Angel Vladimirov Peterchev
Associate Professor in Psychiatry and Behavioral Sciences
I direct the Brain Stimulation Engineering Lab (BSEL) which focuses on the development and modeling of devices and application paradigms for transcranial brain stimulation. Transcranial brain stimulation involves non-invasive delivery of fields (e.g., electric and magnetic) to the brain that modulate neural activity. Transcranial brain stimulation is increasingly used as a tool for brain research and a therapeutic intervention in neurology and psychiatry. My lab works closely with neuroscientists and clinicians to translate novel brain stimulation technology and optimize existing techniques. For example, we have developed a device for transcranial magnetic stimulation (TMS) that allows extensive control over the magnetic pulse parameters. We are currently deploying this device to optimize the magnetic stimulus in neuromodulatory TMS paradigms. We are also developing efficient algorithms for response estimation and individualization of brain stimulation. Another line of work is finite element computational modeling of the fields induced in the brain by electric and magnetic stimulation. My lab is involved in the integration of transcranial brain stimulation with imaging modalities such as functional magnetic resonance imaging (fMRI) and electroencephalography (EEG), as well as the evaluation of the safety of device–device interactions, for example between transcranial stimulators and implants like deep-brain stimulation (DBS) systems.
In parallel, I pursue projects related to power electronics, with applications in electrical energy conversion and storage. Recent projects include modular multilevel converters for solar energy conversion and storage, grid storage applications, as well as electric vehicles.
Appointments and Affiliations
- Associate Professor in Psychiatry and Behavioral Sciences
- Associate Professor in the Department of Electrical and Computer Engineering
- Associate Professor in Neurosurgery
- Faculty Network Member of the Duke Institute for Brain Sciences
- Faculty Network Member of The Energy Initiative
- Office Location: Dept. Psychiatry & Behavioral, Box 3620 DUMC, Durham, NC 27710
- Office Phone: (919) 684-0383
- Email Address: firstname.lastname@example.org
- Ph.D. University of California at Berkeley, 2005
Development and modeling of devices and application paradigms for transcranial brain stimulation; projects related to power electronics, with applications in electrical energy conversion and storage
- BME 394: Projects in Biomedical Engineering (GE)
- BME 493: Projects in Biomedical Engineering (GE)
- BME 494: Projects in Biomedical Engineering (GE)
- BME 791: Graduate Independent Study
- BME 792: Continuation of Graduate Independent Study
- ECE 431: Power Electronic Circuits for Energy Conversion
- ECE 493: Projects in Electrical and Computer Engineering
- ECE 494: Projects in Electrical and Computer Engineering
- ECE 531: Power Electronic Circuits for Energy Conversion
- EGR 393: Research Projects in Engineering
- ENRGYEGR 431: Power Electronic Circuits for Energy Conversion
In the News
- Energy Initiative-Supported Project Connects Brain Science with Electric Cars (Aug 23, 2017)
- A shocking result: Study finds new trend of applying electric currents to your brain can actually lower your IQ (May 6, 2015 | The Daily Mail)
- Energy Initiative Provides First Round of Research Seed Funding (Apr 16, 2014)
- Peterchev, AV; DʼOstilio, K; Rothwell, JC; Murphy, DL, Controllable pulse parameter transcranial magnetic stimulator with enhanced circuit topology and pulse shaping., J Neural Eng, vol 11 no. 5 (2014) [10.1088/1741-2560/11/5/056023] [abs].
- Mueller, JK; Grigsby, EM; Prevosto, V; Petraglia, FW; Rao, H; Deng, Z-D; Peterchev, AV; Sommer, MA; Egner, T; Platt, ML; Grill, WM, Simultaneous transcranial magnetic stimulation and single-neuron recording in alert non-human primates., Nat Neurosci, vol 17 no. 8 (2014), pp. 1130-1136 [10.1038/nn.3751] [abs].
- Peterchev, AV; Goetz, SM; Westin, GG; Luber, B; Lisanby, SH, Pulse width dependence of motor threshold and input-output curve characterized with controllable pulse parameter transcranial magnetic stimulation., Clin Neurophysiol, vol 124 no. 7 (2013), pp. 1364-1372 [10.1016/j.clinph.2013.01.011] [abs].
- Goetz, SM; Truong, CN; Gerhofer, MG; Peterchev, AV; Herzog, H-G; Weyh, T, Analysis and optimization of pulse dynamics for magnetic stimulation., Plos One, vol 8 no. 3 (2013) [10.1371/journal.pone.0055771] [abs].
- Peterchev, AV; Wagner, TA; Miranda, PC; Nitsche, MA; Paulus, W; Lisanby, SH; Pascual-Leone, A; Bikson, M, Fundamentals of transcranial electric and magnetic stimulation dose: definition, selection, and reporting practices., Brain Stimul, vol 5 no. 4 (2012), pp. 435-453 [10.1016/j.brs.2011.10.001] [abs].
- Lee, WH; Deng, Z-D; Kim, T-S; Laine, AF; Lisanby, SH; Peterchev, AV, Regional electric field induced by electroconvulsive therapy in a realistic finite element head model: influence of white matter anisotropic conductivity., Neuroimage, vol 59 no. 3 (2012), pp. 2110-2123 [10.1016/j.neuroimage.2011.10.029] [abs].
- Peterchev, AV; Murphy, DL; Lisanby, SH, Repetitive transcranial magnetic stimulator with controllable pulse parameters., J Neural Eng, vol 8 no. 3 (2011) [10.1088/1741-2560/8/3/036016] [abs].
- Deng, Z-D; Lisanby, SH; Peterchev, AV, Electric field strength and focality in electroconvulsive therapy and magnetic seizure therapy: a finite element simulation study., J Neural Eng, vol 8 no. 1 (2011) [10.1088/1741-2560/8/1/016007] [abs].
- Peterchev, AV; Rosa, MA; Deng, Z-D; Prudic, J; Lisanby, SH, Electroconvulsive therapy stimulus parameters: rethinking dosage., J Ect, vol 26 no. 3 (2010), pp. 159-174 [10.1097/YCT.0b013e3181e48165] [abs].
- Peterchev, AV; Jalinous, R; Lisanby, SH, A transcranial magnetic stimulator inducing near-rectangular pulses with controllable pulse width (cTMS)., Ieee Transactions on Bio Medical Engineering, vol 55 no. 1 (2008), pp. 257-266 [10.1109/TBME.2007.900540] [abs].
- Peterchev, AV; Sanders, SR, Quantization resolution and limit cycling in digitally controlled PWM converters, Ieee Transactions on Power Electronics, vol 18 no. 1 II (2003), pp. 301-308 [10.1109/TPEL.2002.807092] [abs].