1

Magnetocardiogramof a Healthy Individual

Copyright © 2005 CardioMag Imaging, Inc. (CMI) 450 Duane Av, Schenectady, NY 12304, USA

2

Patient With Normal Coronary Arteries

Copyright © 2005 CardioMag Imaging, Inc. (CMI) 450 Duane Av, Schenectady, NY 12304, USA

Demographic data Basic parameters

Gender Age BMI HR BP EF

female 65 31 80 130:80 --

Risk factors

DM HT Prior MI Prior CAD Smoker HLP

no no no no yes no

Other test results

ECG ECHO TNI Indication

normal normal normal ACS

Coronary Angiography

LAD LCX RCA

stenosis location stenosis location stenosis location

3

Atrial Activity of the Normal Control

Copyright © 2005 CardioMag Imaging, Inc. (CMI) 450 Duane Av, Schenectady, NY 12304, USA

The vector in the animated colour magnetic field map depicts the location and orientation of a magnetic dipole that is equivalent to the source of the electric activity. Interpretation of the vector’s dynamics (changes over time) helps understanding the underlying electrical process.

4

Right Atrial Depolarization

Copyright © 2005 CardioMag Imaging, Inc. (CMI) 450 Duane Av, Schenectady, NY 12304, USA

The history of vectors indicates that the electric activity in the right atrium is uniform and focused.

5

Left Atrial Depolarization

Copyright © 2005 CardioMag Imaging, Inc. (CMI) 450 Duane Av, Schenectady, NY 12304, USA

A clean transition of electrical activity from right to left atrium is visible.

6

Atrial Repolarization

Copyright © 2005 CardioMag Imaging, Inc. (CMI) 450 Duane Av, Schenectady, NY 12304, USA

Electric activity during atrial repolarization is directed opposite to depolarization. Due to lower signal strength its interpretation requires experience. In case of an accessory pathway a second dipolar structure would be visible. Note: for better visibility only the beginning of atrial repolarization is shown.

7

Depolarization of the Intra-ventricular Septum

Copyright © 2005 CardioMag Imaging, Inc. (CMI) 450 Duane Av, Schenectady, NY 12304, USA

The AV node carries the activity to the intraventricular septum, which depolarizes. The electric current propagates along the septum until it reaches the apex.

8

Ventricular Depolarization

Copyright © 2005 CardioMag Imaging, Inc. (CMI) 450 Duane Av, Schenectady, NY 12304, USA

The ventricles depolarize. The map shows a superposition of LV and RV activity. The LV free wall’s magnetic signature dominates over that of the RV. However, the effect of a conduction abnormality in the RV would be visible indirectly through a change in pattern and polarity.

9

Late Ventricular Depolarization

Copyright © 2005 CardioMag Imaging, Inc. (CMI) 450 Duane Av, Schenectady, NY 12304, USA

The electric activity moves from anterior to posterior indicated by an increasing distance of the two maxima. Note that the polarity of the magnetic field flips by 180 degrees. The 3D animation nicely reflects the spatial propagation of the vector.

10

The ‘ST Segment’

Copyright © 2005 CardioMag Imaging, Inc. (CMI) 450 Duane Av, Schenectady, NY 12304, USA

The ST segment in the normal MCG is rather flat: MCG traces in the butterfly plot are bundled densely. The map often shows a random distribution of magnetic fields. This is due to the fact that cardiac electric activity is close to zero thus leading to a very small signal to noise ratio. In the present case it can be concluded that the remaining activity in the ST segment is mostly due to non-cardiac sources (noise).

11

Ventricular Repolarization

Copyright © 2005 CardioMag Imaging, Inc. (CMI) 450 Duane Av, Schenectady, NY 12304, USA

In the normal heart repolarization usually begins in the last area of the heart to have been depolarized, and then travels backward, in the opposite direction of the wave of depolarization. The approaching wave of depolarization and the receding wave of repolarization generate similar field maps both in pattern and polarity. The normal heart shows a uniform, homogenous, and stable field distribution.