Tactile spatial acuity is reduced by skin stretch at the human wrist.

The skin is an elastic organ that is continuously distorted as our limbs move. The hypothesis that the precision of human tactile localisation is reduced when the skin is stretched, with concurrent expansion of receptive fields (RFs) was tested. Locognosic acuity over the dorsal wrist area was quantified during application of background stretch by (a) Wrist-Bend (skin stretch combined with non-cutaneous proprioceptor activation) and (b) Skin-Pull (skin stretch alone). Participants identified the perceived direction (distal or proximal) of brief test stimuli, applied along a 7-point linear array, relative to a central reference locus. Performance was significantly reduced during the large amplitude compared to the small amplitude of tonic skin stretch, but there was no effect of stretch mode (Wrist-Bend, Skin-Pull), nor was the effect of stretch amplitude modulated by the mode of stretch. Locognosic acuity was poorer than baseline accuracy for the large amplitude skin stretches, for both application modes, but did not differ significantly from baseline for either of the small amplitude stretches. We interpret these observations as corroborating the long-held assumption that tactile localisation is primarily dependent upon the RF dimensions, and associated innervation densities, of regional touch units. The finding that performance was reduced to a similar extent under Skin-Pull and Wrist-Bend conditions suggests that non-cutaneous proprioceptors had rather little tonic modulatory effect.