(Corrina Joel/EyeEm/Getty Images) HUMANS The Sensitivity of Human Fingertips Is Greater Than We Ever Imagined JACINTA BOWLER 21 MARCH 2021
Skin – the largest organ in the human body – envelops us from head to toe, letting us touch, feel, and interact with the outside world. But there's one part of that organ even more attuned to touch than any other.
A new study has revealed just how receptive the sensory neurons in our fingers are: As it turns out, we can detect touch on the minuscule scale of a single fingerprint ridge.
"You would expect that a single papillary ridge would play a role, but it hasn't been shown [before]," Ewa Jarocka, co-author of the study from Umeå University in Sweden told The Guardian.
Sensory neurons attached to receptors are dotted just underneath the skin's surface, allowing us to detect touch, vibration, pressure, pain, and lots more. Our hands alone contain tens of thousands of these neurons, each one with receptors on a small surface area of the skin, called a receptive field.
To map these fields, the researchers strapped down the arms of 12 healthy people and glued their fingernails to plastic holders to really make sure they couldn't move. A machine then wheeled tiny, 0.4 millimeter-wide cones around 7 mm apart across their skin (you can see what that looks like below) and the team recorded each neuron's response using an electrode in the participants' arms.
The setup. (Jarocka et al., J. Neurosci, 2021)
Specifically, they were mapping the more sensitive zones – known as subfields – within these receptive fields.
By calculating the sensory neuron detection areas and mapping them onto the fingerprint, the team found that the detection area's width was equivalent to the width of one fingerprint ridge.
These subfields also didn't move when the machine wheeled the dots faster or slower, or changed directions, suggesting that these sensitive areas are anchored to the fingerprint ridges themselves.
"We report that the sensitivity of the subfield arrangement for both neuron types on average corresponds to a spatial period of ~0.4 mm and provide evidence that a subfield's spatial selectivity arises because its associated receptor organ measures mechanical events limited to a single papillary ridge," the researchers write in their new paper.
Receptive fields projected on a fingerprint. (Jarocka et al., J. Neurosci, 2021)
Excitingly, this is the first study to show that our fingerprint ridges are helping us feel the world around us more accurately.
"We have all those multiple hotspots, and each one responds to the details of 0.4 millimeters, which is the approximate width of the [fingerprint] ridge," Jarocka told New Scientist.
"Then our brain receives all that information. This really offers an explanation to how it's possible that we're so dexterous and have such a high sensitivity in our fingertips."
The research has been published in The Journal of Neuroscience.