Stimulus Novelty, and Not Neural Refractoriness, Explains the Repetition Suppression of Laser-Evoked Potentials

Brief radiant laser pulses selectively activate skin nociceptors and elicit transient brain responses (laser-evoked potentials [LEPs]). When LEPs are elicited by pairs of stimuli (S1–S2) delivered at different interstimulus intervals (ISIs), the S2-LEP is strongly reduced at short ISIs (250 ms) and progressively recovers at longer ISIs (2,000 ms). This finding has been interpreted in terms of order of arrival of nociceptive volleys and refractoriness of neural generators of LEPs. However, an alternative explanation is the modulation of another experimental factor: the novelty of the eliciting stimulus. To test this alternative hypothesis, we recorded LEPs elicited by pairs of nociceptive stimuli delivered at four ISIs (250, 500, 1,000, 2,000 ms), using two different conditions. In the constant condition, the ISI was identical across the trials of each block, whereas in the variable condition, the ISI was varied randomly across trials and single-stimulus trials were intermixed with paired trials. Therefore the time of occurrence of S2 was both less novel and more predictable in the constant than in the variable condition. In the constant condition, we observed a significant ISI-dependent suppression of the biphasic negative–positive wave (N2–P2) complex of the S2-LEP. In contrast, in the variable condition, the S2-LEP was completely unaffected by stimulus repetition. The pain ratings elicited by S2 were not different in the two conditions. These results indicate that the repetition-suppression of the S2-LEP is not due to refractoriness in nociceptive afferent pathways, but to a modulation of novelty and/or temporal predictability of the eliciting stimulus. This provides further support to the notion that stimulus saliency constitutes a crucial determinant of LEP magnitude and that a significant fraction of the brain activity time-locked to a brief and transient sensory stimulus is not directly related to the quality and the intensity of the corresponding sensation, but to bottom-up attentional processes.

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Skipping Breakfast Affects the Early Steps of Cognitive Processing

Journal of Psychophysiology ◽

10.1027/0269-8803/a000214 ◽

2019 ◽

Vol 33 (2) ◽

pp. 109-118

Author(s):

Andrés Antonio González-Garrido ◽

Jacobo José Brofman-Epelbaum ◽

Fabiola Reveca Gómez-Velázquez ◽

Sebastián Agustín Balart-Sánchez ◽

Julieta Ramos-Loyo

Keyword(s):

Working Memory ◽

Cognitive Processing ◽

Task Difficulty ◽

Brain Activity ◽

Reaction Times ◽

Brain Potentials ◽

Brain Functioning ◽

Attentional Processes ◽

Electrical Brain Activity ◽

Skipping Breakfast

Abstract. It has been generally accepted that skipping breakfast adversely affects cognition, mainly disturbing the attentional processes. However, the effects of short-term fasting upon brain functioning are still unclear. We aimed to evaluate the effect of skipping breakfast on cognitive processing by studying the electrical brain activity of young healthy individuals while performing several working memory tasks. Accordingly, the behavioral results and event-related brain potentials (ERPs) of 20 healthy university students (10 males) were obtained and compared through analysis of variances (ANOVAs), during the performance of three n-back working memory (WM) tasks in two morning sessions on both normal (after breakfast) and 12-hour fasting conditions. Significantly fewer correct responses were achieved during fasting, mainly affecting the higher WM load task. In addition, there were prolonged reaction times with increased task difficulty, regardless of breakfast intake. ERP showed a significant voltage decrement for N200 and P300 during fasting, while the amplitude of P200 notably increased. The results suggest skipping breakfast disturbs earlier cognitive processing steps, particularly attention allocation, early decoding in working memory, and stimulus evaluation, and this effect increases with task difficulty.

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DIAGNOSTIC ACCURACY OF LASER EVOKED POTENTIALS IN DIABETIC NEUROPATHY

10.26226/morressier.598b05d8d462b80290b538e9 ◽

2017 ◽

Author(s):

Giulia Di Stefano

Keyword(s):

Diabetic Neuropathy ◽

Diagnostic Accuracy ◽

Evoked Potentials ◽

Laser Evoked Potentials

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Suggestion and Pain in Migraine: A Study by Laser Evoked Potentials

CNS & Neurological Disorders - Drug Targets ◽

10.2174/187152712800269759 ◽

2012 ◽

Vol 11 (2) ◽

pp. 110-126 ◽

Cited By ~ 14

Author(s):

Marina de Tommaso ◽

Antonio Federici ◽

Giovanni Franco ◽

Katia Ricci ◽

Marta Lorenzo ◽

...

Keyword(s):

Evoked Potentials ◽

Laser Evoked Potentials

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Heartbeat evoked potentials (HEP) capture brain activity affecting subsequent heartbeat

Biomedical Signal Processing and Control ◽

10.1016/j.bspc.2021.102731 ◽

2021 ◽

Vol 68 ◽

pp. 102731

Author(s):

Mindaugas Baranauskas ◽

Aida Grabauskaitė ◽

Inga Griškova-Bulanova ◽

Benedikta Lataitytė-Šimkevičienė ◽

Rytis Stanikūnas

Keyword(s):

Evoked Potentials ◽

Brain Activity

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Focal Mechanical Vibration Does not Change Laser-Pain Perception and Laser-Evoked Potentials: A Pilot Study

Pain Practice ◽

10.1111/papr.12417 ◽

2016 ◽

Vol 17 (1) ◽

pp. 25-31 ◽

Cited By ~ 2

Author(s):

Costanza Pazzaglia ◽

Filippo Camerota ◽

Claudia Celletti ◽

Ileana Minciotti ◽

Elisa Testani ◽

...

Keyword(s):

Pilot Study ◽

Evoked Potentials ◽

Pain Perception ◽

Mechanical Vibration ◽

Laser Evoked Potentials

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Dyspnea-pain counterirritation induced by inspiratory threshold loading: a laser-evoked potentials study

Journal of Applied Physiology ◽

10.1152/japplphysiol.01055.2011 ◽

2012 ◽

Vol 112 (7) ◽

pp. 1166-1173 ◽

Cited By ~ 8

Author(s):

Guillaume Bouvier ◽

Louis Laviolette ◽

Felix Kindler ◽

Lionel Naccache ◽

André Mouraux ◽

...

Keyword(s):

Evoked Potentials ◽

Somatosensory Evoked Potentials ◽

Normal Male ◽

Work Effort ◽

Top Down ◽

Laser Evoked Potentials ◽

Brain Potentials ◽

Nociceptive Flexion Reflex ◽

Electrical Stimuli ◽

Experimentally Induced

Background: experimentally induced dyspnea of the work/effort type inhibits, in a top-down manner, the spinal transmission of nociceptive inputs (dyspnea-pain counterirritation). Previous studies have demonstrated that this inhibition can be assessed by measuring the nociceptive flexion reflex (RIII). However, its clinical application is limited because of the strong discomfort associated with the electrical stimuli required to elicit the RIII reflex. Study objectives: we examined whether the dyspnea-pain counterirritation phenomenon can be evaluated by measuring the effect of work/effort type dyspnea on the magnitude of laser-evoked brain potentials (LEPs). Methods: 10 normal male volunteers were studied (age: 19–30 years). LEPs were elicited using a CO2 laser stimulator delivering 10- to 15-ms stimuli of 6 ± 0.7 W over a 12.5 mm2 area. The EEG was recorded using nine scalp channels. Non-nociceptive somatosensory-evoked potentials (SEPs) served as control. LEPs and SEPs were recorded before, during, and after 10 min of experimentally induced dyspnea [inspiratory threshold loading (ITL)]. Results: pain caused by the nociceptive laser stimulus was mild. ITL consistently induced dyspnea, mostly of the “excessive effort” type. Amplitude of the N2-P2 wave of LEPs decreased by 37.6 ± 13.8% during ITL and was significantly correlated with the intensity of dyspnea [ r = 0.66, CI 95% (0.08–0.92, P = 0.0319)]. In contrast, ITL had no effect on the magnitude of non-nociceptive SEPs. Discussion: experimentally induced dyspnea of the work/effort type reduces the magnitude of LEPs. This reduction correlates with the intensity of dyspnea. The recording of LEPs could constitute a clinically applicable approach to assess the dyspnea-pain counterirritation phenomenon in patients.

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