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Thursday, November 15, 2018

New advanced biomaterial to repair damaged nervous tissue

November 14, 2018, Universidad Politécnica de Madrid


Fluorescence microscopy images showing stem cells (green) implanted in a brain tissue (blue). The four figures at the right show the survival of non-encapsulated stem cells, and the figures at the right show the silk fibroin hydrogels-encapsulated stem cells. Credit: Front Cell Neurosci. 2018 Sep 6;12:296. doi: 10.3389/fncel.2018.00296


A team of researchers from the Centre for Biomedical Technology (CTB) at Universidad Politécnica de Madrid (UPM) in collaboration with the Universidad Complutense de Madrid (UCM), the Instituto Cajal and the Hospital Clínico San Carlos has developed an innovative treatment to repair damaged brain tissues. Thanks to the implantation of encapsulated stem cells in an innocuous biomaterial and fully biocompatible (silk fibroin), researchers have achieved the functional recovery of mice after suffering an induced brain stroke.
This encapsulation can increase the survival rate of stem  implanted in the  and, in addition to positively influencing the repair of damaged nerve tissue, it can prevent the extent of the damage.
A wide range of neurological disorders can cause permanent physical and cognitive disabilities. The nervous system has a limited capacity to recover after an injury, for instance after a stroke or brain trauma but also in neurodegenerative diseases such as Alzheimer's or Parkinson's in which there is a progressive deterioration of our brain.
Stem cell therapies have the therapeutic potential to protect and repair the damaged brain. However,  has difficulties, including a reduced survival rate in the brain after transplant. This a barrier to achieving the most suitable therapy.
In order to overcome this barrier, a team led by researchers from the Centre for Biomedical Technology, in collaboration with UCM, the Instituto Cajal and the Hospital Clínico San Carlos, has developed an innovative bioengineering strategy to repair the damaged brain tissue. To do this, the researchers implanted  encapsulated in fully biocompatible silk fibroin into mice with brain infarctions.
After the treatment, the mice experienced a significant improvement in their sensory and motor skills. Additionally, by using electrophysiological techniques, the researchers have shown improvement of brain reorganization in adjacent areas to the damaged zone. Silk fibroin considerably increased the survival of  implanted in the brain, preventing an extent of the damage after de induced stroke in animals.
Daniel González Nieto, a CTB-UPM researcher, says, "These results are a step forward in new treatments of neurologic disorders when using silk fibroin as a drug delivery vehicle, achieving a higher therapy performance and the functional improvement of patients."
More information: Laura Fernández-García et al. Cortical Reshaping and Functional Recovery Induced by Silk Fibroin Hydrogels-Encapsulated Stem Cells Implanted in Stroke Animals, Frontiers in Cellular Neuroscience(2018). DOI: 10.3389/fncel.2018.00296 

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