Current Density Imaging through Acoustically Encoded Magnetometry: A Theoretical Exploration

TL;DR

This paper explores a theoretical method to improve current density imaging in biological tissues by using acoustically encoded magnetometry, aiming to achieve unique current reconstruction through sound-based spatial encoding.

Contribution

It proposes a novel, speculative approach employing pulsed acoustic waves for spatial encoding to enhance current density imaging in biological systems.

Findings

Theoretical analysis of acoustically encoded magnetometry.

Potential for improved current density reconstruction.

Foundation for future experimental validation.

Abstract

The problem of determining a current density confined to a volume from measurements of the magnetic field it produces exterior to that volume is known to have non-unique solutions. To uniquely determine the current density, or the non-silent components of it, additional spatial encoding of the electric current is needed. In biological systems such as the brain and heart, which generate electric current associated with normal function, a reliable means of generating such additional encoding, on a spatial and temporal scale meaningful to the study of such systems, would be a boon for research. This paper explores a speculative method by which the required additional encoding might be accomplished, on the time scale associated with the propagation of sound across the volume of interest, by means of the application of a radially encoding pulsed acoustic spherical wave.