Imagine a world where damaged organs in your body, kidneys, liver, heart, can be stimulated to heal themselves.
Envision people tragically paralyzed whose injured spinal cords can be repaired. Think about individuals suffering from the debilitating effects of Parkinson's or Alzheimer's relieved of their symptoms, completely and permanently.
Dr. Samuel I. Stupp, director of the Institute of BioNanotechnology in Medicine at Northwestern University, is one of a new breed of scientists combining nanotechnology and biology to enable the body to heal itself -- and who are achieving amazing early results. Dr. Stupp's work suggests that nanotechnology can be used to mobilize the body's own healing abilities to repair or regenerate damaged cells.
In a dramatic demonstration of what nanotechnology might achieve in regenerative medicine, paralyzed lab mice with spinal cord injuries have regained the ability to walk using their hind limbs six weeks after a simple injection of a purpose-designed nanomaterial.
A video of Dr. Stupp discussing his groundbreaking research with collaborator John Kessler is available on April 24 at www.nanotechproject.org/114 .
"By injecting molecules that were designed to self-assemble into nanostructures in the spinal tissue, we have been able to rescue and regrow rapidly damaged neurons," said Dr. Stupp at an April 23 session hosted by the Project on Emerging Nanotechnologies. "The nanofibers, thousands of times thinner than a human hair, are the key to not only preventing the formation of harmful scar tissue which inhibits spinal cord healing, but to stimulating the body into regenerating lost or damaged cells."
Stupp's work hinges on a fundamental area of nanotechnology ,self-assembly, that someday should enable medical researchers to tailor and deliver individualized patient treatments in previously unimaginable ways. Stupp and his coworkers designed molecules with the capacity to self-assemble into nanofibers once injected into the body with a syringe. When the nanofibers form they can be immobilized in an area of tissue where it is necessary to activate some biological process, for example saving damaged cells or regenerating needed differentiated cells from stem cells.