Isoflurane and Surgical Stress Disrupt Fatty Acid and Carbon Metabolism Leading to Cardiomyopathy

Aging alters cardiac resilience to anesthetic and surgical stress, yet the molecular basis of these effects remains poorly understood. To define age-dependent cardiac transcriptional responses to isoflurane exposure and operative (ISO/OP) stress, we analyzed gene expression profiles across young adult (3m), late middle-aged (17m), and geriatric mice (27m) following short-term 2 h ISO/OP exposure. At 24 h after cessation, all age groups exhibited distinct cardiac transcriptional signatures separating ISO/OP from sham controls. In young adult hearts, transcriptional alterations 24 hours after cessation of ISO/OP were characterized by dysregulation of small molecule catabolic processes, fatty acid metabolism, disruptions to protein processing in endoplasmic reticulum and cytoskeletal organization. Late middle-aged mice displayed amplified perturbations in lipid metabolism alongside suppression of muscle system and calcium signaling pathways, while old mice showed robust activation of PPAR and AMPK signaling and downregulation of genes governing contractility and morphogenesis. In contrast, geriatric mice showed upregulation of fatty acid metabolic pathways, robust activation of PPAR and AMPK signaling, coupled with suppression of muscle differentiation and actin organization following ISO exposure, indicating a maladaptive metabolic reprogramming. Overlapping DEGs across all age groups converged on pathways regulating oxidative stress, Ca ²⁺ handling, hypertrophy, and energy metabolism, suggesting a conserved but age-intensified cardiac stress response. Longitudinal profiling in aged mice revealed persistent transcriptomic remodeling five weeks after stress. Crucially, this remodeling was observed even after ISO exposure alone, indicating that general anesthesia is a primary driver of this long-term effect. This persistent signature was marked by mitochondrial dysfunction and dysregulation of genes associated with diabetic cardiomyopathy, extracellular matrix integrity, and neurodegenerative signaling. Together, these findings identify isoflurane exposure as a potent inducer of persistent, age-dependent metabolic and structural reprogramming in the heart, implicating impaired lipid utilization and mitochondrial homeostasis as central mechanisms linking the perioperative period, and specifically anesthetic exposure, to long-term cardiovascular vulnerability.