Source Model of Magnetic Fields of Auditory Evoked Brainstem Responses

S. Ueno; K. Iramina; K. Maekawa; K. Harada; S. Wada; S. Matsuoka

doi:10.1109/TJMJ.1989.4564068

Source Model of Magnetic Fields of Auditory Evoked Brainstem Responses

S. Ueno, K. Iramina, K. Maekawa, K. Harada, S. Wada, S. Matsuoka

Intelligence Science

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Abstract

The origins of auditory evoked brainstem responses (ABRs) are not fully understood. In the present study we investigate a possible mechanism of ABR occurrence. A source model for ABRs is proposed which simulates, in part, ABR waveforms. Pathways of auditory nerves are represented by a combination of five or six straight lines. Using this simple pathway model, the waveforms and spatial distributions of electrical potentials and magnetic fields are simulated. The results show that electrical potentials change with the dipole orientation. The spatial patterns of electrical potentials and magnetic fields also vary as the dipole orientation changes. The spatial patterns of calculated potentials closely simulate the contour maps of wave V in measured ABRs.

Original language	English
Pages (from-to)	614-619
Number of pages	6
Journal	IEEE Translation Journal on Magnetics in Japan
Volume	4
Issue number	10
DOIs	https://doi.org/10.1109/TJMJ.1989.4564068
Publication status	Published - Oct 1989

All Science Journal Classification (ASJC) codes

Engineering (miscellaneous)
General Engineering

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10.1109/TJMJ.1989.4564068

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abstract = "The origins of auditory evoked brainstem responses (ABRs) are not fully understood. In the present study we investigate a possible mechanism of ABR occurrence. A source model for ABRs is proposed which simulates, in part, ABR waveforms. Pathways of auditory nerves are represented by a combination of five or six straight lines. Using this simple pathway model, the waveforms and spatial distributions of electrical potentials and magnetic fields are simulated. The results show that electrical potentials change with the dipole orientation. The spatial patterns of electrical potentials and magnetic fields also vary as the dipole orientation changes. The spatial patterns of calculated potentials closely simulate the contour maps of wave V in measured ABRs.",

author = "S. Ueno and K. Iramina and K. Maekawa and K. Harada and S. Wada and S. Matsuoka",

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AU - Ueno, S.

AU - Iramina, K.

AU - Maekawa, K.

AU - Harada, K.

AU - Wada, S.

AU - Matsuoka, S.

PY - 1989/10

Y1 - 1989/10

N2 - The origins of auditory evoked brainstem responses (ABRs) are not fully understood. In the present study we investigate a possible mechanism of ABR occurrence. A source model for ABRs is proposed which simulates, in part, ABR waveforms. Pathways of auditory nerves are represented by a combination of five or six straight lines. Using this simple pathway model, the waveforms and spatial distributions of electrical potentials and magnetic fields are simulated. The results show that electrical potentials change with the dipole orientation. The spatial patterns of electrical potentials and magnetic fields also vary as the dipole orientation changes. The spatial patterns of calculated potentials closely simulate the contour maps of wave V in measured ABRs.

AB - The origins of auditory evoked brainstem responses (ABRs) are not fully understood. In the present study we investigate a possible mechanism of ABR occurrence. A source model for ABRs is proposed which simulates, in part, ABR waveforms. Pathways of auditory nerves are represented by a combination of five or six straight lines. Using this simple pathway model, the waveforms and spatial distributions of electrical potentials and magnetic fields are simulated. The results show that electrical potentials change with the dipole orientation. The spatial patterns of electrical potentials and magnetic fields also vary as the dipole orientation changes. The spatial patterns of calculated potentials closely simulate the contour maps of wave V in measured ABRs.

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Source Model of Magnetic Fields of Auditory Evoked Brainstem Responses

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