Changing Reference Frames during the Encoding of Tactile Events

Azañón, Elena; Soto‐Faraco, Salvador

doi:10.1016/j.cub.2008.06.045

Cited by 184 publications

(201 citation statements)

References 44 publications

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“…Moreover, a single weight parameter for each reference frame was sufficient to account for uncrossed and for crossed performance, indicating that the integration follows the same principles in both postures. Effects of body posture on touch processing have often been attributed to the external reference frame of touch (Driver & Spence, 1998;Aglioti et al, 1999;Kennett et al, 2001;Yamamoto & Kitazawa, 2001a;Shore et al, 2002;Soto-Faraco et al, 2004;Röder et al, 2004;Eimer et al, 2004;Bolognini & Maravita, 2007;Azañón & Soto-Faraco, 2008;Heed et al, 2012;Buchholz et al, 2011;. This is because body posture determines the location of the stimulated skin region in space, but should not influence the processing of any other tactile stimulus characteristics .…”

Section: Discussionmentioning

confidence: 99%

“…Moreover, the present parameter estimates invite the speculation that bottom-up influences, such as the number of stimuli, are reflected in the anatomical weights, whereas top-down influences, such as task instructions, bear on the external weights: Indeed, the anatomical representation of touch is associated with the primary somatosensory cortices, that store all sensory characteristics of a touch. In contrast, the external representation of touch is presumably established later and in higher-order brain regions (Azañón & Soto-Faraco, 2008;Heed & Röder, 2010;Overvliet et al, 2011;Soto-Faraco & Azañón, 2013;Rigato et al, 2013). The latter are tightly connected to frontal brain areas associated with cognitive control processes.…”

Section: Weighted Integration Accounts For Previous Findingsmentioning

confidence: 99%

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Integration of anatomical and external response mappings explains crossing effects in tactile localization: A probabilistic modeling approach

2015

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To act upon a tactile stimulus its original skinbased, anatomical spatial code has to be transformed into an external, posture-dependent reference frame, a process known as tactile remapping. When the limbs are crossed, anatomical and external location codes are in conflict, leading to a decline in tactile localization accuracy. It is unknown whether this impairment originates from the integration of the resulting external localization response with the original, anatomical one or from a failure of tactile remapping in crossed postures. We fitted probabilistic models based on these diverging accounts to the data from three tactile localization experiments. Hand crossing disturbed tactile left-right location choices in all experiments. Furthermore, the size of these crossing effects was modulated by stimulus configuration and task instructions. The best model accounted for these results by integration of the external response mapping with the original, anatomical one, while applying identical integration weights for uncrossed and crossed postures. Thus, the model explained the data without assuming failures of remapping. Moreover, performance differences across tasks were accounted for by non-individual parameter adjustments, indicating that individual participants' task adaptation results from one common functional mechanism. These results suggest that remapping is an automatic and accurate process, and that the observed localization impairments in touch result from a cognitively controlled integration process that combines anatomically and externally coded responses.

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Section: Discussionmentioning

confidence: 99%

Section: Weighted Integration Accounts For Previous Findingsmentioning

confidence: 99%

Integration of anatomical and external response mappings explains crossing effects in tactile localization: A probabilistic modeling approach

2015

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“…Tactile inputs have been shown to be coded somatotopically at early stages of processing and, subsequently, to be processed in spatiotopic space (Azañón & Soto-Faraco, 2008). The influences from the somatotopic distance have been reported in simple temporal tasks, such as tactile simultaneity judgment (Clark & Geffen, 1990;Kuroki, Watanabe, Kawakami, Tachi, & Nishida, 2010) and tactile apparent motion detection (Kuroki et al, 2010;Sherrick, 1968), and in tactile learning (Harris, Harris, & Diamond, 2001).…”

Section: Methodsmentioning

confidence: 99%

Somatotopic or spatiotopic? Frame of reference for localizing thermal sensations under thermo-tactile interactions

Ho¹,

Watanabe

Ando

et al. 2010

Attention, Perception, & Psychophysics

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“…Head and Holmes (Head and Holmes 1911) suggested that a superficial body schema (a representation of the body in the brain) is first created in a canonical position with posture being added later to form what they called the postural schema. Their seminal study has since obtained substantial support (Shuler et al 2001;Azañón and Soto-Faraco 2008;Schntz-Bosbach et al 2009;Azañón et al 2010a, b). The present experiment investigates whether long-range masking effects occur at the level of the superficial body schema or after postural information has been added to form a postural schema.…”

Section: Introductionmentioning

confidence: 91%

Long-range tactile masking occurs in the postural body schema

D’Amour

Harris

2015

Exp Brain Res

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Long-range tactile masking has been reported between mirror symmetric body locations. This suggests a general principle of contralateral inhibition between corresponding points on each side of the body that may serve to enhance distinguishing touches on the two halves of the body. Do such effects occur before or after posture is added to the body schema? Here, we address this question by exploring the effect of arm position on long-range tactile masking. The influence of arm position was investigated using different positions of both the test and masking arms. Tactile sensitivity was measured on one forearm, while vibrotactile-masking stimulation was applied to the opposite arm or to a control site on the shoulder. No difference was found in sensitivity when test arm position was varied. Physical contact between the arms significantly increased the effectiveness of a masking stimulus applied to the other arm. Long-range masking between the arms was strongest when the arms were held parallel to each other and was abolished if the position of either the test arm or the masking arm was moved from this position. Modulation of the effectiveness of masking by the position of both the test and masking arms suggests that these effects occur after posture information is added to the body's representation in the brain.

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Changing Reference Frames during the Encoding of Tactile Events

Cited by 184 publications

References 44 publications

Integration of anatomical and external response mappings explains crossing effects in tactile localization: A probabilistic modeling approach

Integration of anatomical and external response mappings explains crossing effects in tactile localization: A probabilistic modeling approach

Somatotopic or spatiotopic? Frame of reference for localizing thermal sensations under thermo-tactile interactions

Long-range tactile masking occurs in the postural body schema

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