The snake detection theory, also sometimes called the snake detection hypothesis, suggests that snakes have contributed to the evolution of primates' visual system. According to the theory, predatory pressure from snakes has selected individuals who are better able to recognize them, improving their survival chances and therefore transferring such skill to their offspring. From this point of view, snakes were responsible for the modification and expansion of primate visual systems which made vision the most developed sensory interface with the external environment for modern primates. In her book The Fruit, the Tree, and the Serpent (2009), anthropologist Lynne Isbell writes that snakes evolved to be difficult to detect and mortally dangerous. Surviving the peril of snakes for millions of years required selective pressure favoring primates' specialized visual systems. Compared to that of other mammals, the pulvinar region of the brain – which helps to visually detect relevant objects – is disproportionately large and effective in the brains of primates (including humans).
The concept of snakes being a special threat to humans has been confirmed by population-based studies. Ophidiophobia (phobia of snakes) is one of the most common and intense phobias among the general population. Furthermore, a study reported that around 50% of people experience dreams about snakes.
Empirical studies
Many empirical studies have found evidence for the theory. Primates, including humans, are able to quickly detect snakes. Some studies have found that humans can detect snake images before subjective visual perception. However, the pre-conscious detection of snake stimuli is still under debate by the scientific community. Regardless, snakes images have been experimentally demonstrated to be detected more rapidly compared to other fear-relevant stimuli: empirical evidences have shown that snakes are more rapidly detected compared to spiders; according to the snake detection theory this is because the arachnids were, historically, a less relevant threat to primates. Snake stimuli are particularly distracting during perceptual tasks, suggesting that the brain preferentially processes snake stimuli, even when attentional processes are demanded by other targets. Enhanced snake detection has also been found in young children.
Brain imaging investigations have found further evidence for the theory. Support for the idea of a high visual sensitivity to snakes has been proven in primate neural activity in response to snake threats. Non-invasive electroencephalogram (EEG) studies have found an enhanced visual brain activity in response to images of snakes in humans.
References
- Isbell, Lynne A. (1 July 2006). "Snakes as agents of evolutionary change in primate brains". Journal of Human Evolution. 51 (1): 1–35. CiteSeerX 10.1.1.458.2574. doi:10.1016/j.jhevol.2005.12.012. PMID 16545427.
- Isbell, Lynne A. (2009). The Fruit, the Tree, and the Serpent. Harvard University Press. ISBN 9780674033016.
- Allman Updyke, Erin and Welsh, Erin (2022) . "Episode 97 Snake Venoms: Collateral Damage". This Podcast Will Kill You. Exactly Right Network.
- Isbell, Lynne A. (2009). The Fruit, the Tree, and the Serpent. Harvard University Press. ISBN 9780674033016.
- Sagan, Carl (26 September 2012). "Dragons of Eden: Speculations on the Evolution of Human Intelligence". Random House Publishing Group.
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