The prevalence of pacemaker patients among the general population and of conducted energy devices (CED) for law enforcement and self-defence is increasing. Consequently, the question whether cardiac pacemaker (CPM) patients are on particular risk becomes increasingly important. The risk of Taser X26 electric interference with implanted CPM has been investigated by numerical simulation at MRI-based anatomical models of CPM patients with devices implanted at conventional sites (left pectoral, right pectoral and abdominal) and with the monopolar CPM electrode placed at the ventricular apex. In spite of 10fold higher peak voltages the different coupling conditions make Taser-induced CPM interference voltages lower than those caused by external cardiac defibrillators. It is shown that electric interference considerably depends on ECD electrode orientation. The most unfavourable conditions are encountered with ECD electrodes aligned with the line from the CPM electrode tip to CPM can (EPC line). It could be shown that worst case interference voltages of monopolar pacemakers of any kind of implantation remain below the pulse immunity level as defined in safety standards of implantable cardiac pacemakers and of cardioverter defibrillators. However, interference voltages exceed CPM sensing thresholds. Therefore, capturing should be expected at Taser X26 contact mode application at any position at the upper part of the body including the abdomen, both at frontal and dorsal positions.
The prevalence of pacemaker patients among the general population and of application of conducted energy devices (CED) for law enforcement and self-defence is increasing. Consequently, the question whether cardiac pacemaker (CPM) patients are at particular risk becomes increasingly important. Electric high-tension pulses of CEDs such as Taser® weapons are used for law enforcement to incapacitate subjects by delivering short-term high-tension pulses. This is done either in distance mode by firing dart electrodes towards the subject or in contact mode by directly pressing the weapon and its integrated two contact electrodes against the body. The Taser X26 emits 5 s long series of pulses with about 18 Hz repetition frequency. Applied voltages depend on load resistance and, hence, on the application site at the body. Since voltages may considerably exceed those of external defibrillators which are limited to 5 kV [
In Germany the annual pacemaker implantation rate is about 0.09% of the population. With an average CPM lifetime of 9.8 years the prevalence of pacemaker patients can be estimated to about 0.8% of the population [
Implanted cardiac stimulators (pacemaker or cardioverter defibrillators) are able to adjust their stimulation rate to physiologic needs by measuring patient’s (residual) intrinsic cardiac activity (electrocardiogram, ECG) via a sensing electrode fixed within the cardiac muscle of either the atrium or ventricle. However, this beneficial approach constitutes also an Archilles heel because input signals make the system vulnerable to induced interference voltages which may be confused with cardiac activity and degrade CPM function. Taser pulses generate 3D intracorporal electric field distributions and, consequently, differences of electric potentials which may be picked up between the tip of the cardiac CPM electrode and the pacemaker can and become interference voltages which add to or replace cardiac ECGs. Usually, pacemaker cans are implanted at the upper part of the body below the clavicle at the left side (left-pectoral) with the electrode forwarded along blood vessels to the target cardiac region such as the ventricular apex (
Experimental results in swine models reported no significant functional changes due to Taser application [
To fill this gap by numerical anatomical modelling this paper quantitatively estimates interference voltages of monopolar pacemakers induced by Taser X26 pulses delivered in contact application.
To allow assessment independent from specific pacemaker models results are compared with requirements of medical device safety standards.
Intracorporal electric field distributions have been determined by numerical simulation. This was performed at self-generated models of pacemaker patients based on the anatomical model NORMAN, an MRI-based model of an average European man (73 kg, 176 cm) with a spatial resolution of 2 × 2 × 2 mm voxels, segmented into 35 different biologic tissues [
Calculation of the induced intracorporal electric field distribution was performed by solving Maxwell’s equations based on the Finite Integration Technique with the software package CST Studio® Suite 2009 [
Taser X26 application was studied with CED electrodes kept in the constant distance of 38 mm according to contact mode application. They were placed at various positions at the upper part of the body both frontal and dorsal. At each position investigation was performed in two orthogonal orientations of the CED electrodes. From fundamental physics the worst case could be expected at alignment along the line from the pacemaker electrode tip to the pacemaker can (EPC line); some slight deviations from the EPC line were necessary due to anatomical reasons (e.g. ribs). For practical reasons distant from the EPC line investigated orientations were vertical and horizontal, respectively.
From the 3D intracorporal electric field distribution pacemaker interference voltages were assessed by determining the electric potential difference between pacemaker electrode tip and pacemaker can. The load-dependence of delivered Taser pulses was accounted for by numerical calculation of position-dependent body impedances and selecting delivered Taser X26 pulses from the results of own measurements accordingly. For this purpose the delivered Taser X26 pulses had been measured [11,12]. Calculated body impedances have been verified by directly measuring body impedances at volunteers with constant contact pressure.
Taser X-26 weapons deliver 5 s long series of pulses repeated with about 18.4 Hz. After an oscillating onset phase the main pulse lasts for about 100 µs. Pulse parameters including time course and repetition frequency vary with load impedance [11-13]. Depending on electrode location the pulse peak amplitude extended to 12 kV (the open circuit voltage exceeded 70 kV). A part of delivered voltages is picked up by the pacemaker.
Delivered CED pulses generate intracorporal electric field distributions with an equipotential zone midway between and fairly perpendicular to the line connecting the two Taser contact electrodes (TCE line) with some variation due to anatomical inhomogeneities. For worst case coupling the electric field distribution is shown within intracorporal planes across the pacemaker can and the ventricular electrode tip for the three different pacemaker patient models (
The highest interference voltages were induced with CED electrodes positioned at one of either end of the EPC line. With increasing distance to the EPC line interference voltages decrease rapidly. With the pacemaker can in left pectoral position the maximum interference voltage with electrodes along the EPC line amounted to 11,500 mVpeak. In the less efficient orientation perpendicular to the EPC line the interference voltage was reduced to 480 mVpeak (
With the electrode at the back at the position corresponding to the frontal worst case position the interfereence voltage was reduced to 580 mVpeak. This is about 20 fold lower than the frontal result but still 290 fold above
the conventional pacemaker sensing threshold of 2 mVpeak-peak. Even if Taser X26 pulses are delivered in the abdominal region and in the back the interference voltage remains still about one order of magnitude above the pacemaker sensing limit. Applications at the back cause smaller interference voltages compared to frontal, however, not at any position. In general interference voltages were well above 2 mVpeak (Figures 3 and 4). At other types of implantation the worst case interference voltage was in the same range than the left pectoral case. The worst case of right-pectoral implantation was 9100 mVpeak. With the pacemaker in abdominal position, the worst case amounted to 9000 mVpeak.
Taser devices deliver peak voltages which may be one order of magnitude higher than pulses of external defibrillators. For pacemakers implanted at left-pectoral site simulation results showed that in worst case (defibrillator electrodes placed medial and lateral of the heart) and maximum output voltage (5 kVpeak) the induced interference voltage amounted to critical 676,000 mVpeak. This explains existing concerns that the higher Taser X26 pulses might damage pacemakers. However, results showed that interference voltages induced by worst case contact application are 59 fold lower than those of external defibrillators. This can be explained by the smaller contact area and smaller spacing of Taser X26 contact electrodes and, therefore, less efficient intracorporal electric field distributions.
The use of the numerical anatomical model of a slim man is already widely accepted and validated for investigations of different kind of electric and electromagnetic interference [8,12,14]. It could be expected that CED application at larger and/or more obese persons would lead to lower interference voltages. This was confirmed by additional simulations made with the Visible Human model of an adult man (103 kg, 186 cm) with the body mass index 29.8 (which is higher than NORMAN’s 23.6). In that case the worst case interference voltage was found to be reduced by 19.6%.
To assess the impact of electric interference the results were compared to the requirements on electromagnetic immunity as defined in medical safety standards of electronic implants. This should allow general device-independent conclusions. Safety standards of implantable cardiac pacemakers [
Since application of external defibrillators to pacemaker patients cannot be excluded, standards require that cardiac pacemakers and cardioverter defibrillators shall not be damaged and their function not be critically degraded by interference pulses up to 270 Vpeak. From this requirement it can be concluded that even worst case Taser contact application interference voltages of 11.5 Vpeak as encountered in this study should not cause adverse effects in electronic medical implants.
The vulnerability of capturing interference signals depends on the pre-set sensing level of cardiac pacemakers. The most appropriate sensing setting for EMC tests is assumed to be 2 mVpeak-peak for monopolar and 0.3 mVpeak-peak for bipolar electrode configurations [17,18]. However, it is acknowledged that state of the art pacemakers can be adjusted to even more sensitive settings such as 0.1 Vpeak-peak. However, in such cases devices may become already vulnerable also to intracorporal biosignals, and physicians have to decide upon such a tradeoff. Simulation results demonstrate that Taser X26 interference peak voltages are well above these sensing thresholds. At pectoral implantation (left or right) they are about two orders of magnitudes higher in the thorax region and still the 10 fold at abdominal sites. In case of abdominally implanted pacemakers higher voltages can also be induced by abdominal hits. Therefore, with a pulse repetition frequency of about 18 Hz right in the frequency bandwidth of the ECG sensing of Taser X26 pulses should be expected at almost any hit position at the upper part of the body, thorax and abdomen. This is independent from the orientation of the contact electrodes and includes frontal and dorsal hits.
However, in daily life sensing and capturing are no rare events. Existing exposure limits of electromagnetic fields such as of electrical appliances and power supply facilities are not set low enough to exclude such interference [
If interference signals are stronger than biosignals pacemakers are able to identify such interference, transiently switch to an asynchronous fix-frequency safety mode and pace with constant rate. If interference signals are suitable to mimic cardiac biosignals depending on pacemaker’s operation mode they may either inhibit or trigger pacing. Inhibition can be ignored, if at the same time the heartbeat is generated by the patient, anyway. If not, this can be tolerated if it lasts only for a 5 s Taser X26 pulse series. Triggering may increase pacing rate, however, only up to a device-specific maximum rate (runaway protection) which for several seconds can be tolerated as well. However, it cannot be excluded that interference could cause persisting change of the operation mode of programmable devices with potential adverse consequences although with much lower probability of occurrence.
This investigation is concentrating on hazards of pacemaker patients related to their CPM. Other sideeffects such as adverse tissue heating or cardiac fibrillation were not investigated. The risk of Taser X26-related cardiac fibrillation has already been analysed in [
At contact application Taser X26 interference with implanted cardiac pacemakers must be taken into account at the entire upper part of the body, both frontal and dorsal. In general, horizontal orientation of Taser weapons proved to be considerably less efficient in inducing interference voltages than vertical orientation. While interference voltages are not high enough to critically damage pacemaker function, sensing and capturing must be expected at any position at the upper part of the body, frontal and dorsal irrespective the site of implantation.
This work was supported by the Austrian Association for Research Funding in co-operation with the Austrian Ministries of Internal Affairs, Justice and National Defence.
The authors wish to thank Dr. P. Dimbylow, Health Protection Agency, for providing his numerical model NORMAN.