Inhibition of the Oversensing of Cardiac Pacemakers in Chest CT

Norihiko Akiba; Masashi Takeda; Giichiro Nakaya; Osamu Nakamura; Mika Tsuboi; Joel Matsumoto; Kyoichi Ito; Yasuo Okuyama; Morio Shimada; Kohki Yoshikawa

doi:10.4236/ojmi.2012.24022

Open Journal of Medical Imaging > Vol.2 No.4, December 2012

Inhibition of the Oversensing of Cardiac Pacemakers in Chest CT

Norihiko Akiba, Masashi Takeda, Giichiro Nakaya, Osamu Nakamura, Mika Tsuboi, Joel Matsumoto, Kyoichi Ito, Yasuo Okuyama, Morio Shimada, Kohki Yoshikawa
Department of Clinical Engineering, National Hospital Organization Tokyo Medical Center, Tokyo, Japan.
Department of Radiological Technology, Nihon Institute of Medical Science, Moroyama, Japan.
Department of Radiology, Japanese RedCross Medical Center,Tokyo, Japan.
Department of Radiology, National Hospital Organization Tokyo Medical Center, Tokyo, Japan.
Graduate Division of Medical Health Sciences in Graduate School of Komazawa University, Tokyo, Japan.
Toshiba Medical Systems Corporation, Tokyo, Japan.
DOI: 10.4236/ojmi.2012.24022 PDF HTML 4,498 Downloads 8,230 Views Citations

Abstract

Objectives: The purpose of this study is to identify how to manage oversensing of pacemakers in chest CT. Methods: Four different models of pacemakers were examined to select the pacemaker generating oversensing. To the pacemaker with oversensing, intermittent switching X-ray was exposed using ECG-gated CT helical scan system at prospective CTA mode. IVY Model was used to synchronize the ECG. Only during in the alert period that is non-refractory and sensing is available, intermittent switching X-ray (300 msec/sec) was exposed in chest CT. For comparison, the same intermittent switching X-ray (300 msec/sec) was exposed in the refractory period when sensing was not available. Results: Oversensing was detected only in one of the four pacemakers tested. In this pacemaker, oversensing was generated by exposure of the intermittent switching X-ray in the alert (non-refractory) period, but oversensing was not observed in the refractory period. Conclusion: A pacemaker has alert and refractory periods. Oversensing of a pacemaker was found to be inhibited by selective ECG-synchronized exposure in the refractory period. Since all pacemakers have the refractory period, the results of this study can be widely applied to the patients with pacemakers in chest CT, and their chest CT can be operated safely.

Keywords

Cardiac Pacemaker; Refractory Period; Oversensing; Computed Tomography; Chest CT

Share and Cite:

N. Akiba, M. Takeda, G. Nakaya, O. Nakamura, M. Tsuboi, J. Matsumoto, K. Ito, Y. Okuyama, M. Shimada and K. Yoshikawa, "Inhibition of the Oversensing of Cardiac Pacemakers in Chest CT," Open Journal of Medical Imaging, Vol. 2 No. 4, 2012, pp. 119-124. doi: 10.4236/ojmi.2012.24022.

1. Introduction

In 2005, the first case of the pacemaker-related defect was reported in Japan claiming that a pacemaker induced a partial electric oversensing in X-ray CT [1-8,11,12]. Ministry of Health, Labor and Welfare issued the reminder to medical institutions titling “Precautions for the use of X-ray CT and implantable cardiac pacemakers with regard to their interactions” [11,12].

In 2009, the precautions were revised [13], and recommended to monitor pulses at the fixed pacing mode or to stop X-ray irradiation in the patient with a pacemaker because X-ray irradiation temporarily suppresses the pacing, and may induce bradyarrhythmia with dizziness or fainting.

As of 2011, the reports of oversensing and reset of the cardiac pacemaker still have been observed [7]. Therefore, in this article we investigated the way to inhibit the oversensing in X-ray CT.

2. Materials and Methods

CT unit (Aquilion PRIME, 80-detector row, Toshiba), four models of pacemakers (St. Jude Medical, and Medtronic) and two pacemaker programmers were used. Pacing rate and refractory period were set at 60 ppm and 300 msec, respectively. A pacemaker was attached on the subclavicular fossa of the chest phantom (Kyoto Kagaku) and was scanned by helical CT at 15.6 helical pitch (0.195 beam pitch), rotation time of 0.35 msec, and tube voltage of 120 kVp in Automatic Exposure Control mode 12 (AEC 12) used in Toshiba CT units (Figure 1).

2.1. Detection of the Oversensing of a Pacemaker

Four models of pacemakers were investigated to detect the oversensing induced by non-ECG-gated CT helical scans. The same scan parameters were used with the ones above-mentioned. The time of X-ray exposure to pacemakers was set at 2.0 sec.

2.2. Inhibition of the Oversensing of a Pacemaker

The intermittent switching X-ray was exposed to the pacemaker detected oversensing. ECG-gated CT helical scan was performed in the Prospective CTA Model in Toshiba CT units (Aquilion PRIME, Toshiba Medical Systems, Tokyo, Japan) [14]. IVY Model (Ivy Biomedical Systems, Inc.) was used for ECG synchronizationing the ECG.

In the sensible period (non-refractory period, defined as alert period), intermittent switching X-ray was exposed at 300 msec per second were to the pacemaker attached on the chest phantom. Similarly, the intermittent switching X-ray was exposed in the non-sensible period (refractory period) (Figure 2).

3. Results

3.1. Detection of the Oversensing of a Pacemaker

X-ray was irradiated to the pacemakers in CT (Figure 3). Three (models II - IV) of 4 pacemakers (II - IV) did not observe oversensing (Table 1). Both atrial pacing (AP) and ventricular pacing (VP) were normal in all three pacemakers without oversensing. In the pacemaker (model I) which showed oversensing, AP and VP were changed to atrial oversensing (AS) and ventricular oversensing (VS), respectively (Figure 4). These results show that oversensing suppressed the changes of AP and VP (AP→AS and VP→VS). The time when the pacing was blocked by oversensing was 3.8 sec. Figure 5 shows that oversensing occurred in the atrium and ventricle and that pacing rate was changed by oversensing in the range between 50 and 180 ppm.

Figure 1. Chest CT with a pacemaker.

Figure 2. The image of the timing of intermittent switching exposures to the pacemaker at the interval of 60 ppm. In the sensible period defined as alert period and the non-sensible period defined as refractory period, intermittent switching X-ray was exposed at 300 ms per second in chest phantom CT.

Figure 3. ECG of the pacemakers which did not show oversensing. In ECG, 3 (models II - IV) of 4 pacemakers did not show oversensing after exposure for 2.0 sec. Both atrial pacing (AP) and ventricular pacing (VP) were normal in these 3 pacemakers.

Table 1. The results of 4 pacemaker models after CT irradiation and the results of the over-sensing-positive model I in the alert and refractory periods. Three (models II-IV) of 4 pacemakers did not show oversensing. In the model I which showed oversensing, the intermittent switching exposure induced oversensing in the alert period, but not in the refractory period.

Figure 4. ECG of the pacemaker which observed oversensing. In ECG, one pacemaker (model I) showed oversensing after exposure for 2.0 sec. In this model I, atrial pacing (AP) and ventricular pacing (VP) were changed to the atrial oversensing (AS) and ventricular oversensing (VS), respectively. It is evident that oversensing suppressed the changes of AP and VP (AP→AS and VP→VS). Not-pacing time caused by oversensing was 3.8 sec.

Figure 5. Atrial and ventricular long-term histograms (% of beats) of the pacemaker which observed oversensing (model I). The graphs show that oversensing occurs in the atrium and ventricle, and pacing is changed in the range between 50 and 180 ppm by oversensing.

3.2. Inhibition of the Oversensing of a Pacemaker

Figure 6 shows the results in the sensible alert period. Intermittent switching X-ray was exposed at 300 msec per second and followed chest phantom CT. ECG showed the changes from AP to AS and from VP to VS. These results show that oversensing suppressed the changes of AP and VP (AP→AS and VP→VS, arrows in Figure 6). The time when the pacing was blocked by was oversensing was 4.8 sec (Table 1, Figure 6).

Figure 7 shows the results of the non-sensable refracttory period. The intermittent switching X-ray was exposed at 300 ms per second and followed chest phantom CT. In ECG, both AP and VP were normal and no oversensing was observed (Table 1). Oversensing of the pacemaker was not induced by X-irradiation in the refractory period.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	C. H. McCollough, J. Zhang, A. N. Primak, W. J. Clement and J. R. Buysman, “Effects of CT Irradiation on Implantable Cardiac Rhythm Management Devices,” Radiology, Vol. 243, No. 3, 2007, pp. 766-774. doi:10.1148/radiol.2433060993
[2]	O. Nakamura, G. Nakaya, S. Ogashiwa, A. Hashimoto and M. Kondou, “Experimental Study of the Influence on Pacemakers of X-Rays from Angiocardiography Equipment,” Japanese Journal of Radiological Technology, Vol. 64, No. 3, 2008, pp. 335-341. doi:10.6009/jjrt.64.335
[3]	N. Umezawa, M. Hirose and T. Shinbo, “Verification of Irradiation Conditions of X-Rays That Influence Implantable Cardiac Pacemakers,” Japanese Journal of Radiological Technology, Vol. 64, No. 7, 2008, pp. 795-804. doi:10.6009/jjrt.64.795
[4]	N. Oda, H. Nakajima, H. Abe, S. Koyama and S. Kakeda, “Effect of Diagnostic X-Rays of Implantable Cardiac Pacemakers and Implantable Cardioverter Defibrillators, and It’s Management,” Japanese Journal of Radiological Technology, Vol. 64, No. 7, 2005, pp. 805-813. doi:10.6009/jjrt.64.805
[5]	M. Lewis, “Radiation Dose Issues in Multi-Slice CT Scanning,” Impact Technology Update, No. 3, 2005. http://www.impactscan.org/download/msctdose.pdf
[6]	S. Yamaji, S. Imai and F. Saito, “Does High-Power Computed Tomography Scanning Equipment Affect the Operation of Pacemakers?” Circulation Journal, Vol. 70, No. 2, 2006, pp. 190-197. doi:10.1253/circj.70.190
[7]	T. Ushijima, Y. Yamao, N. Nagasawa, M. Matsuzuki and T. Sasou, “Partial Electrical Reset of CT Irradiation on Implantable Cardiac Devices: Relationship between Reset and Tube Voltage, Tube Current, and Rotation Time,” Japanese Journal of Radiological Technology, Vol. 67, No. 6, 2011, pp. 648-653. doi:10.6009/jjrt.67.648
[8]	N. G. Blamires and J. Myatt, “X-Ray Effects on Pacemaker Type Circuits,” Pacing and Clinical Electrophysiology, Vol. 5, No. 2, 1982, pp. 151-155. doi:10.1111/j.1540-8159.1982.tb02206.x
[9]	D. L. Hayes, P.J. Wang, D.W. Reynolds, M. Estes, J. L. Griffith, et al., “Interference with Cardiac Pacemakers by Cellular Telephones,” The New England Journal of Medicine, Vol. 336, No. 21, 1997, pp. 1473-1479. doi:10.1056/NEJM199705223362101
[10]	M. Niehaus and J. Tebbenjohanns, “Electromagnetic Interference in Patients with Implanted Pacemakers or Cardioverter-Defibrillators,” Heart, Vol. 86, No. 3, 2001, pp. 246-248.
[11]	Pharmaceuticals and Medical Devices Safety Information, No. 213, 2005, pp. 3-4. http://www.pmda.go.jp/english/index.html
[12]	Pharmaceuticals and Medical Devices Safety Information, No. 221, 2006, pp. 12-15. http://www.pmda.go.jp/english/index.html
[13]	Pharmaceuticals and Medical Devices Safety Information, No. 263, 2009, pp. 34-36. http://www.pmda.go.jp/english/index.html
[14]	T. Ota, M. Tsuyuki, M. Okumura, T. Sato and T. Kondo, “Evaluation of Exposure Dose Reduction in Multislice CT Coronary Angiography (MS-CTA) with Prospective ECG-Gated Helical Scan,” Proceedings of SPIE, Vol. 6913, 2008.

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