15 research outputs found
School of Batman: The Asylum's New Wing - Jens Foell
<div>Can psychopathy be used to determine why there are so many new criminals in Arkham Asylum? Find out on this week's episode of School of Batman!</div><div><br></div><div>This week, we're joined by Jens Foell, who has a PhD in Neuropsychology from Heidelberg University and is currently a researcher in the Department of Psychology at Florida State University. To find out more about Jens's research, follow him on Twitter at @fMRI_guy.</div><div><div>__________________</div><div><br></div><div>Impact Moderato by Kevin MacLeod is licensed under a Creative Commons Attribution license (creativecommons.org/licenses/by/4.0/)</div><div>Source: incompetech.com/music/royalty-fre…isrc=USUAN1100618</div><div>Artist: incompetech.com/</div><div><br></div><div>Cool Vibes - Film Noire by Kevin MacLeod is licensed under a Creative Commons Attribution license (creativecommons.org/licenses/by/4.0/)</div><div>Source: incompetech.com/music/royalty-fre…isrc=USUAN1100863</div><div>Artist: incompetech.com/</div><div><br></div><div>Mechanolith by Kevin MacLeod is licensed under a Creative Commons Attribution license (creativecommons.org/licenses/by/4.0/)</div><div>Source: incompetech.com/music/royalty-fre…isrc=USUAN1100879</div><div>Artist: incompetech.com/</div></div
Cross_Domain_InhDis_Supplement – Supplemental material for Quantifying Inhibitory Control as Externalizing Proneness: A Cross-Domain Model
<p>Supplemental material, Cross_Domain_InhDis_Supplement for Quantifying Inhibitory Control as Externalizing Proneness: A Cross-Domain Model by Noah C. Venables, Jens Foell, James R. Yancey, Michael J. Kane, Randall W. Engle, and Christopher J. Patrick in Clinical Psychological Science</p
Percentage of estimates of the body representation in dreams (n = 2,156).
<p>Percentage of estimates of the body representation in dreams (n = 2,156).</p
Results for ordinal logistic regression analyses on body representation in dreams (given validity of all other item values; n = 2,112).
<p>Results for ordinal logistic regression analyses on body representation in dreams (given validity of all other item values; n = 2,112).</p
Mirror visual feedback (MVF) devices.
<p>(A) Mirror glasses: are usable within an MR environment. The optical path was deflected by a prism, which was a 1.5–1.53 45-90-45 angled glass, Barium crown (BK-7, Abbe 63) with quarter wavelength surface tolerance. (B) Mirror box: was a framed glass mirror (size: 35 by 12 centimetres / 13.8 by 4.7 inches) which was placed on the abdomen of the subject providing view on the executing hand as well as the visual reflection of the hand appearing to move in synchrony. During both conditions view on the mirror reflection of the moving limb was provided by means of an additional mirror attached to the head coil. (C) Illustration of the MVF as provided by the mirror glasses: in contrast to the mirror box the users’ view is limited to the mirror reflection of the moving (physical) hand as opposed to seeing both hands (physical hand and visual reflection of the physical hand). The mirror reflection of the physical hand was seen through on eye by means of a prism leading to a total inversion in the left-right dimension (in our setup the right hand movements were seen through the right eye appearing as left hand movements). Furthermore, mirror glasses provide a much larger field of view, allowing the whole limb to be inverted.</p
Task-related brain activation for the mirror glasses and mirror box conditions.
<p>fMRI activations were mapped on a FSL render image. MI/SI = primary motor/somatosensory cortex, ipsi = ipsilateral to the executing (right) hand.</p
Brain regions and peak voxel coordinates showing significant task-related brain activation for the mirror box and mirror glasses conditions.
<p>Areas of significant fMRI-response were determined using clusters identified by a <i>z</i> > 3.0 threshold and a corrected cluster threshold of p = 0.05 assuming a Gaussian random field for the <i>z</i>-statistics. Coordinates are displayed in the Montreal Neurological Institute (MNI152) space.</p><p>Brain regions and peak voxel coordinates showing significant task-related brain activation for the mirror box and mirror glasses conditions.</p
Ratings on the intensity and vividness of mirror illusions for the mirror box and mirror glasses conditions.
<p>Results are reported with Mean ± Standard Deviation of the Mean (<i>M</i> ± <i>SD</i>). Comparisons of the two items between conditions were conducted with paired sample <i>t</i>-tests with Bonferroni adjusted alpha-values of 0.025 (0.05/2). Numerical rating scale ranging from 1 (‘as clear and vivid as a real perceptual experience’) to 7 (‘not at all clear and vivid’).</p><p>Ratings on the intensity and vividness of mirror illusions for the mirror box and mirror glasses conditions.</p
Brain regions showing significant positive psychophysiological interactions (PPI) with the motor representation of the moving hand.
<p>fMRI activations were mapped on a FSL render image. For illustrative purposes the spherical seed region of interest in the left primary motor cortex is also shown as red-colored sphere. MI/SI = primary motor/somatosensory cortex, LOC = lateral occipital cortex, PCC = posterior cingulate cortex, ipsi = ipsilateral to the executing (right) hand.</p
Results for the conjunction analysis.
<p>a) whole brain analysis (<i>p</i><.05, FWE-corrected); the number above each slice indicates the height (z-coordinate in Montreal Neurological Institute [MNI] space); b) analysis for bilateral ventral premotor cortex using regions of interest (<i>p</i><.005, uncorrected); given is the y-coordinate of the slices of peak activity (in MNI space). MOG =  middle occipital gyrus; MTG =  middle temporal gyrus; S2+ =  secondary somatosensory cortex plus its vicinity; PG =  precentral gyrus. Color bars indicate <i>t</i>-values.</p