Detection of biological signals from a live mammalian muscle using an early stage diamond quantum sensor

James Luke Webb,Michael Kieschnick,Jan Meijer,Christoffer Olsson,Jocelyn Achard,Luca Troise,Nikolaj Winther Hansen,Kirstine Berg-Sørensen,Alexander Huck,Axel Thielscher,Robert Staacke,Ovidiu Brinza,Jean-François Perrier,Adam M Wojciechowski,Ulrik Lund Andersen

doi:10.1038/s41598-021-81828-x

Abstract

The ability to perform noninvasive and non-contact measurements of electric signals produced by action potentials is essential in biomedicine. A key method to do this is to remotely sense signals by the magnetic field they induce. Existing methods for magnetic field sensing of mammalian tissue, used in techniques such as magnetoencephalography of the brain, require cryogenically cooled superconducting detectors. These have many disadvantages in terms of high cost, flexibility and limited portability as well as poor spatial and temporal resolution. In this work we demonstrate an alternative technique for detecting magnetic fields generated by the current from action potentials in living tissue using nitrogen vacancy centres in diamond. With 50 pT/sqrt{text {Hz}} sensitivity, we show the first measurements of magnetic sensing from mammalian tissue with a diamond sensor using mouse muscle optogenetically activated with blue light. We show these proof of principle measurements can be performed in an ordinary, unshielded lab environment and that the signal can be easily recovered by digital signal processing techniques. Although as yet uncompetitive with probe electrophysiology in terms of sensitivity, we demonstrate the feasibility of sensing action potentials via magnetic field in mammals using a diamond quantum sensor, as a step towards microscopic imaging of electrical activity in a biological sample using nitrogen vacancy centres in diamond.

Highlights

The ability to perform noninvasive and non-contact measurements of electric signals produced by action potentials is essential in biomedicine
We report the first use of a diamond quantum sensor to measure action potentials in vitro from a live mammalian specimen via their magnetic field
The time-varying magnetic field from the specimen was detected using the protocol of optically detected magnetic resonance (ODMR) magnetometry

Summary

Introduction

The ability to perform noninvasive and non-contact measurements of electric signals produced by action potentials is essential in biomedicine. Techniques for sensing biological magnetic fields, for example magnetoencephalography (MEG) of the living brain, have been primarily based on superconducting quantum interference devices (SQUIDs)[6,7,8,9].This approach requires bulky magnetic shielding and cryogenic cooling, preventing proximity studies of living tissue and delivering poor spatial resolution. These disadvantages have limited the use of the technique for dissected tissue microscopy. As yet uncompetitive with probe electrophysiology in terms of sensitivity at this early stage, we consider these measurements an early but important step towards the goal of in vivo biosensing from living specimens using diamond quantum sensing, with the particular end goal of demonstrating sensing and imaging of signals in neural networks in the mammalian b rain[26,27]

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Results

Conclusion