Our brains are glowing. While this phenomenon isn’t visible to the naked eye, scientists have the ability to detect faint light that permeates the skull. Recent studies indicate that this light varies based on our activities.
All living tissues generate a subtle light known as Ultraweak Photon Emissions (UPE). This emission ceases once the organism dies. The human brain, however, emits a considerable amount of this light due to its high energy consumption, accounting for around 20% of the body’s total energy.
“Ultraweak photon emissions, or UPE, are extremely faint light signals produced by all types of cells throughout the body—trillions of times weaker than the light from bulbs,” stated Dr. Nirosha Murugan, an Assistant Professor of Health Sciences at Wilfrid Laurier University in Ontario, Canada. BBC Science Focus.
“Although UPE is a weak signal, the energy expenditure of the brain generates more light than other organs,” she explained. “Consider the hundreds of billions of brain cells; each one emits a weak light signal, but together they create a measurable collective glow outside the head.”
Murugan’s research team aimed to explore whether this glow fluctuated with brain activity and if it could be utilized to assess brain functions.
To investigate, scientists equipped participants with caps containing electrical sensors to track both electrical impulses and light emitted from the brain. Twenty adults were invited to sit in a darkened room.
Participants were directed to open and close their eyes and follow simple audio instructions.
Comparisons were made between the captured electrical signals and UPEs, revealing notable correlations.
“We discovered that the optical signals detected around the head correlate with electrical activity in the brain during cognitive tasks,” Murugan noted. “These patterns of light emission from the brain are dynamic, intricate, and informative.”
The brain emitted this light in a slow, rhythmic pattern, occurring less than once per second, creating the illusion of stability throughout the two-minute tasks.
Murugan indicated that measuring this brain light could offer scientists and medical professionals a novel method for brain imaging, potentially identifying conditions like epilepsy, dementia, and depression.
This light is not merely a by-product; it might also play a functional role in the brain. Murugan emphasized that examining it could “uncover hidden dimensions” of our cognitive processes.
“I hope that the possibility of detecting and interpreting light signals from the brain will inspire new questions previously deemed unfathomable,” she stated. “For instance, can UPEs permeate the skull and influence other brains within the vicinity?”
This study serves as a preliminary exploration, suggesting that plenty remains to be uncovered about our illuminating brains.
Nonetheless, Murugan expressed hope that the team’s discoveries will “ignite a new discussion regarding the significance of light in brain functionality.”
read more:
About our experts
Dr. Nirosha Murugan is an assistant professor in the Department of Health Sciences at Wilfrid Laurier University, Ontario, Canada. She was recently appointed as Tier 2 Canada Research Chair of Biophysics at the University of Algoma in Ontario.
Source: www.sciencefocus.com
