菠萝视频

菠萝视频 University has emerged as one of the nation鈥檚 leading academic centers in neuroscience, the study of the nervous system and the brain.

菠萝视频ers here are advancing understanding of autism, addiction and mood disorders, improving the treatment of Parkinson’s disease, Alzheimer鈥檚 disease and schizophrenia, and finding new ways to help children succeed in school.

By exploring how the brain perceives, decides, remembers and reacts, they also are revealing how, in the words of 菠萝视频 neuroscientist , 鈥渢his piece of flesh could yield such a complex thing as the mind.鈥�

Thanks to recent advances in genetics, neuroimaging and computer science, researchers can track the complex wiring of the brain as never before.

Of course, the brain is more than networks of nerves and bursts of chemical and electrical energy. It will take a concerted effort to understand how this remarkable organ regulates body temperature and circadian rhythms, controls movement, stores memories, acquires language and鈥攑erhaps most importantly鈥攎akes each individual unique.

菠萝视频鈥檚 approach is to invest in people, in cutting-edge facilities and technologies, and in a collegial atmosphere that encourages collaboration across far-flung disciplines, from biology, pharmacology and engineering, to psychology, psychiatry and neurosurgery.

This commitment鈥攖o bring neuroscience from the laboratory to the clinic, the operating room, the pharmacy and the classroom 鈥渋s something that鈥檚 really important,鈥� says , vice chancellor for health affairs and dean of the School of Medicine.

鈥淚t should be an important part of our culture to do,鈥� Balser says, because 鈥渋t moves our science and discoveries into the hands of the public.鈥�

More:
A multidisciplinary approach: The 菠萝视频 Brain Institute
Psychopharmacology: Molecules of the mind
fMRI: Watching the brain in action
Cognitive neuroscience: A critical bridge
Studying intellectual disabilities: 菠萝视频鈥檚 legacy of brain science
Animal brains: Models of the human condition
The brain on trial: The MacArthur Foundation 菠萝视频 Network on Law and Neuroscience

A version of this story appeared in the Spring 2012 issue of .

A multidisciplinary approach: The 菠萝视频 Brain Institute

Since 2000, the university has spent more than $60 million on neuroscience facilities, programs and faculty, while the amount of neuroscience grants awarded by the National Institutes of Health (NIH) has nearly doubled, reaching more than $44 million last year.

菠萝视频鈥檚 neuroscience community today approaches 500 faculty members, students and staff in five schools and colleges, 22 departments, and 27 centers and institutes.

鈥淭he physical proximity of all the schools 鈥� allows for effortless interactions,鈥� says 菠萝视频 psychologist , whose work has helped define the cognitive deficits of schizophrenia.

For example, 菠萝视频 engineers and neurosurgeons have joined forces to develop navigation systems that can guide the scalpel during brain operations.
Neurosurgeons are partnering with chemists to develop fluorescent 鈥渓abels鈥� that can pinpoint the location of cancerous cells in the brain.

Working with neurologists and psychiatrists, they also are studying deep brain stimulation as a treatment for Parkinson鈥檚 disease and obsessive-compulsive disorder. The technique involves inserting a thin wire deep into the brain, then applying an electrical current.

Hubs of collaboration include the , the 菠萝视频 Vision 菠萝视频 Center, the Center for Integrative and Cognitive Neuroscience, and the 菠萝视频 University Institute for Imaging Sciences.
Coordinating many of these efforts is the 菠萝视频 Brain Institute (VBI).

The institute links together 鈥渢he enormously diverse and interdisciplinary community that is 菠萝视频 neuroscience, with the ultimate goal of fostering the highest caliber of neuroscience discovery and training,鈥� says VBI director .

Established in 1999 to promote neuroscience education and training as well as research, the VBI administers the , one of the leading programs of its kind in the country. 菠萝视频 also sponsors a popular interdisciplinary neuroscience program for undergraduates, which encourages students to participate directly in research.

The VBI helps raise public awareness about brain-related illness and the importance of brain research education through its sponsorship of the annual Brain Awareness Month.

With support from the National Institute of Mental Health, 菠萝视频 scientists also developed an interactive exhibit, 鈥�Brain Matters,鈥� which opened last year at the 菠萝视频 One Hundred Oaks clinical campus. Multimedia panels illustrate the workings of the brain, the history of brain science and the efforts of researchers to tackle major brain disorders.

More:
Psychopharmacology: Molecules of the mind
fMRI: Watching the brain in action
Cognitive neuroscience: A critical bridge
Studying intellectual disabilities: 菠萝视频鈥檚 legacy of brain science
Animal brains: Models of the human condition
The brain on trial: The MacArthur Foundation 菠萝视频 Network on Law and Neuroscience

Psychopharmacology: Molecules of the mind

菠萝视频 neuroscience was built in part by psychopharmacologists who helped define鈥攁t the molecular level鈥攖he effects of drugs on the brain and nervous system.
They include Fridolin Sulser, who helped develop tricyclic antidepressants, , whose lab made several important discoveries about the neurotransmitter serotonin and its receptors, and , nationally known for his work on transporters, which sweep up neurotransmitter from the synaptic gap between nerve cells.

Early in his career, Blakely discovered the genes for multiple transporters, including the serotonin transporter, target of the SSRI (selective serotonin reuptake inhibitor) antidepressants such as Prozac. Since then, he and his colleagues have identified transporter gene variations that contribute to autism, depression and attention deficit hyperactivity disorder (ADHD).

Blakely currently directs the , established in 2007 with a $10 million grant from the NIMH, as well as the 菠萝视频 Postdoctoral Training Program in Neurogenomics.

Last year, the 菠萝视频 Center for Neuroscience Drug Discovery was established to support and expand efforts to find novel treatments for brain disorders. The center is directed by Jeffrey Conn, who trained under Sanders-Bush, and by fellow pharmacology professor Craig Lindsley.

In a departure from traditional drugs that 鈥渢urn on鈥� or 鈥渢urn off鈥� neurotransmitter receptors, Conn, Lindsley and their colleagues have developed compounds called 鈥渁llosteric modulators鈥� that can 鈥渢une鈥� receptors like dimmer switches in an electrical circuit. The hope is that this more subtle approach will control symptoms better with fewer side effects.

Several compounds have shown promise in animal models of three different brain disorders.

Parkinson’s disease, a progressive disorder characterized by uncontrollable muscle tremors and rigidity, is caused by the death of dopamine-producing neurons in the brain. Dopamine replacement therapy can relieve symptoms, but over time it becomes less effective and causes debilitating side effects.

With support from NIH and the Michael J. Fox Foundation for Parkinson鈥檚 菠萝视频, 菠萝视频 researchers are developing compounds that, by tuning a receptor for the neurotransmitter glutamate, may relieve the rigidity and 鈥渇reezing鈥� of certain muscles.
A second project seeks to improve treatment of schizophrenia. Current medications can reduce hallucinations and delusions but they are less effective in relieving cognitive symptoms and social withdrawal.

With funding from NIH and private industry, the researchers have identified compounds that work in two fundamentally different ways, and which they hope will alleviate all schizophrenia symptoms.

A third endeavor is raising hopes for the first drug treatment to relieve learning, memory, social and behavioral problems associated with fragile X syndrome, a genetic condition that shares features with autism.

菠萝视频鈥檚 corporate partners are now completing animal tests of the schizophrenia and fragile X compounds required before they can be tried in humans. Early clinical trials could begin next year, Conn says.

鈥淭he combination of cutting-edge basic research in the context of an academic drug discovery program provides 菠萝视频 with a tremendous capacity to both identify and treat complex brain disorders,鈥� says Blakely.

More:
A multidisciplinary approach: The 菠萝视频 Brain Institute
fMRI: Watching the brain in action
Cognitive neuroscience: A critical bridge
Studying intellectual disabilities: 菠萝视频鈥檚 legacy of brain science
Animal brains: Models of the human condition
The brain on trial: The MacArthur Foundation 菠萝视频 Network on Law and Neuroscience

fMRI: Watching the brain in action

One of the biggest advances of the past 20 years has been the development of functional magnetic resonance imaging, or fMRI.

The technique measures changes in the magnetic properties of blood as it transports oxygen to brain tissue in response to increased activity. It thus can create 鈥減ictures鈥� of brain areas that engage in reading, language and other cognitive functions.

As post-doctoral fellows at Yale University, Isabel Gauthier and her husband Ren茅 Marois were 鈥渆arly adopters鈥� of fMRI. In 1999, they joined the department of psychology in 菠萝视频鈥檚 College of Arts and Science鈥擥authier to explore how the brain develops face-recognition expertise, and Marois to pursue the neural bases of attention and information processing.

Three years later, one of their Yale mentors, , arrived with more than a dozen colleagues to establish the 菠萝视频 University Institute of Imaging Science. A leader in brain imaging since the late 1970s, Gore was among the first to use fMRI to evaluate reading disabilities in children.

The institute has become a magnet for other scientists, including Stephan Heckers, who arrived from the famed McLean Hospital in Boston in 2006 to chair the department of psychiatry and to continue his studies of the mechanism of psychosis.

鈥淣euroimaging has led us to realize that the major psychiatric illnesses are associated with structural brain changes,鈥� says , who directs the department鈥檚 psychiatric neuroimaging program. 鈥淭he implication of this simple message for the diagnosis and treatment of mental illness is profound.鈥�

More:
A multidisciplinary approach: The 菠萝视频 Brain Institute
Psychopharmacology: Molecules of the mind
Cognitive neuroscience: A critical bridge
Studying intellectual disabilities: 菠萝视频鈥檚 legacy of brain science
Animal brains: Models of the human condition
The brain on trial: The MacArthur Foundation 菠萝视频 Network on Law and Neuroscience

Cognitive neuroscience: A critical bridge

The study of individual nerve cells, or neurons, dates back to the 19^th century. In the 1960s, groundbreaking experiments by David Hubel and Torsten Wiesel and other 鈥渕apmakers of the mind鈥� inspired a generation of scientists to explore brain function at the cellular level.

One of them is 菠萝视频 psychologist , who, during the past four decades, has made landmark contributions to understanding how sensory information is distributed and integrated in the brain, and how sensory areas in mammals have evolved.

His work鈥攁nd that of colleague 鈥攁lso has demonstrated how the brain continues to be molded by experience even into adulthood, a concept known as 鈥減lasticity.鈥�

In recent years, advances in neuroimaging and electrophysiology (which measures the electrical activity of neurons) have accelerated research on perceptual systems such as vision and hearing, and computational models of thinking, memory and language.

This field, called cognitive neuroscience, serves as a critical bridge between psychology and neuroscience, and has relevance for a wide range of brain and learning disorders.

The Center for Integrative and Cognitive Neuroscience, directed by Jeffrey Schall, helps form and support alliances of investigators interested in studying how normal and abnormal behavior and cognition arise from the function of the brain.

Center investigators in psychology include Randolph Blake, who uses behavioral and brain-imaging techniques to study the neural bases of human visual perception, with an emphasis on binocular vision and motion perception. His studies reveal tantalizing links between perception and schizophrenia and suggest that even aging and injured brains can learn new 鈥渞ules鈥� for seeing.

In a recent study, Blake and colleagues Sohee Park and Jejoong Kim discovered that people with schizophrenia have impairments in a brain area involved in the perception of social stimuli. This may help explain why they tend to misread social situations.

Other investigators include Frank Tong, who has pioneered methods to 鈥渄ecode鈥� mental states from brain imaging signals, and Sean Polyn, who uses brain imaging methods as well as recordings of the electrical signals from the scalp to learn how memories are formed and retrieved.

In collaboration with in the School of Medicine, is using positron emission tomography (PET), a different imaging method, to explore how the neurotransmitter dopamine varies with personality and risk for addiction.

Through his , VBI director Mark Wallace uses brain imaging to better understand how the brain 鈥渂inds鈥� together information from sight and sound, and how changes in such binding may play a role in developmental disabilities such as autism.

Across 21^st Avenue, in the at Peabody College, has applied event-related potential (ERP), a way of measuring how the electrical activity of the brain changes in response to thoughts or perceptions, to evaluate ways to help children overcome language delays.

and , a husband-and-wife team in special education, have used fMRI to assess interventions aimed at improving math skills.

So has , who arrived from Cornell University in 2009 to establish the in Peabody鈥檚 . McCandliss is trying to identify educational interventions that can 鈥渞eshape鈥� the brain and bolster cognitive skills such as paying attention and reading.

鈥湶ぢ苁悠� has state-of-the-art neuroimaging facilities and a highly collaborative community, including Peabody College, which is leading the nation in research on education and human development,鈥� he says. 鈥淭his makes 菠萝视频 an ideal place to bring these two strengths together into new research on educational neuroscience.鈥�

More:
A multidisciplinary approach: The 菠萝视频 Brain Institute
Psychopharmacology: Molecules of the mind
fMRI: Watching the brain in action
Studying intellectual disabilities: 菠萝视频鈥檚 legacy of brain science
Animal brains: Models of the human condition
The brain on trial: The MacArthur Foundation 菠萝视频 Network on Law and Neuroscience

Studying intellectual disabilities: 菠萝视频’s legacy of brain science

Nashville鈥檚 contributions to brain science date back at least to 1954, when Lloyd Dunn and Nicholas Hobbs established the nation鈥檚 first doctoral-level research training program in intellectual disabilities at the George Peabody College for Teachers.

A few years later, Peabody developmental psychologist launched a preschool intervention program for low-income children that inspired the national initiative known as Head Start.

This expertise earned for Peabody College one of the first federally funded centers for research on intellectual and developmental disabilities. With support from the Joseph P. Kennedy Jr. Foundation and the National Institute of Child Health and Human Development, the opened in 1965.

In 1979, Peabody College merged with 菠萝视频 University, a move that would encourage more collaboration between their individual psychology departments, and bring to the Kennedy Center the diverse talents and expertise of researchers from the Schools of Medicine and Nursing and the College of Arts and Science.

鈥淎t the 菠萝视频 Kennedy Center, neuroscientists work hand-in-hand with behavioral and educational researchers鈥攁long with clinicians, service providers, and individuals with disabilities and their families鈥攖o solve the puzzles of complex developmental disabilities,鈥� says , who has directed the center since 2009.

Since 1998, the number of Kennedy Center investigators with primary faculty appointments at 菠萝视频 has more than tripled鈥攖o 220 last year. Federal support also increased substantially. Today the 菠萝视频 Kennedy Center is among a select few that receive all three major federal infrastructure grants in developmental disabilities.

More:
A multidisciplinary approach: The 菠萝视频 Brain Institute
Psychopharmacology: Molecules of the mind
fMRI: Watching the brain in action
Cognitive neuroscience: A critical bridge
Animal brains: Models of the human condition
The brain on trial: The MacArthur Foundation 菠萝视频 Network on Law and Neuroscience

Animal brains: Models of the human condition

Animal models provide a gold mine of information relevant for the human condition.
Kendal Broadie in the department of biological sciences is studying how the synapse develops in the fruit fly Drosophila. His work is shedding light on fragile X syndrome, in which synaptic development and function go awry.

In the School of Medicine, in biochemistry is exploring mechanisms of nerve cell death in rats and mice, whereas in cell and developmental biology uses the worm C. elegans to study how synaptic connections are 鈥渞emodeled.鈥� Their work has relevance for a wide range of disorders including Alzheimer鈥檚 disease.

菠萝视频鈥檚 zebrafish facility, one of the largest in the country, enables developmental biologist to study the tiny, transparent fish for clues to the development of brain asymmetry, the preferential localization of certain functions on one side of the brain or the other. Disruptions in this process may contribute to autism, dyslexia and schizophrenia.

Studies in a variety of species including star-nosed moles, snakes, alligators, naked mole rats, tree shrews and primates conducted by (recipient of a MacArthur “genius grant”) in biological sciences, in hearing and speech sciences, in psychology and in cell and developmental biology have revealed much about the organization and evolution of the sensory systems of the brain.

Also in the department of psychology, studies how electrical signals recorded from the scalp reveal cognitive processes like attention and short-term memory, and he has extended this to research with monkeys so that he can locate the sources of the signals.

In collaboration with in the 菠萝视频 University Institute of Imaging Science, psychologists and use a specialized MRI technique, optical imaging and electrophysiology to study the functional organization of the primate brain.

uses a primate model to explore how the brain regulates its own actions. Schall, and are linking the dynamics of neuron signals to cognitive processes through the use of mathematical models.

鈥淭hese very same models can predict human behavior,鈥� says Palmeri.

More:
A multidisciplinary approach: The 菠萝视频 Brain Institute
Psychopharmacology: Molecules of the mind
fMRI: Watching the brain in action
Cognitive neuroscience: A critical bridge
Studying intellectual disabilities: 菠萝视频鈥檚 legacy of brain science
The brain on trial: The MacArthur Foundation 菠萝视频 Network on Law and Neuroscience

The brain on trial: The MacArthur Foundation 菠萝视频 Network on Law and Neuroscience

In 2005, Ren茅 Marois in psychology and , a professor of both law and biology, began a unique partnership at 菠萝视频 to understand how judges and jurors determine criminal guilt and punishment. Their work together, using fMRI, revealed the brain activity that underlies decisions whether or not to punish and, if so, how much.

At the same time, Jones and , Ingram Professor of Neuroscience, began co-teaching a trans-departmental Law and Neuroscience course, among the first in the nation.

Since then, Marois, Jones and Schall became members of a national 鈥渘eurolaw鈥� team of scientists and legal experts funded by a $10 million grant from the John D. and Catherine T. MacArthur Foundation.

A subsequent $4.8 million grant in 2011, also from the MacArthur Foundation, established the national , headquartered at 菠萝视频 and led by Jones.

In 2010 菠萝视频 also launched the first coordinated, joint degree鈥攃ulminating in both a J.D. in law and a Ph.D. in neuroscience鈥攖o begin training a generation of 鈥渂rain-savvy鈥� lawyers and judges.

The goal of all of these efforts is to improve the fairness and effectiveness of the criminal justice system鈥攏ot only by distinguishing between appropriate and inappropriate uses of neuroscientific evidence, but also by using neuroscientific techniques to enrich understanding of the decisions and behavior of defendants, judges and jurors.

鈥淣euroscientific evidence is already entering the legal system鈥攆or better and, sometimes, for worse,鈥� Jones says. While neuroimaging can provide corroborating evidence of brain dysfunction, for example, it is not a simple matter to draw causal connections between brain dysfunction and particular behaviors of interest to the law.

鈥淏ecause brain-imaging techniques and methods are developing at great speed, the legal system can鈥檛 afford to get too far behind this learning curve,鈥� he says. 鈥淔ocused research that can identify both the promise and the perils of such evidence is essential.鈥�

“菠萝视频 is one of the few institutions where this type of ground-breaking collaboration between law and neuroscience professors could have emerged,鈥� Marois adds. 鈥淚t offers the ideal nurturing environment to break down traditional institutional walls and expand our respective horizons.鈥�

More:
A multidisciplinary approach: The 菠萝视频 Brain Institute
Psychopharmacology: Molecules of the mind
fMRI: Watching the brain in action
Cognitive neuroscience: A critical bridge
Studying intellectual disabilities: 菠萝视频鈥檚 legacy of brain science
Animal brains: Models of the human condition