Magnetocardiography

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Magnetocardiography (MCG) is a technique to measure the magnetic fields produced by electrical activity in the heart using extremely sensitive devices such as the Superconducting Quantum Interference Device (SQUIDs). If the magnetic field is measured using a multichannel device, a map of the magnetic field is obtained over the chest; from such a map, using mathematical algorithms that take into account the conductivity structure of the torso, it is possible to locate the source of the activity. For example, sources of abnormal rhythms or arrhythmia, may be located using MCG.

The first MCG measurements were made by Baule and McFee[1] using two large coils placed over the chest, connected in opposition to cancel out the relatively large magnetic background. Heart signals were indeed seen, but were very noisy. The next development was by David Cohen[2], who used a magnetically-shielded room to reduce the background, and a smaller coil with better electronics; the heart signals were now less noisy, allowing a magnetic map to be made, verifying the magnetic properties and source of the signal. However, the use of an inherently noisy coil detector discouraged widespread interest in the MCG. The turning point came with the development of the sensitive detector called the SQUID (superconducting quantum interference device) by James Zimmerman[3]. The combination of this detector and Cohen's new shielded room at MIT allowed the MCG signal to be seen as clearly as the conventional electrocardiogram, and the publication of this result[4] marked the real beginning of magnetocardiography (as well as Biomagnetism generally).


Magnetocardiography is now used in various laboratories and clinics around the world, both for research on the normal human heart, and for clinical diagnosis[5].

[edit] Notes

  1. ^ Baule G.M, McFee R. Detection of the magnetic field of the heart. American Heart Journal 1963;66:95-6.
  2. ^ Cohen D. Magnetic fields around the torso: production by electrical activity of the human heart. Science 1967;156:652-4.
  3. ^ Zimmerman, J.E., Theine, P., and Harding, J.T. Design and operation of stable rf-biased superconducting point-contact quantum devices, etc. Journal of Applied Physics 1970; 41:1572-1580.
  4. ^ Cohen D, Edelsack EA, Zimmerman JE. Magnetocardiograms taken inside a shielded room with a superconducting point-contact magnetometer. Applied Physics Letters 1970;16(7): 278-80.
  5. ^ Koch, H. Recent advances in magnetocardiography. Journal of Electrocardiology 2004; 37: 117-122.

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