Abstract Body:
Ventricular tachycardia (VT) is a dangerous arrhythmia that occurs in structurally and electrically heterogenous regions of the diseased heart, leading to sudden cardiac arrest and death if left untreated. One of the main drivers underlying the arrhythmogenic substrate is abnormal remodeling of the autonomic nervous system after cardiac injury, resulting in a heterogenous distribution of sympathetic innervation and subsequent ventricular arrhythmia. In patients with VT refractory to conventional therapy, noninvasive cardiac stereotactic body radiotherapy (SBRT) has emerged as a promising new treatment. Here, we investigated whether cardiac radiotherapy homogenizes the arrhythmogenic substrate through induction of cardiac sympathetic nerve innervation and activity in a closed-chest ischemia reperfusion murine model of ischemic heart failure.

Using single nucleus-RNA sequencing, we identified global transcriptomic changes in the left ventricle 6 weeks after 25 Gray (Gy) cardiac X-ray radiation. Notably, these changes included increased expression of neurotrophins such as brain derived neurotrophic factor, a growth factor essential for neuronal survival and development, in irradiated hearts compared to sham controls. Consequently, Western blot and immunofluorescence showed increased expression of the sympathetic neuronal markers tyrosine hydroxylase and neuropeptide Y at the scar border zone of irradiated mice. Similar immunofluorescence results were observed at the irradiated border zone from the explanted heart of a patient previously targeted with 25 Gy compared to a nontargeted remote region within the same heart. These findings suggest a novel role for radiation-induced remodeling of the sympathetic nervous system in the anti-arrhythmic response to SBRT.