Lifeboat Foundation

Past neuroscience research consistently found a link between deviations from the “normal” iron metabolism, also known as iron dysregulation, and different neurodegenerative diseases, including Parkinson’s disease (PD) and Multiple Sclerosis (MS). Specifically, brain regions associated with these diseases have been found to be often populated by microglia (i.e., resident immune cells) packed with Iron.

While the association between iron dysregulation and neurodegenerative diseases is well documented, the ways in which iron accumulation affects the physiology of microglia and neurodegeneration are yet to be fully grasped. Researchers at global health care company Sanofi have recently carried out a study aimed at filling this gap in the literature, by better understanding how microglia respond to iron.

“For years it has been known that iron accumulates in affected brain regions in PD, MS and other neurodegenerative diseases,” Timothy Hammond, one of the researchers who carried out the study, told MedicalXpress. “This is something we can see in patients using MRI imaging, where it has been shown that iron levels increase over the course of the disease. We also had our own data from progressive MS patients showing iron dysregulation in brain microglia, the resident immune cells of the brain.”

A recent neuroimaging study has identified a link between respiration and neural activity changes in rats. The findings, which have been published in the journal eLife, suggest that breathing might modulate neural responses across the brain.

“Breathing is an essential physiologic process for a living organism,” said study author Nanyin Zhang, the Lloyd & Dorothy Foehr Huck Chair in Brain Imaging and director of the Center for Neurotechnology in Mental Health Research at Penn State.

“Scientists know that respiration is controlled by the brain stem, and the breathing process can modulate neural activity changes in several brain regions. However, people still do not have a comprehensive picture about brain-wide regions involved during breathing. This question can in principle be answered using a technique called functional magnetic resonance imaging (fMRI), a non-invasive neuroimage method that allows us to map neural activity in the whole brain.”

Gene therapies have the potential to treat neurological disorders like Alzheimer’s and Parkinson’s diseases, but they face a common barrier—the blood-brain barrier. Now, researchers at the University of Wisconsin-Madison have developed a way to move therapies across the brain’s protective membrane to deliver brain-wide therapy with a range of biological medications and treatments.

“There is no cure yet for many devastating brain disorders,” says Shaoqin “Sarah” Gong, UW-Madison professor of ophthalmology and visual sciences and biomedical engineering and researcher at the Wisconsin Institute for Discovery. “Innovative brain-targeted delivery strategies may change that by enabling noninvasive, safe and efficient delivery of CRISPR genome editors that could, in turn, lead to genome-editing therapies for these diseases.”

CRISPR is a molecular toolkit for editing genes (for example, to correct mutations that may cause disease), but the toolkit is only useful if it can get through security to the job site. The blood-brain barrier is a membrane that selectively controls access to the brain, screening out toxins and pathogens that may be present in the bloodstream. Unfortunately, the barrier bars some beneficial treatments, like certain vaccines and gene therapy packages, from reaching their targets because in lumps them in with hostile invaders.

A study conducted in Brazil and reported in an article published in Molecular Psychiatry suggests that schizophrenia may be associated with alterations in the vascularization of certain brain regions. Researchers at the State University of Campinas (UNICAMP), D’Or Research and Education Institute (IDOR) and the Federal University of Rio de Janeiro (UFRJ) found a link between astrocytes (central nervous system cells) from patients with schizophrenia and formation of narrow blood vessels.

Schizophrenia is a severe multifactorial mental health disorder affecting around 1% of the world population. Common symptoms include loss of contact with reality (psychosis), hallucinations (hearing voices, for example), delusions or delirium, disorganized motor behavior, loss of motivation and cognitive impairment.

In the study, the researchers focused on the role of astrocytes in development of the disease. These glial cells are housekeepers of the central nervous system and important to its defense. They are the central elements of the neurovascular units that integrate neural circuitry with local blood flow and provide neurons with metabolic support.

Michael Levin is an American developmental and synthetic biologist at Tufts University. His research interests include: bioelectrical signals by which cells communicate to serve the dynamic anatomical needs of the organism during development, regeneration, and cancer suppression; basal cognition and intelligence in diverse unconventional substrates; and top-down control of form and function across scales in biology.

Join us as we discuss.
- Bioelectricity.
- Regeneration.
- The future in medicine.
- The act of free will and more.

Continue reading “Rekindi #29 — Bioelectricity, Regeneration, Cancer Suppression & Xenobots — with Michael Levin” »

Our ability to learn, move, and sense our world comes from the neurons in our brain. This information moves through our brain between neurons that are linked together by tens of trillions of tiny structures called synapses. Although tiny, synapses are not simple and must be precisely organized to function properly. Indeed, diseases like autism and Alzheimer’s are increasingly linked to defects in the organization and number of these tiny structures. Now researchers at Thomas Jefferson University have found a new way in which synapses organization is controlled, which could eventually lead to better treatments for neurological diseases.

Researchers who study how synapses grow and are lost have long focused on a molecule called PSD-95, which helps create and maintain the scaffolding around which a synapse is built. A new paper, publishing in Nature Neuroscience October 19th, reveals that a second protein interacts with PSD-95 and enables adaptive changes, such as changes in sensation, to be translated into changes in the synaptic scaffold, changing the amount of PSD-95 at the synapse.

“We can’t see or learn or talk without synapses working properly,” says senior author Matthew Dalva, Ph.D., Associate Professor of Neuroscience at the Sidney Kimmel Medical College at Thomas Jefferson University and the Farber Institute of Neuroscience at Jefferson and leader of the Theme Team for Synapse Biology. “We need a better understanding of how the brain works normally in order to develop a better sense of where to intervene to stop or cure diseases of the brain. It’s important to understand how these molecules interact.”

In this Review, Villeda and colleagues describe blood-to-brain communication from a systems physiology perspective, with an emphasis on blood-derived signals as potent drivers of both age-related brain dysfunction and brain rejuvenation.

Scientists who watched nerve cells connect inside the eyes of growing squid have uncovered a remarkable secret — the cephalopods’ brains independently evolved to develop in the same way ours do.

.The discovery, made using high-resolution cameras focused on the retinas of longfin squid (Doryteuthis pealeii) embryos, reveals that, in spite of 500 million years of divergent evolution, the basic blueprint for how complex brains and nervous systems evolve may be the same across a wide range of species.

The intelligence of cephalopods — a class of marine animals that includes octopuses, squid and cuttlefish — has long been a subject of fascination among biologists. Unlike most invertebrates, these animals possess remarkable memories; use tools to solve problems; excel at camouflage; react with curiosity, boredom or even playful malevolence to their surroundings; and can dream, if the ripples of colors that flash across their skin as they sleep are any indication.

Continue reading “Squid and human brains develop the same way despite diverging 500 million years ago” »

The inside of a person’s mouth can say a lot about their overall health. Studies have established links between poor oral health and conditions like heart disease, high blood pressure and pneumonia. Now, a new study shows there’s a connection to the brain. Researchers in the U.K. found certain bacteria in the mouth may cause deadly brain abscesses.