More Ways to Connect
  Facebook Twitter YouTube RSS
  LinkedIn PInterest Instagram
Search
News
Sid Khosla, MD, researches how airflow affects sound in the larynx.
PHOTOS: 
1

Sid Khosla, MD, researches how airflow affects sound in the larynx.
|
2

Effie Gutmark (front), PhD, a UC professor of aerospace engineering, is applying his knowledge of jet engine noise in the study of normal and abnormal voice.
Back Next
Publish Date: 03/13/07
Media Contact: AHC Public Relations, (513) 558-4553
print
PDF download
RSS feed
related news
share this
Jet Engines Help Solve the Mysteries of the Voice

CINCINNATI—Although scientists know about basic voice production—the two “vocal folds” in the larynx vibrate and pulsate airflow from the lungs—the larynx is one of the body’s least understood organs.

 

Sound produced by vocal-fold vibration has been extensively researched, but the specifics of how airflow actually affects sound have not been shown using an animal model—until now.

 

Vortices, or areas of rotational motion that look like smoke rings, produce sound in jet engines. New research from the University of Cincinnati (UC) uses methods developed from the study of jet noise to identify similar vortices in an animal model.

 

Sid Khosla, MD, lead author of the study, says vortices may help explain why individual voices are different and can have a different richness and quality to their sound.

 

“If vortices didn’t affect sound production, the voice would sound mechanical,” says Khosla, assistant professor of otolaryngology. “The vortices can produce sound by a number of mechanisms. This complexity produces a sound that makes my voice different from yours.”

 

Khosla and his team report their findings in the March edition of the Annals of Otology, Rhinology and Laryngology.

 

“Understanding how airflow patterns affect sound in a jet engine (aeroacoustics) helps us determine how we can reduce jet noise,” says coauthor Ephraim Gutmark, PhD, a UC professor of aerospace engineering. “We can apply the same physical understanding of aeroacoustics to study normal and abnormal voice.”

 

According to Khosla, computational and theoretical models have been developed to demonstrate how vortices affect sound production, but the UC team is the first to demonstrate it using an animal model, which makes their findings more applicable to the human larynx.

 

“Currently, when surgery is required to treat voice disorders, it’s primarily done on the vocal cords,” says Khosla. “Actually knowing there are additional sources that affect sound may open up a whole new way for us to treat voice disorders.”

 

In addition to better surgery techniques, Khosla says, having a better understanding of how vortices affect voice production could help in the development of improved pharmacological approaches and clinical pathology services, as well as improved training of the voice.

  

Khosla and Gutmark’s collaborators in the study are UC’s Shanmugam Muruguppan, PhD, and Ronald Scherer, PhD, now at Bowling Green State University.

The study was funded by a grant from the National Institute on Deafness and Other Communication Disorders (NIDCD). 



 back to list | back to top