Skin sympathetic nerve activity and the temporal clustering of cardiac arrhythmias
Takashi Kusayama, Juyi Wan, Anisiia Doytchinova, Johnson Wong, Ryan A. Kabir, Gloria Mitscher, Susan Straka, Changyu Shen, Thomas H. Everett IV, Peng-Sheng Chen
Takashi Kusayama, Juyi Wan, Anisiia Doytchinova, Johnson Wong, Ryan A. Kabir, Gloria Mitscher, Susan Straka, Changyu Shen, Thomas H. Everett IV, Peng-Sheng Chen
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Clinical Research and Public Health Cardiology

Skin sympathetic nerve activity and the temporal clustering of cardiac arrhythmias

Abstract

BACKGROUND. Simultaneous noninvasively recorded skin sympathetic nerve activity (SKNA) and electrocardiogram (neuECG) can be used to estimate cardiac sympathetic tone. We tested the hypothesis that large and prolonged SKNA bursts are associated with temporal clustering arrhythmias. METHODS. We recorded neuECG in 10 patients (69 ± 10 years old) with atrial fibrillation (AF) episodes and in 6 patients (50 ± 13 years old) with ventricular tachycardia (VT) or fibrillation (VF) episodes. Clustering was defined by an arrhythmic episode followed within 1 minute by spontaneous recurrences of the same arrhythmia. The neuECG signals were bandpass filtered between 500–1000 Hz to display SKNA. RESULTS. There were 22 AF clusters, including 231 AF episodes from 6 patients, and 9 VT/VF clusters, including 99 VT/VF episodes from 3 patients. A total duration of SKNA bursts associated with AF was longer than that during sinus rhythm (78.9 min/hour [interquartile range (IQR) 17.5–201.3] vs. 16.3 min/hour [IQR 14.5–18.5], P = 0.022). The burst amplitude associated with AF in clustering patients was significantly higher than that in nonclustering patients (1.54 μV [IQR 1.35–1.89], n = 114, vs. 1.20 μV [IQR 1.05–1.42], n = 21, P < 0.001). The SKNA bursts associated with VT/VF clusters lasted 9.3 ± 3.1 minutes, with peaks that averaged 1.13 ± 0.38 μV as compared with 0.79 ± 0.11 μV at baseline (P = 0.041). CONCLUSION. Large and sustained sympathetic nerve activities are associated with the temporal clustering of AF and VT/VF. FUNDING. This study was supported in part by NIH grants R42DA043391 (THE), R56 HL71140, TR002208-01, R01 HL139829 (PSC), a Charles Fisch Cardiovascular Research Award endowed by Suzanne B. Knoebel of the Krannert Institute of Cardiology (TK and THE), a Medtronic-Zipes Endowment, and the Indiana University Health-Indiana University School of Medicine Strategic Research Initiative (PSC).

Authors

Takashi Kusayama, Juyi Wan, Anisiia Doytchinova, Johnson Wong, Ryan A. Kabir, Gloria Mitscher, Susan Straka, Changyu Shen, Thomas H. Everett IV, Peng-Sheng Chen

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Figure 2

Representative SKNA burst in AF patient.

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Representative SKNA burst in AF patient. The data came from the same pat...
The data came from the same patient as shown in Figure 1. (A) The proportion of aSKNA recorded every 60 s. The aSKNA indicated 2 Gaussian distributions. The burst threshold is indicated by a red dotted line, which was calculated as the mean representing lower amplitude plus 3 times SD. (B) Actual recordings of the SKNA in Lead I in a 30-s window. These recordings correspond to * (sinus), ** (sinus), and *** (AF) in A. Small SKNA discharges occurred regularly (top). Large SKNA bursts were observed irregularly (middle and bottom). (C) Heart rate (black line) and average SKNA (aSKNA) from Lead I (blue) plotted over time. The onsets of AF are indicated by red (IRAF) and orange (non-IRAF) dots. The large and frequent SKNA bursts occurred during AF. There were smaller bursts of nerve activities associated with sinus rate acceleration. Binary time series graph shows the SKNA burst (black) versus nonbursting period (white), indicating that SKNA bursts preceded the AF clustering episodes. SKNA, skin sympathetic nerve activity; AF, atrial fibrillation; HR, heart rate.