Stem Cells Used To Reverse Paralysis In Animals
- Christopher
- Posts: 845
- Joined: Wed Jun 18, 2003 10:09 pm
- Injury Description, Date, extent, surgical intervention etc: Date of Injury: 12/15/02
Level of Injury:
-dominant side C5, C6, & C7 avulsed. C8 & T1 stretched & crushed
BPI Related Surgeries:
-2 Intercostal nerves grafted to Biceps muscle,
-Free-Gracilis muscle transfer to Biceps Region innervated with 2 Intercostal nerves grafts.
-2 Sural nerves harvested from both Calves for nerve grafting.
-Partial Ulnar nerve grafted to Long Triceps.
-Uninjured C7 Hemi-Contralateral cross-over to Deltoid muscle.
-Wrist flexor tendon transfer to middle, ring, & pinky finger extensors.
Surgical medical facility:
Brachial Plexus Clinic at The Mayo Clinic, Rochester MN
(all surgeries successful)
"Do what you can, with what you have, where you are."
~Theodore Roosevelt - Location: Los Angeles, California USA
Stem Cells Used To Reverse Paralysis In Animals
Just curious... what would you be willing to do or give to help initiate a cure?
http://www.sciencedaily.com/releases/20 ... 160933.htm
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Stem Cells Used To Reverse Paralysis In Animals
ScienceDaily (Jan. 28, 2009)
— A new study has found that transplantation of stem cells from the lining of the spinal cord, called ependymal stem cells, reverses paralysis associated with spinal cord injuries in laboratory tests. The findings show that the population of these cells after spinal cord injury was many times greater than comparable cells from healthy animal subjects. The results open a new window on spinal cord regenerative strategies.
The transplanted cells were found to proliferate after spinal cord injury and were recruited by the specific injured area. When these cells were transplanted into animals with spinal cord injury, they regenerated ten times faster while in the transplant subject than similar cells derived from healthy control animals.
Spinal cord injury is a major cause of paralysis, and the associated trauma destroys numerous cell types, including the neurons that carry messages between the brain and the rest of the body. In many spinal injuries, the cord is not actually severed, and at least some of the signal-carrying nerve cells remain intact. However, the surviving nerve cells may no longer carry messages because oligodendrocytes, which comprise the insulating sheath of the spinal cord, are lost.
The regenerative mechanism discovered was activated when a lesion formed in the injured area. After a lesion formed in the transplant subject, the stem cells were found to have a more effective ability to differentiate into oligodendrocytes and other cell types needed to restore neuronal function.
Currently, there are no effective therapies to reverse this disabling condition in humans. However, the presence of these stem cells in the adult human spinal cords suggests that stem cell-associated mechanisms might be exploited to repair human spinal cord injuries.
Given the serious social and health problems presented by diseases and accidents that destroy neuronal function, there is an ever-increasing interest in determining whether adult stem cells might be utilized as a basis of regenerative therapies.
“The human body contains the tools to repair damaged spinal cords. Our work clearly demonstrates that we need both adult and embryonic stem cells to understand our body and apply this knowledge in regenerative medicine,” says Miodrag Stojkovic, co-author of the study. “There are mechanisms in our body which need to be studied in more detail since they could be mobilized to cure spinal cord injuries.”
Journal reference:
1. Moreno-Manzano et al. Activated Spinal Cord Ependymal Stem Cells Rescue Neurological Function. Stem Cells, January 2009; DOI: 10.1002/stem.24
http://www.sciencedaily.com/releases/20 ... 160933.htm
======================================================
Stem Cells Used To Reverse Paralysis In Animals
ScienceDaily (Jan. 28, 2009)
— A new study has found that transplantation of stem cells from the lining of the spinal cord, called ependymal stem cells, reverses paralysis associated with spinal cord injuries in laboratory tests. The findings show that the population of these cells after spinal cord injury was many times greater than comparable cells from healthy animal subjects. The results open a new window on spinal cord regenerative strategies.
The transplanted cells were found to proliferate after spinal cord injury and were recruited by the specific injured area. When these cells were transplanted into animals with spinal cord injury, they regenerated ten times faster while in the transplant subject than similar cells derived from healthy control animals.
Spinal cord injury is a major cause of paralysis, and the associated trauma destroys numerous cell types, including the neurons that carry messages between the brain and the rest of the body. In many spinal injuries, the cord is not actually severed, and at least some of the signal-carrying nerve cells remain intact. However, the surviving nerve cells may no longer carry messages because oligodendrocytes, which comprise the insulating sheath of the spinal cord, are lost.
The regenerative mechanism discovered was activated when a lesion formed in the injured area. After a lesion formed in the transplant subject, the stem cells were found to have a more effective ability to differentiate into oligodendrocytes and other cell types needed to restore neuronal function.
Currently, there are no effective therapies to reverse this disabling condition in humans. However, the presence of these stem cells in the adult human spinal cords suggests that stem cell-associated mechanisms might be exploited to repair human spinal cord injuries.
Given the serious social and health problems presented by diseases and accidents that destroy neuronal function, there is an ever-increasing interest in determining whether adult stem cells might be utilized as a basis of regenerative therapies.
“The human body contains the tools to repair damaged spinal cords. Our work clearly demonstrates that we need both adult and embryonic stem cells to understand our body and apply this knowledge in regenerative medicine,” says Miodrag Stojkovic, co-author of the study. “There are mechanisms in our body which need to be studied in more detail since they could be mobilized to cure spinal cord injuries.”
Journal reference:
1. Moreno-Manzano et al. Activated Spinal Cord Ependymal Stem Cells Rescue Neurological Function. Stem Cells, January 2009; DOI: 10.1002/stem.24
Re: Stem Cells Used To Reverse Paralysis In Animals
Hello Christopher,
Thanks for posting the article...when will this be deemed safe for use on humans?
When my accident occurred I was traveling around the world and pursuing a career in photography...since the accident I have become a homebody and I am bored to death...it has been almost 5 months and scheduled to see Dr. Rochkind at the end of Feb for surgery and maybe laser treatment...
To answer your question, I would give anything for a sense of freedom...sign me up for any stem cell clinical trial!
Peace
Thanks for posting the article...when will this be deemed safe for use on humans?
When my accident occurred I was traveling around the world and pursuing a career in photography...since the accident I have become a homebody and I am bored to death...it has been almost 5 months and scheduled to see Dr. Rochkind at the end of Feb for surgery and maybe laser treatment...
To answer your question, I would give anything for a sense of freedom...sign me up for any stem cell clinical trial!
Peace