By Muhammad Mubbashir Sheikh MD, Mohamad Z. Koubeissi MD, Dennis D. Spencer MD, and Rafeed Alkawadri MD

Results can be viewed here. Ann Neurol. 2021 Nov 28. doi: 10.1002/ana.26277. Online ahead of print.

According to relativity, the faster you move, the slower you perceive time and vice versa. For example: if we jumped inside a rocket ship and traveled near light speed for ten years traveling away from the earth only to return to the world ten years older than when we left, but our friends back on Earth will have aged 20 years since we left. This relativity of time is complex for regular human beings to understand because we generally don't experience it in our day-to-day lives story of paradoxes. The 4-D simplification of space-time warp and the simplification of equations has helped in that sense. The absence of distinct organs for time perception humans might add to the perplexity of comprehending physical time. For instance, time perception has been evolved in the physical sense across cultures and pre-and post-industrial revolutions.

In the most basic evolutionary sense, time perception roots in the circadian/seasonal cycles and the quick motor decisions that may make the difference between perishing and survival. Consistently, the notion of time has been an intrinsic part of many civilizations. For instance, the Egyptians did not have a god of time; however, their iconography illustrates their conception of time. Parmenides in the 5th century BC held that time is a figment of the imagination. The experience of time has always been a persistent challenge, reflecting a theoretical approach applied to the western philosophical tradition, stating that time is a construction of the self, according to the assessment of St Augustine’s. Many cultures appraised time; “The time is a master of him who does not have a master” and “Time waits for no one” are simply examples of a long list of such didacticism.

To that end, we reported in Annals of Neurology on a profound illusionary alteration of time and duration perceptions during direct electrical cortical stimulation for functional mapping. We analyzed the cortical and subcortical networks relating to that experience. To our knowledge, this account is the first original of a human’s understanding of time dilation during direct cortical stimulation.

Our findings suggest

1. Right hemispheric contribution to time perception in humans has also been proposed by lesional studies.

2. There is a hierarchal view of time perception in humans. At the highest level, it depends on integrating multiple neural systems emerging from various motor sensory (seconds) and executive networks (minutes). The right mid-claustrum/insula and the inferior frontal lobe regions may play the role of a pacemaker interacting with the accumulators spanning large neocortical (working memory) and mesial temporal regions (memory time cells).

3. That level of complexity and pace helps explain the variability in time interval interpretation perception: e.g., pre and post-industrial revolution, cross-culture, the difference between boredom and fun, diseases such as Parkinson's, ADHD, and drug use.

More to follow.