Comparing neural response to painful electrical stimulation with functional MRI at 3 and 7 T

Andreas Hahn; Georg S Kranz; Eva-Maria Seidel; Ronald Sladky; Christoph Kraus; Martin Küblböck; Daniela M Pfabigan; Allan Hummer; Arvina Grahl; Sebastian Ganger; Christian Windischberger; Claus Lamm; Rupert Lanzenberger

doi:10.1016/j.neuroimage.2013.06.010

Comparing neural response to painful electrical stimulation with functional MRI at 3 and 7 T

Standard

Comparing neural response to painful electrical stimulation with functional MRI at 3 and 7 T. / Hahn, Andreas; Kranz, Georg S; Seidel, Eva-Maria; Sladky, Ronald; Kraus, Christoph; Küblböck, Martin; Pfabigan, Daniela M; Hummer, Allan; Grahl, Arvina; Ganger, Sebastian; Windischberger, Christian; Lamm, Claus; Lanzenberger, Rupert.

In: NEUROIMAGE, Vol. 82, 15.11.2013, p. 336-43.

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

Harvard

Hahn, A, Kranz, GS, Seidel, E-M, Sladky, R, Kraus, C, Küblböck, M, Pfabigan, DM, Hummer, A, Grahl, A, Ganger, S, Windischberger, C, Lamm, C & Lanzenberger, R 2013, 'Comparing neural response to painful electrical stimulation with functional MRI at 3 and 7 T', NEUROIMAGE, vol. 82, pp. 336-43. https://doi.org/10.1016/j.neuroimage.2013.06.010

APA

Hahn, A., Kranz, G. S., Seidel, E-M., Sladky, R., Kraus, C., Küblböck, M., Pfabigan, D. M., Hummer, A., Grahl, A., Ganger, S., Windischberger, C., Lamm, C., & Lanzenberger, R. (2013). Comparing neural response to painful electrical stimulation with functional MRI at 3 and 7 T. NEUROIMAGE, 82, 336-43. https://doi.org/10.1016/j.neuroimage.2013.06.010

Vancouver

Hahn A, Kranz GS, Seidel E-M, Sladky R, Kraus C, Küblböck M et al. Comparing neural response to painful electrical stimulation with functional MRI at 3 and 7 T. NEUROIMAGE. 2013 Nov 15;82:336-43. https://doi.org/10.1016/j.neuroimage.2013.06.010

Bibtex

@article{85962b1e2fdb4e789b6ec79c3626921c,

title = "Comparing neural response to painful electrical stimulation with functional MRI at 3 and 7 T",

abstract = "Progressing from 3T to 7 T functional MRI enables marked improvements of human brain imaging in vivo. Although direct comparisons demonstrated advantages concerning blood oxygen level dependent (BOLD) signal response and spatial specificity, these mostly focused on single brain regions with rather simple tasks. Considering that physiological noise also increases with higher field strength, it is not entirely clear whether the advantages of 7T translate equally to the entire brain during tasks which elicit more complex neuronal processing. Therefore, we investigated the difference between 3T and 7 T in response to transcutaneous electrical painful and non-painful stimulation in 22 healthy subjects. For painful stimuli vs. baseline, stronger activations were observed at 7 T in several brain regions including the insula and supplementary motor area, but not the secondary somatosensory cortex (p<0.05 FWE-corrected). Contrasting painful vs. non-painful stimulation limited the differences between the field strengths to the periaqueductal gray (PAG, p<0.001 uncorrected) due to a similar signal increase at 7 T for both the target and specific control condition in most brain regions. This regional specificity obtained for the PAG at higher field strengths was confirmed by an additional spatial normalization strategy optimized for the brainstem. Here, robust BOLD responses were obtained in the dorsal PAG at 7 T (p<0.05 FWE-corrected), whereas at 3T activation was completely missing for the contrast against non-painful stimuli. To summarize, our findings support previously reported benefits obtained at ultra-high field strengths also for complex activation patterns elicited by painful electrical stimulation. However, this advantage depends on the region and even more on the contrast of interest. The greatest gain at 7 T was observed within the small brainstem region of the PAG, where the increased field strength offered marked improvement for the localization of activation foci with high spatial specificity.",

author = "Andreas Hahn and Kranz, {Georg S} and Eva-Maria Seidel and Ronald Sladky and Christoph Kraus and Martin K{\"u}blb{\"o}ck and Pfabigan, {Daniela M} and Allan Hummer and Arvina Grahl and Sebastian Ganger and Christian Windischberger and Claus Lamm and Rupert Lanzenberger",

year = "2013",

month = nov,

day = "15",

doi = "10.1016/j.neuroimage.2013.06.010",

language = "English",

volume = "82",

pages = "336--43",

journal = "NEUROIMAGE",

issn = "1053-8119",

publisher = "Academic Press",

}

RIS

TY - JOUR

T1 - Comparing neural response to painful electrical stimulation with functional MRI at 3 and 7 T

AU - Hahn, Andreas

AU - Kranz, Georg S

AU - Seidel, Eva-Maria

AU - Sladky, Ronald

AU - Kraus, Christoph

AU - Küblböck, Martin

AU - Pfabigan, Daniela M

AU - Hummer, Allan

AU - Grahl, Arvina

AU - Ganger, Sebastian

AU - Windischberger, Christian

AU - Lamm, Claus

AU - Lanzenberger, Rupert

PY - 2013/11/15

Y1 - 2013/11/15

N2 - Progressing from 3T to 7 T functional MRI enables marked improvements of human brain imaging in vivo. Although direct comparisons demonstrated advantages concerning blood oxygen level dependent (BOLD) signal response and spatial specificity, these mostly focused on single brain regions with rather simple tasks. Considering that physiological noise also increases with higher field strength, it is not entirely clear whether the advantages of 7T translate equally to the entire brain during tasks which elicit more complex neuronal processing. Therefore, we investigated the difference between 3T and 7 T in response to transcutaneous electrical painful and non-painful stimulation in 22 healthy subjects. For painful stimuli vs. baseline, stronger activations were observed at 7 T in several brain regions including the insula and supplementary motor area, but not the secondary somatosensory cortex (p<0.05 FWE-corrected). Contrasting painful vs. non-painful stimulation limited the differences between the field strengths to the periaqueductal gray (PAG, p<0.001 uncorrected) due to a similar signal increase at 7 T for both the target and specific control condition in most brain regions. This regional specificity obtained for the PAG at higher field strengths was confirmed by an additional spatial normalization strategy optimized for the brainstem. Here, robust BOLD responses were obtained in the dorsal PAG at 7 T (p<0.05 FWE-corrected), whereas at 3T activation was completely missing for the contrast against non-painful stimuli. To summarize, our findings support previously reported benefits obtained at ultra-high field strengths also for complex activation patterns elicited by painful electrical stimulation. However, this advantage depends on the region and even more on the contrast of interest. The greatest gain at 7 T was observed within the small brainstem region of the PAG, where the increased field strength offered marked improvement for the localization of activation foci with high spatial specificity.

AB - Progressing from 3T to 7 T functional MRI enables marked improvements of human brain imaging in vivo. Although direct comparisons demonstrated advantages concerning blood oxygen level dependent (BOLD) signal response and spatial specificity, these mostly focused on single brain regions with rather simple tasks. Considering that physiological noise also increases with higher field strength, it is not entirely clear whether the advantages of 7T translate equally to the entire brain during tasks which elicit more complex neuronal processing. Therefore, we investigated the difference between 3T and 7 T in response to transcutaneous electrical painful and non-painful stimulation in 22 healthy subjects. For painful stimuli vs. baseline, stronger activations were observed at 7 T in several brain regions including the insula and supplementary motor area, but not the secondary somatosensory cortex (p<0.05 FWE-corrected). Contrasting painful vs. non-painful stimulation limited the differences between the field strengths to the periaqueductal gray (PAG, p<0.001 uncorrected) due to a similar signal increase at 7 T for both the target and specific control condition in most brain regions. This regional specificity obtained for the PAG at higher field strengths was confirmed by an additional spatial normalization strategy optimized for the brainstem. Here, robust BOLD responses were obtained in the dorsal PAG at 7 T (p<0.05 FWE-corrected), whereas at 3T activation was completely missing for the contrast against non-painful stimuli. To summarize, our findings support previously reported benefits obtained at ultra-high field strengths also for complex activation patterns elicited by painful electrical stimulation. However, this advantage depends on the region and even more on the contrast of interest. The greatest gain at 7 T was observed within the small brainstem region of the PAG, where the increased field strength offered marked improvement for the localization of activation foci with high spatial specificity.

U2 - 10.1016/j.neuroimage.2013.06.010

DO - 10.1016/j.neuroimage.2013.06.010

M3 - SCORING: Journal article

C2 - 23769917

VL - 82

SP - 336

EP - 343

JO - NEUROIMAGE

JF - NEUROIMAGE

SN - 1053-8119

ER -