The Seventh Sense: Exploring the Science of Remote Touch in Humans
For centuries, humans have spoken of the five senses—sight, hearing, taste, smell, and touch—as the complete toolkit through which we understand the world. Later, science acknowledged additional senses such as balance (vestibular sense) and body position (proprioception). Now, a groundbreaking discovery by scientists at Queen Mary University of London suggests that humans may possess an even more extraordinary ability: a seventh sense known as “remote touch.”
This newly identified phenomenon challenges long-standing assumptions about human perception. Remote touch refers to the ability to detect objects without direct physical contact, particularly those buried beneath surfaces such as sand, soil, or soft ground. Rather than relying on sight or touch in the traditional sense, the human nervous system appears capable of sensing subtle pressure variations and resistance patterns transmitted through materials.
What Is Remote Touch?
Remote touch is not about supernatural powers or extrasensory perception. Instead, it is deeply biological. When a person moves their hand or foot over a surface like sand, the material subtly shifts. These shifts create minute vibrations and pressure changes that travel through the surface. Hypersensitive nerve endings—especially in the fingertips and soles of the feet—pick up these micro-signals.
The brain then processes this information, translating it into spatial awareness: an understanding of what lies beneath the surface, where it is, and sometimes even its shape or density. In essence, the body “feels” objects indirectly through the environment.
A Skill Rooted in Evolution
Interestingly, this ability is not unique to humans. Coastal birds, for example, use similar mechanisms to locate prey buried under sand or mud. By sensing pressure changes and resistance through their beaks, they can pinpoint hidden food with astonishing accuracy.
What surprised researchers is that humans may possess an even more refined version of this ability. While modern humans rarely rely on such skills in daily life, our evolutionary ancestors likely depended on them for survival—finding food, avoiding danger, or navigating unfamiliar terrain.
Over time, as tools and technology replaced the need for such sensory precision, this ability became largely unconscious. Yet, according to the research, it never disappeared.
How the Nervous System Makes It Possible
The human skin is home to millions of sensory receptors, many of which are concentrated in the fingertips. These receptors are capable of detecting:
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Micro-pressure differences
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Resistance changes in materials
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Vibrations at extremely low frequencies
When these signals reach the brain, the nervous system integrates them with memory and spatial reasoning. The result is an intuitive understanding of space beyond direct touch.
This explains why experienced professionals—such as surgeons, craftsmen, or even blind individuals using canes—often demonstrate heightened spatial awareness. Their brains are exceptionally trained to interpret indirect sensory input.
More Accurate Than Machines?
One of the most remarkable findings from the study is that human remote touch can, in certain contexts, outperform current robotic sensors. While machines rely on rigid algorithms and limited sensor types, the human nervous system adapts in real time, filtering noise and refining perception instantly.
This flexibility allows humans to detect variations that machines often miss—particularly in complex, uneven, or natural environments.
Training the Seventh Sense
Although remote touch operates subconsciously in most people, researchers believe it can be trained and enhanced. By focusing attention on subtle vibrations, resistance, and feedback from surfaces, individuals can improve their ability to interpret these signals.
Simple practices may include:
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Walking barefoot on sand or grass while focusing on pressure changes
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Using hands to hover just above textured surfaces
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Slow, mindful movements that heighten tactile awareness
Such training doesn’t grant new abilities but rather reactivates dormant neural pathways that evolution has already provided.
Implications for Medical Prosthetics
One of the most promising applications of this discovery lies in medical prosthetics. Modern prosthetic limbs often struggle to provide realistic sensory feedback, limiting a user’s sense of control and embodiment.
By studying how the nervous system interprets remote touch, engineers could design prosthetics that transmit pressure and vibration signals more naturally to the brain. This could dramatically improve:
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Fine motor control
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Balance and coordination
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Emotional connection to prosthetic limbs
In the future, prosthetics may not just replace lost function but restore a natural sense of presence and awareness.
Transforming Search and Rescue Operations
Remote touch could also revolutionize search-and-rescue technologies. In disaster zones where visibility is poor—such as collapsed buildings or landslides—trained responders or sensor-enhanced tools inspired by human perception could detect survivors beneath debris.
By mimicking the way humans sense resistance and vibration through surfaces, new devices could become more sensitive, adaptable, and reliable than current detection systems.
Rethinking Human Potential
The discovery of remote touch invites us to reconsider what it means to be human. Rather than viewing our senses as fixed and limited, this research highlights the hidden depth of human perception.
It suggests that evolution has equipped us with far more sophisticated tools than we actively use—and that many of these abilities remain untapped simply because modern life no longer demands them.
A Quiet Revolution in Perception
Remote touch may not be as immediately dramatic as sight or hearing, but its implications are profound. It bridges biology, neuroscience, technology, and evolution, offering insights into how humans truly interact with the physical world.
As research continues, this seventh sense could redefine rehabilitation, robotics, and our understanding of the human body itself. Perhaps the most powerful realization is this: the ground beneath our feet and the air around our hands are constantly speaking to us—we’ve just forgotten how to listen.
