Device-driven cyclic compression of the superior vena cava as a preload reduction strategy to improve cardiac function in heart failure

We evaluated the physiological efficacy and safety of a novel device-based preload reduction strategy that applies external cyclic compression to the superior vena cava (SVC) in a preclinical heart failure model. Heart failure was induced in eleven pigs using ischemia–reperfusion injury, and a 3D-printed SVC compression device was tested under varying compression ratios and protocols. Hemodynamic responses were monitored using right-heart catheterization and pressure–volume loop analysis. Among the tested conditions, cyclic compression at 85% with 20/5-minute compression–release cycles produced the most favorable effects. Cardiac output increased by 27.3% (3.83 to 4.88 L/min, p = 0.008) and stroke volume by 19.5% (38.6 to 46.1 mL, p = 0.006), while mean arterial and pulmonary pressures remained stable. Systemic vascular resistance decreased by 29.0% (1,200 to 852 dyn·s/cm⁵, p = 0.011), accompanied by reductions in left ventricular end-diastolic pressures and improved contractility. These results demonstrate that externally applied cyclic SVC compression effectively reduces preload and augments cardiac performance without compromising hemodynamic stability. Our study provides a proof-of-concept for the clinical utility of a device-driven external cyclic compression of the SVC as an adjunctive therapy for acute decompensated heart failure, especially in perioperative or critical care settings, and supports further development toward an implantable clinical system.