Abstract

EEG recording studies in humans have revealed the presence of oscillatory rhythms in brain activity, and D oscillations in different frequency bands have been associated with cognitive processes such as working D memory. Additionally, alterations of oscillatory activity are found in psychiatric illnesses such as D schizophrenia. Despite their apparent relevance, however, the role of neural oscillations in cognitive D processes are as yet poorly understood. The proposed project explores these issues using simultaneous D transcranial magnetic stimulation (TMS) and EEG recording. Specifically, the present proposal assesses D two proposals regarding the mechanisms by which TMS influences ongoing neural activity and hence D behavior. The first proposal holds that TMS achieves it effects by injecting electrical noise into task-related D neural areas, producing characteristic declines in performance. However, this proposal is inconsistent with D findings of TMS-related improvements in performance, which have been reported in several studies. Thus, C an alternative account holds that TMS interacts in subtle ways with ongoing neural activity related to the D performance of specific tasks, producing disruptions or improvements in performance depending on the D nature of the interaction. This issue is explored in an experiment comparing the effects of 10-Hz repetitive D (r)TMS on neural activity, to the effects of 10-Hz visual flicker, which is known to produce widespread D entrainment (i.e. disruption) of neural activity to the flicker frequency. Two additional experiments explore 7 task-related changes in neural oscillations, and how TMS can be used to alter such oscillations, producing u improvements or disruptions in performance at the individual subject level. D D The proposed project will help to clarify how neurostimulation methods such as transcranial magnetic D stimulation (TMS) influence ongoing neural activity, and will contribute decisively to our understanding of D the role of neural oscillations in cognitive processes such as working memory. Moreover, the methods D developed here will point the way towards the use of TMS in the exploration and treatment of abnormal D oscillations found in psychiatric illnesses such as schizophrenia.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Mental Health (NIMH)
Type
Postdoctoral Individual National Research Service Award (F32)
Project #
5F32MH088115-02
Application #
7946379
Study Section
Special Emphasis Panel (ZRG1-F02A-J (20))
Program Officer
Vogel, Michael W
Project Start
2009-09-28
Project End
2012-09-27
Budget Start
2010-09-28
Budget End
2011-09-27
Support Year
2
Fiscal Year
2010
Total Cost
$50,474
Indirect Cost

  Institution

Name
University of Wisconsin Madison
Department
Psychiatry
Type
Schools of Medicine
DUNS #
161202122
City
Madison
State
WI
Country
United States
Zip Code
53715

  Publications

Kundu, Bornali; Johnson, Jeffrey S; Postle, Bradley R (2014) Trait-like differences in underlying oscillatory state predict individual differences in the TMS-evoked response. Brain Stimul 7:234-42
Kundu, Bornali; Johnson, Jeffrey S; Postle, Bradley R (2014) Prestimulation phase predicts the TMS-evoked response. J Neurophysiol 112:1885-93
Johnson, Jeffrey S; Kundu, Bornali; Casali, Adenauer G et al. (2012) Task-dependent changes in cortical excitability and effective connectivity: a combined TMS-EEG study. J Neurophysiol 107:2383-92
Johnson, Jeffrey S; Sutterer, David W; Acheson, Daniel J et al. (2011) Increased Alpha-Band Power during the Retention of Shapes and Shape-Location Associations in Visual Short-Term Memory. Front Psychol 2:128
Hamidi, Massihullah; Johson, Jeffrey S; Feredoes, Eva et al. (2011) Does high-frequency repetitive transcranial magnetic stimulation produce residual and/or cumulative effects within an experimental session? Brain Topogr 23:355-67
Johnson, Jeffrey S; Hamidi, Massihullah; Postle, Bradley R (2010) Using EEG to explore how rTMS produces its effects on behavior. Brain Topogr 22:281-93