Autonomic imbalance in cardiovascular disease: molecular mechanisms and emerging therapeutics
Lilian Mott, Jessica L. Caldwell
Abstract
Autonomic imbalance is a key driver of cardiovascular disease progression, arising from disrupted interactions between sympathetic and parasympathetic signaling. This review explores the molecular mechanisms underpinning autonomic dysfunction, emphasizing the roles of β-adrenergic receptor (βAR) signaling, cyclic AMP (cAMP) compartmentation, and cholinergic regulation. Dysregulated cAMP nanodomain signaling, βAR desensitization, impaired vagal tone, and maladaptive autonomic nerve remodeling collectively promote structural, electrophysiological, and functional deterioration. Advances in high-resolution imaging and molecular mapping have revealed previously unrecognized pathways governing second-messenger compartmentation and neuromodulatory feedback loops. These insights are driving the development of next-generation therapeutics designed to selectively restore autonomic balance. Promising strategies include isoform-specific phosphodiesterase inhibitors, vagus nerve stimulation, and axonal modulation therapy, which target norepinephrine and acetylcholine pathways while preserving physiological responsiveness. Integrating pharmacological, neuromodulatory, and molecular approaches represents an evolving frontier for cardiovascular therapeutics. Future strategies will benefit from precision mapping of autonomic circuits, patient-specific profiling, and optimization of therapeutic timing. By linking fundamental molecular signaling with translational advances, this review highlights opportunities to improve treatment precision and efficacy for autonomic dysfunction in cardiovascular disease.