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Category: neuroscience – Page 771

Dr. Amilcar dos Santos MD — Exploring Far Frontiers of Neural, Spinal, and Brain-Computer Interfaces

Exploring the frontiers of neuromodulation, neurostimulation, and neural interfaces.

Neuromodulation is defined as “the alteration of nerve activity through targeted delivery of a stimulus, such as electrical stimulation or chemical agents, to specific neurological sites in the body”. It is carried out to normalize – or modulate – nervous tissue function.

Neuromodulation is an evolving therapy that can involve a range of electromagnetic stimuli such as a magnetic field, an electric current, or a drug instilled directly in the sub-dural space (i.e. intra-thecal drug delivery).

Emerging applications involve targeted introduction of genes or gene regulators and light (optogenetics), but most clinical experience has been with electrical stimulation.

Existing and emerging neuromodulation treatments also include application in medication-resistant epilepsy, chronic head pain conditions, and functional therapy ranging from bladder and bowel or respiratory control, to improvement of sensory deficits, such as hearing and vision.

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Scientists Invent a Microscope That Can Safely Look Straight Through Your Skull

A team of scientists has now found a way to create a clear image from scattered infrared light emitted from a laser, even after it’s passed through a thick layer of bone.

‘Our microscope allows us to investigate fine internal structures deep within living tissues that cannot be resolved by any other means,’ said physicists Seokchan Yoon and Hojun Lee from Korea University.

Seeing what the heck is going on inside of us is useful for many aspects of modern medicine. But how to do this without slicing and dicing through barriers like flesh and bone to observe living intact tissues, like our brains, is a tricky thing to do.

Thick, inconsistent structures like bone will scatter light unpredictably, making it difficult to figure out what’s going on behind them. And the deeper you wish to see, the more scattered light obscures fine and fragile biological structure.

There are plenty of options for researchers who are keen to watch living tissues do their thing, using clever optical tricks to turn scattered photons moving at certain frequencies into an image. But by risking tissue damage or operating only at shallow depths, they all have drawbacks.

Simulations open a new way to reverse cell aging

Simulations that model molecular interactions have identified an enzyme that could be targeted to reverse a called cellular senescence. The findings were validated with laboratory experiments on and equivalent tissues, and published in the Proceedings of the National Academy of Sciences (PNAS).

“Our research opens the door for a new generation that perceives aging as a reversible biological phenomenon,” says Professor Kwang-Hyun Cho of the Department of Bio and Brain engineering at the Korea Advanced Institute of Science and Technology (KAIST), who led the research with colleagues from KAIST and Amorepacific Corporation in Korea.

Cells respond to a variety of factors, such as oxidative stress, DNA damage, and shortening of the telomeres capping the ends of chromosomes, by entering a stable and persistent exit from the . This process, called cellular senescence, is important, as it prevents damaged from proliferating and turning into . But it is also a natural process that contributes to aging and . Recent research has shown that cellular senescence can be reversed. But the laboratory approaches used thus far also impair tissue regeneration or have the potential to trigger malignant transformations.

Drug reverses age-related cognitive decline within days

Just a few doses of an experimental drug can reverse age-related declines in memory and mental flexibility in mice, according to a new study by UC San Francisco scientists. The drug, called ISRIB, has already been shown in laboratory studies to restore memory function months after traumatic brain injury (TBI), reverse cognitive impairments in Down Syndrome, prevent noise-related hearing loss, fight certain types of prostate cancer, and even enhance cognition in healthy animals.

In the new study, published December 1, 2020 in the open-access journal eLife, researchers showed rapid restoration of youthful cognitive abilities in aged mice, accompanied by a rejuvenation of brain and that could help explain improvements in brain function.

“ISRIB’s extremely rapid effects show for the first time that a significant component of age-related cognitive losses may be caused by a kind of reversible physiological “blockage” rather than more permanent degradation,” said Susanna Rosi, Ph.D., Lewis and Ruth Cozen Chair II and professor in the departments of Neurological Surgery and of Physical Therapy and Rehabilitation Science.

Molecular mechanism of long-term memory discovered

Researchers at the University of Basel have discovered a molecular mechanism that plays a central role in intact long-term memory. This mechanism is also involved in physiological memory loss in old age.

Many , from worms to humans, have differentiated memory functions, such as short-term and long-term memory. Interestingly, at the cell and molecule level, many of these functions are nearly identical from life form to life form. Detecting the molecules involved in memory processes is of great importance to both basic and , since it can point the way to the development of drugs for memory disorders.

By studying roundworms (Caenorhabditis elegans), scientists at the Transfaculty Research Platform for Molecular and Cognitive Neurosciences (MCN) at the University of Basel have now discovered a of long-term memory that is also involved in memory loss in old age. They report on their findings in the journal Current Biology.