XML Feed for RxPG News   Add RxPG News Headlines to My Yahoo!   Javascript Syndication for RxPG News

Research Health World General
 
  Home
 
 Latest Research
 Cancer
 Psychiatry
 Genetics
 Surgery
 Aging
 Ophthalmology
 Gynaecology
 Neurosciences
  Memory
  Regeneration
  Stroke
  Brain Diseases
  Headache
  Spinal Cord Diseases
  Demyelinating Diseases
  Neurodegenerative Diseases
  Taste
  Trigeminal Neuralgia
 Pharmacology
 Cardiology
 Obstetrics
 Infectious Diseases
 Respiratory Medicine
 Pathology
 Endocrinology
 Immunology
 Nephrology
 Gastroenterology
 Biotechnology
 Radiology
 Dermatology
 Microbiology
 Haematology
 Dental
 ENT
 Environment
 Embryology
 Orthopedics
 Metabolism
 Anaethesia
 Paediatrics
 Public Health
 Urology
 Musculoskeletal
 Clinical Trials
 Physiology
 Biochemistry
 Cytology
 Traumatology
 Rheumatology
 
 Medical News
 Health
 Opinion
 Healthcare
 Professionals
 Launch
 Awards & Prizes
 
 Careers
 Medical
 Nursing
 Dental
 
 Special Topics
 Euthanasia
 Ethics
 Evolution
 Odd Medical News
 Feature
 
 World News
 Tsunami
 Epidemics
 Climate
 Business
Search

Last Updated: Aug 19th, 2006 - 22:18:38

Regeneration Channel
subscribe to Regeneration newsletter

Latest Research : Neurosciences : Regeneration

   DISCUSS   |   EMAIL   |   PRINT
Nerve regeneration is possible in spinal cord injuries
Dec 4, 2005, 10:41, Reviewed by: Dr.

"These findings give us hope. The nervous system is capable of being modified to a level where we can achieve nerve fiber growth. Ultimately, the goal is to promote growth and sustain it long enough for recovery of movement to occur in spinal cord injury patients"

 
A team of scientists at UCSF has made a critical discovery that may help in the development of techniques to promote functional recovery after a spinal cord injury.

By stimulating nerve cells in laboratory rats at the time of the injury and then again one week later, the scientists were able to increase the growth capacity of nerve cells and to sustain that capacity. Both factors are critical for nerve regeneration.

The study, reported in the November 15 issue of the Proceedings of the National Academy of Sciences, builds on earlier findings in which the researchers were able to induce cell growth by manipulating the nervous system before a spinal cord injury, but not after.

Key to the research is an important difference in the properties of the nerve fibers of the central nervous system (CNS), which consists of the brain and spinal cord, and those of the peripheral nervous system (PNS), which is the network of nerve fibers that extends throughout the body.

Nerve cells normally grow when they are young and stop when they are mature. When an injury occurs in CNS cells, the cells are unable to regenerate on their own. In PNS cells, however, an injury can stimulate the cells to regrow. PNS nerve regeneration makes it possible for severed limbs to be surgically reattached to the body and continue to grow and regain function.

Regeneration occurs because PNS cell bodies are sensitive to damage to their nerve processes, and they react by sending out a signal that triggers the nerve fibers to regrow, explains Allan Basbaum, PhD, senior study author and chair of the UCSF Department of Anatomy. "Apparently this communication doesn't take place within the CNS."

Scientists do not yet know the biochemical cause for the difference, he adds.

The traditional scientific approach in efforts to enhance CNS regeneration is to manipulate the biochemical environment of the cells at the site of the spinal cord injury, according to Basbaum. Instead of this type of investigation, Basbaum's team used nervous system manipulation techniques to apply the principles of PNS cell growth capability to CNS cells.

The researchers took advantage of an unusual class of nerve fibers that has both a PNS and a CNS branch. Previously, the researchers had shown in animal studies that an injury made to the peripheral branch prior to a spinal cord injury provided the essential communication signal that enabled the CNS branch to grow. But this only worked if the PNS injury--which served as priming for CNS cell growth--was made at least a week before the CNS injury. "Clearly this would have no utility in clinical situations, where treatments cannot be made in anticipation of spinal cord injury," says Basbaum. Another challenge the researchers faced was stimulating CNS cells to grow beyond the injury site and into healthy tissue, which is essential to help regain function.

"A PNS injury at the time of spinal cord damage will only promote growth of nerve fibers into the spinal cord lesion, but not into the tissue beyond it. This is because growth capacity is enhanced, but it is not sustained," he explains. In the new study, researchers evaluated the effect of two peripheral nerve lesions (injuries) in animals with spinal cord injury. One lesion was made at the time of the cord injury and a second was made a week later. Both lesions were located in the animals' sciatic nerve, which is part of the PNS.

The researchers found that the two "priming lesions" not only promoted significant spinal cord regeneration within the area of the spinal cord injury, but more important, the regenerating axons grew back into normal areas of the spinal cord, where the hope is that functional connections can be reestablished. Axons are the long, fragile, fibers that conduct impulses between nerve cells in the brain, spinal cord and limbs.

"Getting the growth beyond the lesion is key. If we can get those axons to grow even a few centimeters past the lesion, they can start sending signals and developing new circuits throughout the body," says Basbaum. Basbaum adds that timing is critical for successful nerve regeneration. "There is a window of opportunity just after the injury when the potential for growth through and beyond the lesion is greatest. If we wait too long after an injury, the cells revert back to their normal, no-growth state. Plus, scar tissue begins to form, making growth difficult." "These findings give us hope. The nervous system is capable of being modified to a level where we can achieve nerve fiber growth. Ultimately, the goal is to promote growth and sustain it long enough for recovery of movement to occur in spinal cord injury patients," he concludes. Study co-authors include first-author Simona Neumann, PhD, and Kate Skinner, MD, both of UCSF. The research was funded by the Roman Reed Spinal Cord Injury Research Fund of California and the National Institutes of Health.

 

- November 15 issue of the Proceedings of the National Academy of Sciences
 

www.ucsf.edu

 
Subscribe to Regeneration Newsletter
E-mail Address:

 

UCSF is a leading university that consistently defines health care worldwide by conducting advanced biomedical research, educating graduate students in the life sciences, and providing complex patient care.



Related Regeneration News

Severed nerve fibers in spinal cord can regenerate for long distances
Common brain cells may have stem-cell-like potential
Using Embryonic Stem Cells to Awaken Latent Motor Nerve Repair
Understanding how axons find their destinations
Novel stem cell technology leads to better spinal cord repair
Myosin-II: A new focus for the mechanism of nerve growth
Structural remodeling of neurons demonstrated in mature brains
How "baby" neurons are integrated into brain
Nerve regeneration is possible in spinal cord injuries
Silenced smedwi-2 gene shows role in regeneration


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

 

© Copyright 2004 onwards by RxPG Medical Solutions Private Limited
Contact Us