RxPG News Feed for RxPG News

Medical Research Health Special Topics World
  Home
 
   Health
 Aging
 Asian Health
 Events
 Fitness
 Food & Nutrition
 Happiness
 Men's Health
 Mental Health
 Occupational Health
 Parenting
 Public Health
 Sleep Hygiene
 Women's Health
 
   Healthcare
 Africa
 Australia
 Canada Healthcare
 China Healthcare
 India Healthcare
 New Zealand
 South Africa
 UK
 USA
 World Healthcare
 
 Latest Research
 Aging
 Alternative Medicine
 Anaethesia
 Biochemistry
 Biotechnology
 Cancer
 Cardiology
 Clinical Trials
 Cytology
 Dental
 Dermatology
 Embryology
 Endocrinology
 ENT
 Environment
 Epidemiology
 Gastroenterology
 Genetics
 Gynaecology
 Haematology
 Immunology
 Infectious Diseases
 Medicine
 Metabolism
 Microbiology
 Musculoskeletal
 Nephrology
 Neurosciences
 Obstetrics
 Ophthalmology
 Orthopedics
 Paediatrics
 Pathology
 Pharmacology
 Physiology
 Physiotherapy
 Psychiatry
 Radiology
 Rheumatology
 Sports Medicine
 Surgery
 Toxicology
 Urology
 
   Medical News
 Awards & Prizes
 Epidemics
 Launch
 Opinion
 Professionals
 
   Special Topics
 Ethics
 Euthanasia
 Evolution
 Feature
 Odd Medical News
 Climate

Last Updated: Oct 11, 2012 - 10:22:56 PM
Research Article
Latest Research Channel

subscribe to Latest Research newsletter
Latest Research

   EMAIL   |   PRINT
A recipe for hearing: Sensory hair cells made from stem cells

May 13, 2010 - 4:00:00 AM
Heller says that perhaps the most promising strategy for taking advantage of this new source for hair cells is high-throughput screening for drugs to awaken mammals' lost ability to regenerate hair cells in the way that other animals can.

 
[RxPG] After ten years of effort, researchers reporting in the May 14th issue of the journal Cell, a Cell Press publication, say they have found a way to coax embryonic stem cells as well as reprogrammed adult cells to develop into sensory cells that normally reside in the mammalian inner ear. Those mechanosensitive sensory hair cells are the linchpin of hearing and balance.

Assuming their recipe can be further perfected to reliably generate hair cells in the millions, it opens the door to detailed molecular studies on the cells and new insight into the molecular basis for hearing, according to the researchers. That's especially significant, says Stefan Heller of Stanford University School of Medicine, because the inner ear shelters the last of our senses for which the molecular basis is unknown.

That understanding could also set researchers on a path to discovering new ways to prevent or correct hearing loss by encouraging hair cells' regeneration. After all, the researchers say, our inability to regenerate lost hair cells is the major reason for the permanence of hearing loss as well as certain balance disorders.

Scientists have been left in the dark on the molecular basis for hearing in large part because hair cells are relatively scarce by comparison to other sensory cells, Heller explains. Our inner ears harbor about 30,000 sensory hair cells in total in two different types, few of which can be dissected out of the inner ear and kept alive for study. (Compare that to the 120 million photoreceptors in the retina, all of which can be isolated rather easily.)

Heller's team long ago realized that one solution to this problem was to use stem cells as a source for generating new hair cells, and now they've got the recipe. They have devised what they refer to as a stepwise guidance protocol for making the hearing cells, starting with either mouse embryonic stem cells or induced pluripotent stem (iPS) cells, which are stem cell-like cells derived from adult mouse cells.

The researchers first directed the stem cells to become ectodermal cells capable of responding to ear-inducing growth factors. They then subjected those so-called otic progenitor cells to varying differentiation conditions until they found one that led to the formation of cell clusters displaying hair cell-like characteristics. The key ingredients were chemicals known as a fibroblast growth factors or FGFs, which others had shown to be both sufficient and necessary for ear development.

The hair cell-like cells display all the markers associated with bona fide hair cells, they report. Closer examination of the cells under a scanning electron microscope showed that they were developing bundled structures highly reminiscent of the hair-like tufts of stereocilia that lend hair cells their name.

Most importantly, further study showed that the hair cell-like cells also respond to mechanical stimulation by producing currents like hair cells should. (Fluid inside the ear moves in response to vibration, setting hair cells in motion. Those sensory cells then convert that mechanical signal into an electrical one that is ultimately sent to the brain.)

The reprogrammed cells acted like immature, as opposed to adult, hair cells, they found. For instance, the cells responded with currents regardless of whether they were pushed or pulled; mature hair cells only work in one direction.

In addition to its promise for further scientific study, the new protocol could have clinical implications.

The fact that in vitro-generated hair cell-like cells display mechanosensitivity demonstrated that generation of replacement hair cells from pluripotent stem cells is feasible, a finding that justifies the development of stem cell-based treatment strategies for hearing and balance disorders, the researchers conclude.

Heller says that perhaps the most promising strategy for taking advantage of this new source for hair cells is high-throughput screening for drugs to awaken mammals' lost ability to regenerate hair cells in the way that other animals can.

For some reason, we've lost this mechanism but it must still be there somehow, Heller says. We need to find ways to activate it.




Advertise in this space for $10 per month. Contact us today.


Related Latest Research News


Subscribe to Latest Research Newsletter

Enter your email address:


 Feedback
For any corrections of factual information, to contact the editors or to send any medical news or health news press releases, use feedback form

Top of Page

 
Contact us

RxPG Online

Nerve

 

    Full Text RSS

© All rights reserved by RxPG Medical Solutions Private Limited (India)