 |
|
Musicians' Brains 'Fine-Tuned' to Identify Emotion
March 04, 2009EVANSTON, Ill. --- Looking for a mate who in everyday conversation can pick up even your most subtle emotional cues? Find a musician, Northwestern University researchers suggest.
In a study in the latest issue of European Journal of Neuroscience, an interdisciplinary Northwestern research team for the first time provides biological evidence that musical training enhances an individual's ability to recognize emotion in sound.
"Quickly and accurately identifying emotion in sound is a skill that translates across all arenas, whether in the predator-infested jungle or in the classroom, boardroom or bedroom," says Dana Strait, primary author of the study.
A doctoral student in the Henry and Leigh Bienen School of Music, Strait does research in the Auditory Neuroscience Laboratory directed by neuroscientist Nina Kraus. The laboratory has done pioneering work on the neurobiology underlying speech and music perception and learning-associated brain plasticity.
Kraus, Northwestern's Hugh Knowles Professor of Communication Sciences and Neurobiology; Richard Ashley, associate professor of music cognition; and Auditory Neuroscience Laboratory manager Erika Skoe co-authored the study titled "Musical Experience and Neural Efficiency: Effects of Training on Subcortical Processing of Vocal Expressions in Emotion."
The study, funded by the National Science Foundation, found that the more years of musical experience musicians possessed and the earlier the age they began their music studies also increased their nervous systems' abilities to process emotion in sound.
"Scientists already know that emotion is carried less by the linguistic meaning of a word than by the way in which the sound is communicated," says Strait. A child's cry of "Mommy!" -- or even his or her wordless utterance -- can mean very different things depending on the acoustic properties of the sound.
The Northwestern researchers measured brainstem processing of three acoustic correlates (pitch, timing and timbre) in musicians and non-musicians to a scientifically validated emotion sound. The musicians, who learn to use all their senses to practice and perform a musical piece, were found to have "finely tuned" auditory systems.
This fine-tuning appears to lend broad perceptual advantages to musicians. "Previous research has indicated that musicians demonstrate greater sensitivity to the nuances of emotion in speech," says Ashley, who explores the link between emotion perception and musical experience. One of his recent studies indicated that musicians might even be able to sense emotion in sounds after hearing them for only 50 milliseconds.
The 30 right-handed men and women with and without music training in the European Journal of Neuroscience study were between the ages of 19 and 35. Subjects with music training were grouped using two criteria -- years of musical experience and onset age of training (before or after age 7).
Study participants were asked to watch a subtitled nature film to keep them entertained while they were hearing, through earphones, a 250-millisecond fragment of a distressed baby's cry. Sensitivity to the sound, and in particular to the more complicated part of the sound that contributes most to its emotional content, was measured through scalp electrodes.
The results were not exactly what the researchers expected. They found that musicians' brainstems lock onto the complex part of the sound known to carry more emotional elements but de-emphasize the simpler (less emotion conveying) part of the sound. This was not the case in non-musicians.
In essence, musicians more economically and more quickly focus their neural resources on the important -- in this case emotional -- aspect of sound. "That their brains respond more quickly and accurately than the brains of non-musicians is something we'd expect to translate into the perception of emotion in other settings," Strait says.
The authors of the study also note that the acoustic elements that musicians process more efficiently are the very same ones that children with language disorders, such as dyslexia and autism, have problems encoding. "It would not be a leap to suggest that children with language processing disorders may benefit from musical experience," says Kraus.
Strait, a pianist and oboe player who formerly worked as a therapist with autistic children, goes a step further. Noting that impaired emotional perception is a hallmark of autism and Asberger's syndromes, she suggests that musical training might promote emotion processing in these populations.
To learn more about the link between music, the brain and language processing, visit Northwestern's Auditory Neuroscience Laboratory at http://www.brainvolts.northwestern.edu.
Northwestern University
Auditory Neuroscience Current Events and Auditory Neuroscience News RSSNew brain findings on dyslexic children
The vast majority of school-aged children can focus on the voice of a teacher amid the cacophony of the typical classroom thanks to a brain that automatically focuses on relevant, predictable and repeating auditory information, according to new research from Northwestern University.
Neural mechanism reveals why dyslexic brain has trouble distinguishing speech from noise
New research reveals that children with developmental dyslexia have a deficit in a brain mechanism involved in the perception of speech in a noisy environment.
Taking up music so you can hear
Anyone with an MP3 device -- just about every man, woman and child on the planet today, it seems -- has a notion of the majesty of music, of the primal place it holds in the human imagination.
Lend me your ears -- and the world will sound very different
Recognising people, objects or animals by the sound they make is an important survival skill and something most of us take for granted. But very similar objects can physically make very dissimilar sounds and we are able to pick up subtle clues about the identity and source of the sound.
Research finds music training 'tunes' human auditory system
A newly published study by Northwestern University researchers suggests that Mom was right when she insisted that you continue music lessons — even after it was clear that a professional music career was not in your future.
Labour Predictor device secures venture capital boost
A prototype of the unique device for pregnant women that will accurately predict the onset of labour is expected within six months, following the announcement of a substantial investment led by entrepreneur and business angel, Graham Cooper. Cooper, who lives in Cumbria, has joined Jopejo Ltd as Chairman. He has a strong background in supporting early-stage technologies and his involvement with the company consolidates a strong relationship with innovators at the University of Leeds. The investment opportunity was brought to his attention by Deborah Withington, Professor of Auditory Neuroscience at the University, and the entrepreneur behind both Sound Alert Technology and Sound Foresight o
More Auditory Neuroscience Current Events and Auditory Neuroscience News Articles
 |
Handbook of (Central) Auditory Processing Disorders, Vol. 1: Auditory Neuroscience and Diagnosis by Frank E. Musiek and Gail D. Chermak (Author) The first volume of Musiek and Chermak's definitive Handbook of (C)APD provides comprehensive coverage of auditory neuroscience and clinical science needed to accurately diagnose the range of developmental and acquired (C)APD disorders in children, adults, and older adults. With contributions from world-renowned authors, the handbook reflects major advances in auditory neuroscience and cognitive science, particularly over the last two decades. The chapters in this volume cover basic science foundations, diagnostic principles and procedures, and multidisciplinary assessment, as well as addressing the ongoing research and development in diagnostics. |
|
Cognitive-behavioral recovery in comatose patients following auditory sensory stimulation.: An article from: Journal of Neuroscience Nursing by Alice E. Davis (Author), Ana Gimenez (Author) This digital document is an article from Journal of Neuroscience Nursing, published by American Association of Neuroscience Nurses on August 1, 2003. The length of the article is 6996 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser. Citation Details Title: Cognitive-behavioral recovery in comatose patients following auditory sensory stimulation. Author: Alice E. Davis Publication: Journal of Neuroscience Nursing (Refereed) Date: August 1, 2003 Publisher: American Association of Neuroscience Nurses Volume: 35 Issue: 4 Page: 202(9) Distributed by Thomson... | |
|
The Auditory Cortex: Fundamental Neuroscience by Jeffery A. Winer (Editor), Christoph Schreiner (Editor) There has been substantial progress in understanding the contributions of the auditory forebrain to hearing, sound localization, communication, emotive behavior, and cognition. The Auditory Cortex covers the latest knowledge about the auditory forebrain, including the auditory cortex as well as the medial geniculate body in the thalamus. This book will cover all important aspects of the auditory forebrain organization and function, integrating the auditory thalamus and cortex into a smooth, coherent whole. Volume One covers basic auditory neuroscience. It complements The Auditory Cortex, Volume 2: Integrative Neuroscience, which takes a more applied/clinical perspective. | |
 |
Recent Advances in Auditory Neuroscience 2007 by Edited by Keiji Tabuchi and Akira Hara (Author) From the Preface Hearing impairment is bewildering pathology which causes severe annoyance to many patients. More and more attention is being aimed at elucidating the mechanisms of hearing loss. This volume contains eight chapters, which deal with issues on basic sciences of cochlear physiology, pathology and pharmacology. Research about auditory neuroscience often necessitates the use of nonhuman animal models. This volume reviews recent findings about auditory neuroscience mainly obtained from animal models because there are sufficient grounds to assume similarities in cochlear pathophysiology of human and nonhuman mammalian auditory systems. The goal of the findings cited in this volume is to explain the general mechanisms of hearing impairments for basic researchers, while, at the... |
|
Auditory Function: Neurobiological Bases of Hearing (The Neurosciences Institute monograph series) by Gerald M. Edelman (Editor), etc. (Editor), W.E. Gall (Editor) Recent advances in anatomical, physiological, and psychophysical techniques and new formal analyses have made considerable advances in integrating the various aspects of hearing. Consisting of five sections, this volume begins with development and proceeds from the periphery to the highest psychological functions reflected in speech and guided behavior. In the first section the developing auditory system is considered; in Section Two cochlear neurobiology and current theories of cochlear mechanics are reviewed. Section Three deals with the response properties and electrical characteristics of auditory neurons. Section Four discusses the models of peripheral and central factors in intensity perception, auditory masking, and spectral shape discrimination. The final section examines auditory... | |
 |
The Auditory Midbrain: Structure and Function in the Central Auditory Pathway (Contemporary Neuroscience) by Lindsay Aitkin (Author) |
 |
(NAS Colloquium) Auditory Neuroscience: Development, Transduction, and Integration by Proceedings of the National Academy of Sciences (Author) |
|
Handbook of (Central) Auditory Processing Disorders: Auditory Neuroscience And Diagnosis Vol. 1-2 (v. 1-2) by Gail D. Chermak (Author), Frank E. Musiek (Editor) | |
![The cognitive neuroscience of auditory distraction [An article from: Trends in Cognitive Sciences]](http://ecx.images-amazon.com/images/I/514N087P9RL._SL160_.jpg) |
The cognitive neuroscience of auditory distraction [An article from: Trends in Cognitive Sciences] by T. Campbell (Author) This digital document is a journal article from Trends in Cognitive Sciences, published by Elsevier in 2005. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: We are often aware of the content of distracting sound, although typically remain unaware of the processes by which that sound is disruptive. Disruption can occur even when the sound is ignored and unrelated to the task being performed. In a recent major development, Gisselgard et al. have used positron emission tomography to reveal how distracting sounds recruit the involvement of dorsolateral prefrontal cortex. |
 |
Auditory Perception of Sound Sources (Springer Handbook of Auditory Research) by William A. Yost (Editor), Richard R. Fay (Editor), Arthur N. Popper (Editor) This volume covers higher-level auditory processes that are perceptual processes. The chapters describe how humans and other animals perceive the sounds that they receive from the many sound sources existing in the world. This book will provide an overview of areas of current research involved with understanding how sound-source determination processes operate. This book will focus on psychophysics and perception as well as being relevant to basic auditory research. |
| © 2009 BrightSurf.com |