Techniques in Cognitive Neuroscience Transcranial Magnetic Stimulation (TMS)

1. Techniques in Cognitive NeuroscienceTranscranial Magnetic Stimulation (TMS)

2. Example Exam Questions • How has transcranial magnetic stimulation advanced our understanding about the human brain? • What are the advantages and limitations of transcranial magnetic stimulation relative to other techniques used in cognitive neuroscience. • How does transcranial magnetic stimulation compare with other neuroscientific techniques with regard to spatial and temporal resolution? • “Transcranial magnetic stimulation allows the cognitive neuroscientist to manipulate brain function in time and space.” Discuss.

3. Transcranial Magnetic StimulationLecture Outline • Neurophysiological Underpinnings • Applications • Research • Diagnostic • Therapeutic • Advantages • Limitations

4. Transcranial Magnetic StimulationNeurophysiological Underpinnings Electromagnetic induction: An electric current passed through a stimulating coil produces a magnetic field; changes in the magnetic field induces a flow of electric current in a nearby conductor – brain tissue.

5. Transcranial Magnetic StimulationNeurophysiological Underpinnings Coil design: Circular coil stimulation induces a brain current running in the opposite direction of the primary coil current; the induced current intensity is a function of distance from the stimulating coil. .

6. Transcranial Magnetic StimulationNeurophysiological Underpinnings Coil design: In a Figure-8 (focal) coil, the coil current sums at the coil junction; The induced electric field lies parallel with the cortical surface; Must quantify “motor threshold [MT]” to determine standardised stimulation. .

7. Transcranial Magnetic StimulationNeurophysiological Underpinnings

8. Transcranial Magnetic StimulationNeurophysiological Underpinnings Coil positioning: Over the left primary motor cortex, the current in the coil flow must be counter-clockwise; this is likely related to the anatomical orientation of pyramidal tract neurons and their axons.

9. Transcranial Magnetic StimulationNeurophysiological Underpinnings “Cortical silent period” illustrates a refractory phase following a stimulating pulse.

10. Transcranial Magnetic StimulationNeurophysiological Underpinnings “Short interval intra-cortical inhibition (SICI) and facilitation (SICF)”: Subthreshold conditioning pulse activates GABA-ergic inhibitory interneurons… (Kujirai, 1993)

11. Transcranial Magnetic StimulationNeurophysiological Underpinnings Psychoparmacology: GABA-ergic agonists increase the CSP… (Werhahn et al., 1999)

12. Transcranial Magnetic StimulationNeurophysiological Underpinnings Psychoparmacology: … and ethanol reduces SICF of MEPs (Ziemann et al., 1995)

13. Transcranial Magnetic StimulationNeurophysiological Underpinnings High-frequency Repetitive TMS (HF rTMS): Increases cortical excitability (Peinemann et al., 2004)

14. Transcranial Magnetic StimulationApplications: Neuropsychology

15. Transcranial Magnetic StimulationApplications: ...Neuropsychology

16. Transcranial Magnetic StimulationApplications: “Virtual Lesions” (Desmurget et al., 1999)

17. Transcranial Magnetic StimulationCombining Techniques: fMRI (Bestmann et al., 2005)

18. Transcranial Magnetic StimulationCombining Techniques: EEG (Esser et al., 2006)

19. Transcranial Magnetic StimulationAdvantages (Cowey & Walsh, 2000)

20. Transcranial Magnetic StimulationLimitations Inter-individual variability: e.g. Skull thickness

21. Transcranial Magnetic StimulationLimitations Intra-individual short-term variability

22. The End