carrying outpublic engagementevents.

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What is biochemistry? | Biochemistry

Biochemistry

Biochemistry: Free For All – Open Textbook Library

Reviewed by Jeffry Nichols, Associate Professor, Worcester State University on 6/1/21

Comprehensivenessrating:3see less

The material covered is fairly similar to other biochemistry textbooks, but does lack some of the details of a more comprehensive biochemistry text (i.e. Lehninger's text). This isn't a negative, just an observation. The order in which the concepts are presented is different, but again still fairly complete.

Content Accuracyrating:4

From what I could tell, the information is accurate. Examples appear to be unbiased and give good everyday correlations to biochemistry ideas.

Relevance/Longevityrating:3

The material for the basics and background for biochemistry are unlikely to change, so in that sense they are relevant. The way in which the material is presented, i.e. the formatting, does make it difficult to follow at times. The tables and figures are not always near the relevant text and often there are figures/tables that appear before the section in the text. Again, this could be a formatting issue.

Clarityrating:4

The text is easy to follow, avoids jargon for the most part (until it needs defining). As mentioned above, references to tables/figures are hard to follow and some tables/figures seem "stuck in" at random points. This hurts the clarity of the text while reading.

Consistencyrating:4

Each chapter sticks to a familiar layout and walks the student through the various topics in a coherent manner.

Modularityrating:3

Overall the text could be broken up, but again, possibly due to formatting, many of the links do not work, interrupting the flow, On all the end of chapter sections, I couldn't get any of the links to work, with a message about "to be developed" or "coming soon". This is unfortunate as these links could be great for further exploration and follow up assignments.

Organization/Structure/Flowrating:3

Yes, the organization is pretty good, although I think the introduction of electron transport and electrochemistry should come after an understanding of WHERE these molecules are coming from, i.e. metabolism, breakdown of sugars, fats, amino acids, etc. This doesn't make it "bad", just no my personal preference. And as mentioned previously, the plethora of tables/figures can be overwhelming when they don't always line up with the discussion of them in the text.

Interfacerating:2

Couldn't get the links to work--although it appears many of the links are "printed" after the end of entire book. So the material might be there, but as it is currently put together, it would be difficult for instructors or students to use these links effectively.

Grammatical Errorsrating:4

From what I can tell, the grammar is fine throughout the text.

Cultural Relevancerating:4

Again, from what I read, I didn't notice any insensitive or offensive parts. Examples were clear and highlighted the biochemical aspects without a need address social or other issues. (which could actually be good depending on the nature of the class and student's interest in how science touch many aspects of our lives)

I have hope for this book, but I couldn't readily tell if this book is being maintained or updated on a regular basis, or if it is just a framework for others to build upon. The organization isn't ideal, and there are problems with links and such, but the overall material and coverage looks pretty good.

The rest is here:
Biochemistry: Free For All - Open Textbook Library

Biochemistry

Biochemistry Open & Free OLI

Biochemistry is an introductory course, designed for both biology and chemical engineering majors.

A consistent theme in this course is the development of a quantitative understanding of the interactions of biological molecules from a structural, thermodynamic, and molecular dynamic point of view. A molecular simulation environment provides the opportunity for you to explore the effect of molecular interactions on the biochemical properties of systems.

This course assumes that students have taken introductory chemistry, including basic thermodynamics, as well as introductory organic chemistry. An introductory biology course is not a prerequisite for the course, but students would benefit from some prior exposure to biology, even at the high school level. Required mathematical skills include simple algebra and differential calculus.

The two main learning goals of the course are:

The course begins with amino acids and transitions into protein structure and thermodynamics. Protein-ligand binding is treated for both non-cooperative and cooperative binding using immunoglobulins and oxygen transport as examples. The enzymatic function of proteins is explored using serine and HIV proteases as examples. Enzyme kinetics is treated using steady-state kinetic analysis. Enzyme inhibition is treated quantitatively, using HIV protease as a key example.

Carbohydrate and lipids are presented in sufficient depth to allow the student to fully understand major aspects of central metabolism. The discussion of metabolism is focused on energy generation, fermentation, and metabolic control.

The course concludes with an extensive section on nucleic acid biochemistry. The focus of this section is to provide the student with sufficient background so that they are literate in the recombinant DNA technologies as they relate to protein production using recombinant methods.

After a treatment of molecular forces and solution properties, the course builds on molecular and energetic descriptions of fundamental monomeric building blocks to develop a comprehensive understanding of the biological function of polymers and molecular assemblies at the molecular and cellular level. In addition to multiple case studies, the course concludes with a capstone exercise that leads students through the steps required to produce recombinant proteins for drug discovery. The major topics in the course are:

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Biochemistry Open & Free OLI

Biochemistry

Changing the face of science | @theU – @theU

Adapted from a story that originally appeared here in the University of Utah Health newsroom.

When Faith Bowman was deciding where to attend graduate school, the University of Utah wasnt exactly at the top of her list. Coming from Wisconsin, she didnt know much about the school or the state. But during her recruitment visit, an informal gathering with students from the all-inclusive University of Utah SACNAS (Society for Chicanos/Hispanics and Native Americans in Science) chapter helped her see things differently. After talking with them, she knew that if she came, she would be surrounded by a supportive community. She chose the U, and three years later, that prediction has held true.

To me, SACNAS is a community away from home, says Bowman, now president of the U chapter. Its a place that has created a sense of belonging for me on campus while helping me to achieve my professional goals.

Bowmans experience isnt unique. The Bioscience graduate programs have collaborated with the U SACNAS community in its annual recruitment activities since 2017. These efforts, which included hosting the 2017 SACNAS National Conference in Salt Lake City, have resulted in tripling recruitment of students from historically underrepresented (UR) backgrounds. UR students now comprise 33% of the domestic class, and racial and ethnic minorities comprise 28%, reflecting the national talent pool.

Knowing this diverse, all-inclusive community is here helps recruits decide, in parallel to the awesome research, that we are their best fit, says Jeanette Ducut-Sigala, U SACNAS manager.

The ability to make meaningful change in diversity and inclusion has earned U SACNAS national recognition. In a virtual ceremony held on October 13, the national organization designated the U group Chapter of the Year along with six other local chapters of the 133 located in the U.S. and Puerto Rico.

U SACNAS officially launched in 2014 with the goal of training and supporting the next generation of diverse STEM talent. From students to professionals, the parent organization fosters success in attaining advanced degrees, careers and positions of leadership within STEM. The U chapter mainly serves graduate students, postdocs and staff while a sub-chapter centered on main campus is open to both undergraduates and graduate students. Ducut-Sigala, biochemistry faculty Minna Roh-Johnson and Paul Sigala and human genetics faculty Clement Chow operate as advisors.

Its clear that across the country there is a great need for organizations like this one. According to SACNAS, the national STEM workforce is only 6% Hispanic, 4.8% Black, and 0.2% Native American, numbers that are significantly lower than in the overall U.S. workforce. A lack of diversity hurts all of us, the organization explains, because diverse voices bring creative solutions to our worlds most pressing scientific problems.

U of U SACNAS helps its members to grow through authentic inclusion: hosting talks by professionals to inspire career aspirations and create connections with role models, supportive peer mentoring, outreach and leadership development. In collaboration with the University Counseling Center, Health and Wellness Center and Center for Student Wellness, they hold sessions where members can talk through troublesome issues and learn strategies for balancing their lives in and outside of science. Knowing that role modeling can make all the difference, particularly in young children, they also perform outreach with local K-12 schools to show that science is for everyone.

The organization has provided a sense of belonging to member Jesse Velasco-Silva, a biochemistry graduate student and the chapters vice president. The SACNASfamiliaalways encourages me to bring, show and celebrate my strength, resilience, culture, traditions and science, he says. He explains that being a first-generation Mexican-American immigrant and college student has come with challenges. The guidance and support hes received from the SACNAS community has helped him to overcome them.

As for Bowman, her experience has come full circle. She benefitted from the openness of the U SACNAS community when she was making the difficult decision of where to get her doctoral degree. Now, she does the same for the next sets of prospective students.

I get to show the recruits, particularly the first-gen BIPOC students, how we belong on campus, belong in our programs, and thrive here because we have a community like SACNAS, she says. We have a supportive, collaborative environment at Utah and really, a university committed to equity and inclusion.

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Changing the face of science | @theU - @theU