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Kirill Aristovich

Showing results (1-10 of 44) with videos related to

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Journal of Electrical Bioimpedance|April 18, 2022
Opinion: the Future of Electrical Impedance TomographyKirill Aristovich
Frontiers in Neuroscience|June 10, 2021
Selective Neuromodulation of the Vagus NerveAdam Fitchett, Svetlana Mastitskaya, Kirill Aristovich
Journal of Neural Engineering|June 27, 2019
Simulation of impedance changes with a FEM model of a myelinated nerve fibreIlya Tarotin, Kirill Aristovich, David Holder
IEEE Transactions on Bio-Medical Engineering|July 12, 2018
Model of Impedance Changes in Unmyelinated Nerve FibersIlya Tarotin, Kirill Aristovich, David Holder
Physiological Measurement|February 21, 2019
Effect of dispersion in nerve on compound action potential and impedance change: a modelling studyIlya Tarotin, Kirill Aristovich, David Holder
Physiological Measurement|April 25, 2020
Beneficial techniques for spatio-temporal imaging in electrical impedance tomographyAlistair Boyle, Kirill Aristovich, Andy Adler
Physiological Measurement|October 13, 2023
Non-invasive imaging of neural activity with magnetic detection electrical impedance tomography (MDEIT): a modelling studyKai Mason, Kirill Aristovich, David Holder
Physiological Measurement|December 16, 2021
Simplifying the hardware requirements for fast neural EIT of peripheral nervesEnrico Ravagli, Svetlana Mastitskaya, David Holder, et al.
Frontiers in Medical Technology|May 4, 2023
A combined cuff electrode array for organ-specific selective stimulation of vagus nerve enabled by Electrical Impedance TomographyEnrico Ravagli, Jeffrey Ardell, David Holder, et al.
Physiological Measurement|May 23, 2017
Reproducible 3D printed head tanks for electrical impedance tomography with realistic shape and conductivity distributionJames Avery, Kirill Aristovich, Barney Low, et al.
Pageof 5

Showing results (1-10 of 44) with videos related to

Sort By:
Pageof 5
Journal of Electrical Bioimpedance|April 18, 2022
Opinion: the Future of Electrical Impedance TomographyKirill Aristovich
Frontiers in Neuroscience|June 10, 2021
Selective Neuromodulation of the Vagus NerveAdam Fitchett, Svetlana Mastitskaya, Kirill Aristovich
Journal of Neural Engineering|June 27, 2019
Simulation of impedance changes with a FEM model of a myelinated nerve fibreIlya Tarotin, Kirill Aristovich, David Holder
IEEE Transactions on Bio-Medical Engineering|July 12, 2018
Model of Impedance Changes in Unmyelinated Nerve FibersIlya Tarotin, Kirill Aristovich, David Holder
Physiological Measurement|February 21, 2019
Effect of dispersion in nerve on compound action potential and impedance change: a modelling studyIlya Tarotin, Kirill Aristovich, David Holder
Physiological Measurement|April 25, 2020
Beneficial techniques for spatio-temporal imaging in electrical impedance tomographyAlistair Boyle, Kirill Aristovich, Andy Adler
Physiological Measurement|October 13, 2023
Non-invasive imaging of neural activity with magnetic detection electrical impedance tomography (MDEIT): a modelling studyKai Mason, Kirill Aristovich, David Holder
Physiological Measurement|December 16, 2021
Simplifying the hardware requirements for fast neural EIT of peripheral nervesEnrico Ravagli, Svetlana Mastitskaya, David Holder, et al.
Frontiers in Medical Technology|May 4, 2023
A combined cuff electrode array for organ-specific selective stimulation of vagus nerve enabled by Electrical Impedance TomographyEnrico Ravagli, Jeffrey Ardell, David Holder, et al.
Physiological Measurement|May 23, 2017
Reproducible 3D printed head tanks for electrical impedance tomography with realistic shape and conductivity distributionJames Avery, Kirill Aristovich, Barney Low, et al.
Pageof 5