Ezquerra Romano Ivan, Chowdhury Maansib, Haggard Patrick
Institute of Cognitive Neuroscience, University College London, London WC1N 3AZ, UK.
Max-Delbrück Center for Molecular Medicine in the Helmholtz Association (MDC), Berlin-Buch, Robert-Rössle-Strasse 10, Berlin 13125, Germany.
Proc Biol Sci. 2025 Feb;292(2040):20243014. doi: 10.1098/rspb.2024.3014. Epub 2025 Feb 12.
Skin stimuli reach the brain via multiple neural channels specific for different stimulus types. These channels interact in the spinal cord, typically through inhibition. Inter-channel interactions can be investigated by selectively stimulating one channel and comparing the sensations that result when another sensory channel is or is not concurrently stimulated. Applying this logic to thermal-mechanical interactions proves difficult, because most existing thermal stimulators involve skin contact. We used a novel non-tactile stimulator for focal cooling (9 mm) by using thermal imaging of skin temperature as a feedback signal to regulate exposure to a dry-ice source. We could then investigate how touch modulates cold sensation by delivering cooling to the human hand dorsum in either the presence or absence of light touch. Across three signal detection experiments, we found that sensitivity to cooling was significantly reduced by touch. This reduction was specific to touch, as it did not occur when presenting auditory signals instead of the tactile input, making explanations based on distraction or attention unlikely. Our findings suggest that touch inhibits cold perception, recalling interactions of touch and pain previously described by Pain Gate Theory.
皮肤刺激通过多种针对不同刺激类型的神经通道到达大脑。这些通道在脊髓中相互作用,通常是通过抑制作用。可以通过选择性刺激一个通道,并比较当另一个感觉通道同时受到刺激或未受到刺激时产生的感觉,来研究通道间的相互作用。将这种逻辑应用于热-机械相互作用证明很困难,因为大多数现有的热刺激器都涉及皮肤接触。我们使用了一种新型非触觉刺激器进行局部冷却(9毫米),通过将皮肤温度的热成像作为反馈信号来调节与干冰源的接触。然后,我们可以通过在有或没有轻触的情况下对手背进行冷却,来研究触摸如何调节冷觉。在三个信号检测实验中,我们发现触摸会显著降低对冷却的敏感度。这种降低是触摸所特有的,因为当呈现听觉信号而非触觉输入时,这种情况不会发生,这使得基于分心或注意力的解释不太可能成立。我们的研究结果表明,触摸会抑制冷觉感知,这让人想起疼痛门控理论之前所描述的触摸与疼痛的相互作用。
