Researchers have discovered that the human visual cortex contains eight distinct “body maps” that translate observed actions into simulated touch sensations. According to a study published November 26, 2025, in Nature, this neural mirroring allows the brain to experience empathy by mapping the physical movements of others onto internal sensory templates. This mechanism helps explain why watching someone else get hurt can trigger an involuntary physical flinch.
How the brain translates sight into touch
The human brain does not merely record visual data like a camera; it actively interprets it through the somatosensory cortex. Lead researcher Nicholas Hedger and senior author Tomas Knapen, both associated with the Netherlands Institute for Neuroscience, led the investigation into how this process functions. By analyzing brain scans of volunteers watching Hollywood films like The Social Network, the team identified organized patterns in the visual cortex that mirror the body’s physical layout.
In the somatosensory cortex, specific regions correspond to distinct body parts—a concept known as a homunculus. The discovery of eight similar, parallel maps within the visual cortex suggests that the brain uses these internal templates to “feel” what it sees. This alignment allows the brain to rapidly process whether a person is reaching for an object or expressing an emotion, according to the research published in Nature.
The brain’s reliance on these maps is highly flexible. Researchers believe that by maintaining multiple, overlapping maps, the brain can prioritize different information—such as limb movement versus facial expression—depending on the social context of the moment.
Why do we have multiple body maps?
The existence of eight separate maps suggests a highly specialized system for social cognition. While the research is ongoing, Knapen suggests that these maps act as a “fundamental ingredient” for social interaction. By shifting focus between these maps, the brain can extract specific details about a person’s state, such as their physical posture or the intensity of their emotional expression.
This multi-map system provides a contrast to simpler, single-layer neural models. Rather than being inefficient, the redundancy allows for high-speed “bodily translations.” When you watch a friend cut their finger, your brain uses these visual maps to immediately simulate the sensation of pain, facilitating the empathetic response required for social bonding.
Future applications in medicine and AI
The identification of these maps could shift how scientists approach neurotechnology and mental health. For individuals with autism, who may experience challenges in social processing, these findings offer a new biological framework for understanding those difficulties. Knapen notes that identifying these neural mechanisms could eventually lead to more targeted clinical interventions.
The implications extend to artificial intelligence as well. Current AI models are largely limited to processing text and video without a “bodily dimension.” Integrating these findings into machine learning could allow for more empathetic AI systems. By training algorithms on brain-imaging datasets that capture how humans physically “feel” visual information, developers may be able to bridge the gap between digital processing and human-like social awareness.
Frequently Asked Questions
Why do I flinch when I see someone else get hurt?
Your visual cortex uses “body maps” to translate the sight of an injury into a simulated touch experience in your somatosensory cortex, causing an involuntary reaction.
Are these body maps only for pain?
No. According to the research, these maps translate various visual inputs, including posture, facial expressions, and complex limb movements.
Could this help in treating autism?
Researchers suggest that because these maps are central to social processing, understanding them could help identify new, more effective therapies for social-cognitive differences.
What are your thoughts on how our brains “feel” the world around us? Join the conversation in the comments below or subscribe to our newsletter for more updates on the latest in neuroscience.
