Protecting the brain when energy runs low

 by Biomechanism 

Researchers from the Universities of Leeds, Edinburgh and Dundee have shed new light on the way that the brain protects itself from harm when ‘running on empty.’

The findings could lead to new treatments for patients who are at risk of stroke because their energy supply from blood vessels feeding the brain has become compromised.

Many regions of the brain constantly consume as much energy as leg muscles during marathon running. Even when we are sleeping, the brain needs regular fuel.

Much of this energy is needed to fire up ‘action potentials’, tiny electrical impulses that travel along nerve cells in the brain. These electrical impulses trigger the release of chemical messages at nerve endings, allowing the brain to process information and control bodily functions.

Normally, the bloodstream supplies enough glucose and oxygen to the brain to generate the large amount of energy required for these action potentials to be fired up. But things can go wrong if the blood vessels feeding the brain become narrowed or blocked, restricting the supply of vital nutrients.

A team led jointly by Professors Chris Peers (Leeds), Mark Evans (Edinburgh) and Grahame Hardie (Dundee) has now identified a way for the brain to protect itself when its energy supply is running low. This protective strategy, which is triggered by a protein known as AMPK, reduces the firing frequency of electrical impulses, conserving energy.

The energy-sensing protein AMPK was first discovered by Professor Graham Hardie of the University of Dundee. He said: “When we first defined the AMPK system by studying fat metabolism in the liver back in the 1980s, we had no idea that it might regulate completely different functions in other organs, like nervous conduction in the brain.”

“There are drugs currently on the market that stimulate AMPK, which are used to treat other conditions. In future these and other drugs could be given to at-risk patients to give them a better chance of surviving a stroke.”

Professor Chris Peers, of the University of Leeds’ School of Medicine, said: “Our new findings suggest that if brain cells run short of energy, they start to work more slowly. However, it is better to work slowly than not at all. It is possible that this discovery could, in the long term, lead to new treatments for patients who have problems with circulation to the brain, placing them at higher risk of conditions such as stroke.”

“This research is a good example of what can happen if you pool the expertise of research groups who work in different areas.”

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Full details of the work are published in the Proceedings of the National Academy of Sciences.

For more information:

1. The paper, Ikematsu et al, Phosphorylation of the voltage-gated potassium channel Kv2 :1 by AMP-activated protein kinase, is published in the Proceedings of the National Academy of Sciences[doi/10.1073/pnas.1106201108].

NJIT researcher testing micro-electronic stimulators for spinal cord injuries

 by Biomechanism 

A new wireless device to help victims of spinal cord injury is receiving attention in the research community. Mesut Sahin, PhD, associate professor, in the department of biomedical engineering at NJIT, recently has published and presented news of his findings to develop micro-electrical stimulators for individuals with spinal cord injuries.

Caption: Mesut Sahin, a bioengineer at NJIT, works on developing and testing an embedded micro-electrical stimulator for people with spinal cord injuries. Credit: NJIT

The work, now in its third year of support from a four-year, $1.4 million National Institutes of Health (NIH) grant, has resulted in the development and testing of a technology known by its acronym, FLAMES (floating light activated micro-electrical stimulators). The technology, really a tiny semiconductor device, will eventually enable people with spinal cord injuries to restore some of the motor functions that are lost due to injury. Energized by an infrared light beam through an optical fiber located just outside the spinal cord these micro-stimulators will activate the nerves in the spinal cord below the point of injury and thus allow the use of the muscles that were once paralyzed.

“Our in vivo tests suggest that the FLAMES can be used for intraspinal micro-stimulation even for the deepest implant locations in the rat spinal cord,” said Sahin.

“The power required to generate a threshold arm movement was investigated as the laser source was moved away from the micro-stimulator. The results indicate that the photon density does not decrease substantially for horizontal displacements of the source that are in the same order as the beam radius. This gives confidence that the stimulation threshold may not be very sensitive to small displacement of the spinal cord relative to the spine-mounted optical power source.” Sahin spoke about this work at the IEEE Engineering in Medicine and Biology Conference in Boston, also in September of 2011.

FLAMES is a semiconductor device that is remotely controlled by an optical fiber attached to a low power near-infrared laser. The device is implanted into the spinal cord, and is then allowed to float in the tissue. There are no attached wires. A patient pushes a button on the external unit to activate the laser, the laser then activates the FLAMES device.

“The unique aspect of the project is that the implanted stimulators are very small, in the sub-millimeter range,” Sahin said. “A key benefit is that since our device is wireless, the connections can’t deteriorate over time plus, the implant causes minimal reaction in the tissue which is a common problem with similar wired devices.”

The electrical activation of the central and peripheral nervous system has been investigated for treatment of neural disorders for many decades and a number of devices have already successfully moved into the clinical phase, such as cochlear implants and pain management via spinal cord stimulation. Others are on the way, such as micro stimulation of the spinal cord to restore locomotion, micro stimulation of the cochlear nucleus, midbrain, or auditory cortex to better restore hearing and stimulation of the visual cortex in the blind subject. All of them, however, are wired, unlike FLAMES, which is not.

Selim Unlu, professor of electrical and computer engineering at Boston University, is working with Sahin. “We hope that once FLAMES advances to the clinical stage, patients paralyzed by spinal injury will be able to regain vital functions,” Sahin said.

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NJIT, New Jersey’s science and technology university is internationally recognized for being at the edge in knowledge in architecture, applied mathematics, wireless communications and networking, solar physics, advanced engineered particulate materials, nanotechnology, neural engineering and e-learning. Many courses and certificate programs, as well as graduate degrees, are available online through the Office of Continuing Professional Education.

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