Psychophysically anchored, robust thresholding in studying pain related lateralization of oscillatory pre-stimulus activity

Philipp Taesler; Michael Rose

Psychophysically anchored, robust thresholding in studying pain related lateralization of oscillatory pre-stimulus activity

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Psychophysically anchored, robust thresholding in studying pain related lateralization of oscillatory pre-stimulus activity. / Taesler, Philipp; Rose, Michael.

In: JOVE-J VIS EXP, No. 119, 21.01.2017, p. e55228.

Research output: SCORING: Contribution to journal › SCORING: Journal article › Research › peer-review

Harvard

Taesler, P & Rose, M 2017, 'Psychophysically anchored, robust thresholding in studying pain related lateralization of oscillatory pre-stimulus activity', JOVE-J VIS EXP, no. 119, pp. e55228.

APA

Taesler, P., & Rose, M. (2017). Psychophysically anchored, robust thresholding in studying pain related lateralization of oscillatory pre-stimulus activity. JOVE-J VIS EXP, (119), e55228.

Vancouver

Taesler P, Rose M. Psychophysically anchored, robust thresholding in studying pain related lateralization of oscillatory pre-stimulus activity. JOVE-J VIS EXP. 2017 Jan 21;(119):e55228.

Bibtex

@article{54f903a136bb417fb019c63b3c7fd324,

title = "Psychophysically anchored, robust thresholding in studying pain related lateralization of oscillatory pre-stimulus activity",

abstract = "In perceptual studies, it is often important to objectively assess the equality of delivered stimulation across participants or to quantify the intra-individual sensation magnitude that is evoked by stimulation over multiple trials. This requires a robust mapping of stimulus magnitude to perceived intensity and is commonly achieved by psychophysical estimation methods such as the staircase procedure. Newer, more efficient procedures like the QUEST algorithm fit a psychophysical function to the data in real time while at the same time maximizing the efficiency of data collection. A robust estimate of the threshold intensity between painful and non-painful perception can then be used to reduce the influence of variations in sensory input in subsequent analyses of oscillatory brain activity. By stimulating at a constant threshold intensity determined by an adaptive estimation procedure, the variance in the ratings can be directly attributed to perceptual processes. Oscillatory activity can then be contrasted between “pain” and “no-pain” trials directly, yielding activity that closely relates to perceptual classification processes in nociception.",

author = "Philipp Taesler and Michael Rose",

year = "2017",

month = jan,

day = "21",

language = "English",

pages = "e55228",

journal = "JOVE-J VIS EXP",

issn = "1940-087X",

publisher = "MYJoVE Corporation",

number = "119",

}

RIS

TY - JOUR

T1 - Psychophysically anchored, robust thresholding in studying pain related lateralization of oscillatory pre-stimulus activity

AU - Taesler, Philipp

AU - Rose, Michael

PY - 2017/1/21

Y1 - 2017/1/21

N2 - In perceptual studies, it is often important to objectively assess the equality of delivered stimulation across participants or to quantify the intra-individual sensation magnitude that is evoked by stimulation over multiple trials. This requires a robust mapping of stimulus magnitude to perceived intensity and is commonly achieved by psychophysical estimation methods such as the staircase procedure. Newer, more efficient procedures like the QUEST algorithm fit a psychophysical function to the data in real time while at the same time maximizing the efficiency of data collection. A robust estimate of the threshold intensity between painful and non-painful perception can then be used to reduce the influence of variations in sensory input in subsequent analyses of oscillatory brain activity. By stimulating at a constant threshold intensity determined by an adaptive estimation procedure, the variance in the ratings can be directly attributed to perceptual processes. Oscillatory activity can then be contrasted between “pain” and “no-pain” trials directly, yielding activity that closely relates to perceptual classification processes in nociception.

AB - In perceptual studies, it is often important to objectively assess the equality of delivered stimulation across participants or to quantify the intra-individual sensation magnitude that is evoked by stimulation over multiple trials. This requires a robust mapping of stimulus magnitude to perceived intensity and is commonly achieved by psychophysical estimation methods such as the staircase procedure. Newer, more efficient procedures like the QUEST algorithm fit a psychophysical function to the data in real time while at the same time maximizing the efficiency of data collection. A robust estimate of the threshold intensity between painful and non-painful perception can then be used to reduce the influence of variations in sensory input in subsequent analyses of oscillatory brain activity. By stimulating at a constant threshold intensity determined by an adaptive estimation procedure, the variance in the ratings can be directly attributed to perceptual processes. Oscillatory activity can then be contrasted between “pain” and “no-pain” trials directly, yielding activity that closely relates to perceptual classification processes in nociception.

M3 - SCORING: Journal article

SP - e55228

JO - JOVE-J VIS EXP

JF - JOVE-J VIS EXP

SN - 1940-087X

IS - 119

ER -