May 20, 2014
by Asnan Portal
Researchers in The University of Adelaide brought a new hope for stroke patients since they have discovered that stem cells taken from teeth can grow to resemble brain cells, suggesting they could one day be used in the brain as a therapy for stroke
In the University’s Centre for Stem Cell Research, laboratory studies have shown that stem cells from teeth can develop and form complex networks of brain-like cells. Although these cells haven’t developed into fully fledged neurons, researchers believe it’s just a matter of time and the right conditions for it to happen.
Dr Kylie Ellis, Commercial Development Manager with the University’s commercial arm Adelaide Research & Innovation (ARI) says : (Stem cells from teeth have great potential to grow into new brain or nerve cells, and this could potentially assist with treatments of brain disorders, such as stroke )
Dr Ellis conducted this research as part of her Physiology PhD studies at the University, before making the step into commercialisation. The results of her work have been published in the journal Stem Cell Research & Therapy.
(For the time being treatment options available to the thousands of stroke patients every year are limited,) Dr Ellis says. “The primary drug treatment available must be administered within hours of a stroke and many people don’t have access within that timeframe, because they often can’t seek help for some time after the attack.
This method is unique since we want to be able to use a patient’s own stem cells for tailor-made brain therapy that doesn’t have the host rejection issues commonly associated with cell-based therapies. Another advantage is that dental pulp stem cell therapy may provide a treatment option available months or even years after the stroke has occurred,” she says.
As part of this research Dr Ellis found that stem cells derived from teeth developed into cells that closely resembled neurons.Dr Ellis and her colleagues, Professors Simon Koblar, David O’Carroll and Stan Gronthos, have been working on a laboratory-based model for actual treatment in humans
“We can do this by providing an environment for the cells that is as close to a normal brain environment as possible, so that instead of becoming cells for teeth they become brain cells
The new cells shared very similar properties to neurons, but thry wasn’t idrntical to normal neurons . They also formed complex networks and communicated through simple electrical activity, like you might see between cells in the developing brain.”
This work with dental pulp stem cells opens up the potential for modelling many more common brain disorders in the laboratory, which could help in developing new treatments and techniques for patients.