Scientists create artificial nerve cell connections with plastic beads
October 8th, 2009 - 1:49 pm ICT by ANIWashington, Oct 8 (ANI): In a breakthrough study, scientists have successfully created nerve cell connections with the help of artificial substances, a major advance, which the researchers say, will help make nerve cell repair possible.
Scientists from Montreal NeurologicaI Institute and Hospital (The Neuro) and McGill University created the artificial nerve cell connections using plastic beads coated with a substance that encourages adhesion, and attracts nerve cells.
“Many therapies, most still in the conceptual stage, are aimed at restoring the connection between the nerve cell and the severed nerve fibres that innervate a target tissue, typically muscle,” said Dr. David Colman, Director of The Neuro and principal investigator in the study.
“Traditional approaches to therapies would require the re-growth of a severed nerve fibre a distance of up to one meter in order to potentially restore function.
“The approach we are using however bypasses the need to force nerve cells to artificially grow these long distances, and eliminates the demand for two neurons to make a synapse, both of which are considerable obstacles to neuronal repair in a damaged system,” he added.
The novel approach will help healthy nerve cells form functional contacts with artificial substrates in order to create a paradigm that can be adapted to model systems in which neurons are damaged.
It will be combined with strategies to encourage the outgrowth of damaged neuronal branches through which these connections, or synapses, are formed.
The synapses generated in this study are virtually identical to their natural counterparts except the ‘receiving’ side of the synapse is an artificial plastic rather than another nerve cell or the target tissue itself.
“Even though components of synapses have been induced in similar earlier studies, their functionality was not proven. In order to assess function - that is transmission of a signal from the synapse, we stimulated the nerve cells with electricity, sending the signal, an action potential, to the synapse.
“By artificially stimulating nerve cells in the presence of dyes, we could see that transmission had taken place as the dyes were taken up by the synapses.
“We believe that within the next five years we will have a fully functional device that will be able to directly convey natural nerve cell signals from the nerve cell itself to an artificial matrix containing a mini-computer that will communicate wirelessly with target tissues,” Colman added.
The study appears in Journal of Neuroscience. (ANI)
- Protein key to storing long-term memories - Jan 29, 2012
- Elusive memory molecule identified - Jun 27, 2011
- Gene therapy boosts cell repair in brain disorders - Feb 12, 2012
- Protein that keeps neuro signals intact offers clue into brain disorders - Mar 15, 2011
- Technique 'poised to untangle brain's complexity' developed - Apr 11, 2011
- New discovery sheds light on mechanisms underlying Parkinson's - Feb 10, 2010
- Temporary changes in brain speed up learning - Apr 14, 2011
- New discovery may lead to advances in treating anxiety disorders - Jan 08, 2011
- New prosthetics to restore feeling in amputees - Oct 26, 2009
- Scientists create synthetic brain cell - Apr 25, 2011
- Exercise, caloric restriction may delay debilitating effects of aging - Aug 03, 2010
- Nerve-cell transplants help recover lost ability to learn in brain-damaged rats - Dec 10, 2009
- New finding may shed light on drug abuse and depression - Apr 25, 2011
- Scientists convert skin cells into nerve cells - Jan 28, 2010
- Invisible infrared light could soon activate heart, ear cells - Mar 28, 2011
Tags: artificial substances, breakthrough study, conceptual stage, david colman, long distances, mcgill university, model systems, natural counterparts, nerve cell connections, nerve cells, nerve fibre, nerve fibres, neurons, novel approach, plastic beads, principal investigator, synapse, synapses, target tissue, traditional approaches