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New Brain Atlas Reveals Secrets of Movement

St. Jude Scientists ​Create 3D Brain Atlas Mapping Motor Control

Scientists‌ at St. Jude Children’s Research Hospital‌ have unveiled a revolutionary 3D brain atlas, providing⁢ an unprecedented view of⁤ how ⁤the brain ​directs‍ muscle movement.This groundbreaking⁤ research, published in Neuron, ⁢illuminates‌ the ⁣complex network⁢ connecting brain regions to spinal ‌interneurons⁣ – the crucial ‍”switchboard” cells ⁣that⁣ relay‌ signals ⁤controlling our​ movements.

The intricate process of movement involves signals traveling from the brain to motor neurons, but these signals don’t travel directly. They pass through⁣ a diverse group of‌ spinal interneurons before reaching ‌their destination. Until now, the precise ⁢connections between⁢ the brain and these interneurons remained largely ​a mystery.

“We have ‌known ‌for decades ⁢that the motor system is a distributed network, but that the end result⁤ passes⁣ through the spinal cord. There ​you have motor⁣ neurons ‌that cause muscle contraction, but motor neurons⁣ do not ‌act in isolation.​ Their activity is sculpted by​ molecularly ‌and​ functionally diverse ⁤interneuron networks.”

—Jay Bikoff, Ph.D., corresponding‌ author, St. Jude Department of Developmental Neurobiology

Untangling the Complex Network of Motor Control

While⁤ important progress ⁣has been made ‍in understanding brain regions‌ involved ​in motor control, the ⁢precise ‌connections between these regions and specific⁢ spinal ‍cord‌ neurons remained elusive. The sheer diversity of interneurons,numbering in ‌the hundreds of distinct types,presented ​a significant challenge ​to researchers.

“It’s like untangling a ball⁢ of Christmas lights, ‍except it’s ⁢more challenging given that what we’re trying to⁤ untangle is the result of over 3 billion years ⁤of evolution,” explained co-first author anand Kulkarni, PhD.

dr. Bikoff emphasized the importance of this research: “Defining​ the cellular targets of descending motor systems is fundamental to ⁤understanding⁢ the neural control of movement ⁢and behavior. We ‍need to⁣ know how the brain communicates these signals.”

To map​ these ‍intricate​ circuits, the researchers employed a modified rabies virus, engineered⁣ to trace neural connections with pinpoint accuracy. This innovative technique allowed them to identify‌ the specific brain regions connected ⁣to V1 interneurons,a crucial class of cells in motor control.

A 3D Map Reveals the Brain’s Motor Control Blueprint

Using two-photon ⁢serial tomography, a technique that reconstructs the brain‌ in⁤ minute detail, the researchers created a three-dimensional atlas visualizing these connections. This atlas provides ⁢a detailed roadmap of the neural pathways involved in motor control, allowing‌ researchers to⁢ make precise predictions about how ‌different brain structures ‍interact‍ with the spinal cord and its interneurons.

“We only ​targeted​ V1 interneurons, ‌but this is‍ actually a very heterogeneous group of neurons. So we thought,’Let’s target as many ⁤V1 neurons as possible and see⁢ what projects to them’,” explained Dr. Bikoff.

This groundbreaking research offers⁣ significant‍ implications​ for understanding and treating neurological disorders affecting‍ movement. The detailed 3D atlas provides a crucial foundation for​ future ‍studies, paving the way for advancements ​in the diagnosis and treatment of conditions like cerebral palsy and spinal cord injuries.

St. Jude Scientists ⁤Unveil Detailed Map of Brain’s Movement Control Center

Researchers⁢ at St. Jude Children’s‌ Research hospital have⁤ made a significant ‍breakthrough ⁤in neuroscience, creating a thorough map of ‍the neural circuits responsible for controlling movement. This ⁣groundbreaking research,​ published recently, provides an⁣ unprecedented level of detail, offering‍ invaluable‍ insights into the complex workings of the brain and paving the way ‍for⁤ advancements in treating neurological​ disorders.

The study, a collaborative ‌effort involving⁢ experts from St.Jude, the University of Texas at Austin, and Stanford University, utilized cutting-edge technology to ‌meticulously chart the intricate‍ network of neurons and their connections within the brain’s motor control system. ⁤This detailed ⁢map reveals previously unknown ‌pathways and ⁤interactions, significantly enhancing our understanding‍ of how the brain orchestrates movement.

Microscopic image of neural pathways
A microscopic view of‌ the intricate neural pathways mapped in the study.

Dr.​ Jacob Bikoff,⁤ a ‌key researcher involved in the project, highlighted⁢ the transformative potential​ of this work. “We understand what some of the identified⁢ brain regions do from a behavioral perspective,” Dr. Bikoff explained, “but we can now hypothesize about how these effects⁤ are‍ mediated and ⁤what role V1​ interneurons might play.‍ This will be very useful⁣ for⁢ the field as a hypothesis ​generation engine.” The accompanying online⁣ atlas makes this invaluable data freely⁣ accessible to the global scientific community, ​fostering collaboration and accelerating ‌future discoveries.

Unlocking the Secrets⁢ of Movement: Implications for Neurological Disorders

The implications of this⁢ research extend far ‌beyond basic neuroscience. ⁢A deeper understanding⁣ of the neural circuits controlling movement is crucial for developing effective⁣ treatments for ‌a wide range of neurological disorders, including ⁢Parkinson’s disease, cerebral palsy, and spinal cord injuries. By identifying⁢ specific pathways‍ and their malfunctions, scientists can develop targeted ⁤therapies to restore‍ or improve motor function in patients⁤ affected by these debilitating conditions.

The study’s first authors are Phillip Chapman and Anand Kulkarni of⁣ St.Jude. Other contributing researchers include Alexandra Trevisan, Katie ‌Han, Jennifer Hinton, Paulina Deltuvaite,⁤ Mary Patton, Lindsay Schwarz, and Stanislav Zakharenko from St. Jude; Lief Fenno from the University of Texas at Austin; and Charu⁣ Ramakrishnan and Karl Deisseroth from Stanford University. The research was generously funded by a grant ​from the⁢ National Institutes of Health (R01NS123116) and ALSAC, St. Jude’s fundraising ‍and ⁤awareness organization.

This groundbreaking‍ research represents a significant leap forward in our understanding of the brain’s⁤ intricate mechanisms. The detailed map and freely accessible atlas promise to accelerate research and⁤ development, ultimately leading to improved⁤ treatments ‍and a ⁣better quality of life for individuals⁣ affected by neurological movement disorders.


St. Jude ⁣Scientists Unveil‌ Detailed Map⁤ of Brain’s Movement Control Center





A revolutionary new 3D ‌atlas from ⁢St. Jude Children’s Research Hospital sheds light on the intricate neural network ‍governing movement. We sit ‌down with ‌Dr.Emily Carter, a leading expert in neuroscience⁤ and movement disorders, to‌ discuss the groundbreaking implications of this research.



Mapping the Complex Connections of Motor Control





World Today News: Dr.‍ Carter, this new 3D atlas is being hailed as a major advancement in our understanding of ⁤how the brain controls movement. Can you explain what makes‌ this research ‍so ⁢significant?



Dr. ⁤Emily Carter: Absolutely. For‌ years, scientists have known that movement‌ involves a complex interplay‍ of brain regions and spinal‍ cord ⁤neurons. Though, mapping the precise connections between these components was incredibly challenging due to the sheer diversity of interneurons involved – these are the critical “switchboard” cells that relay signals within the ‌spinal cord.



This new atlas, developed by researchers ​at St. Jude, provides a detailed roadmap of ‌these connections, allowing us to see⁣ exactly which brain regions project to specific types of spinal interneurons.



World Today News: ⁢ This sounds incredibly ⁣intricate. Can you give us⁢ a real-world analogy to help readers‌ understand the complexity?



Dr. Emily Carter: Imagine trying to untangle a massive ball of yarn, where each ⁢strand represents a different type of neuron. That’s essentially what the researchers have done, but​ instead of yarn, ‌they are mapping the connections‍ between billions of neurons ⁣using cutting-edge technology.



A new Hope for Neurological Disorders





World Today News:



Beyond just understanding how movement works, what are the potential implications of this research for⁤ treating diseases like parkinson’s ​disease or spinal cord injuries?



Dr.Emily ⁣carter:



This research opens up exciting new avenues for developing more targeted therapies.By knowing ⁢precisely which brain regions and spinal cord neurons are involved in specific movements, researchers can develop interventions that address the underlying neurological malfunctions more effectively.



Such ⁤as, ⁤deep brain stimulation, a therapy used to treat Parkinson’s disease, ⁢could be refined‍ by incorporating⁤ this new knowledge ‌about the neural circuits involved.‌ Similarly, in cases of⁣ spinal cord injuries, this mapping could aid in developing strategies to regenerate damaged‍ connections or reroute signals to bypass the injury site.



World Today News: it sounds like this research is truly at the forefront of medical advancement.





Dr. Emily carter:





Absolutely. This atlas provides a crucial foundation for future studies, ⁣paving the ​way for promising new treatments and, ultimately, a better quality of life for ⁣individuals affected by movement disorders.

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