Effects of pirfenidone on scar size and ventricular remodeling after myocardial infarction: a preclinical study.

BACKGROUND: An intense fibrotic response after myocardial infarction (MI) may lead to scar expansion and left ventricular (LV) remodeling. We investigated the effects of the antifibrotic drug pirfenidone in this setting. METHODS: Male Wistar rats were randomized to: sham procedure (n = 13), reperfused MI-induced by ligating the left anterior descending artery (LAD) for 45 min (n = 17), reperfused MI plus standard therapy (aspirin, angiotensin-converting enzyme inhibitor, beta blocker, and mineralocorticoid receptor antagonist) (n = 17), reperfused MI plus pirfenidone alone (n = 17), or reperfused MI plus standard therapy and pirfenidone (n = 17). Rats surviving MI induction underwent cardiac magnetic resonance scans after 72 h and 30 days from MI, and were sacrificed on day 31. RESULTS: Rats completing the whole protocol numbered 11 in the sham group, 9 in the untreated MI group, 8 in the standard treatment group, 9 in the pirfenidone alone group, and 9 in the standard treatment plus pirfenidone group. No significant differences emerged between LV volumes, ejection fraction or mass at 30 days or the differences from 72 h to 30 days. Small, nonsignificant differences between rats on pirfenidone alone vs. those on standard therapy emerged. The total extent of LV fibrosis, quantified as area and percentage of the tissue sample, did not differ significantly between rats on pirfenidone alone vs. those on standard therapy alone. CONCLUSION: Pirfenidone does not have additional effects on LV remodeling or fibrosis compared with standard therapy, but its effects are similar to standard therapy alone.

Cardiovascular Response to Intraneural Right Vagus Nerve Stimulation in Adult Minipig.

OBJECTIVE: This study explored intraneural stimulation of the right thoracic vagus nerve (VN) in sexually mature male minipigs to modulate safe heart rate and blood pressure response. MATERIAL AND METHODS: We employed an intraneural electrode designed for the VN of pigs to perform VN stimulation (VNS). This was delivered using different numbers of contacts on the electrode and different stimulation parameters (amplitude, frequency, and pulse width), identifying the most suitable stimulation configuration. All the parameter ranges had been selected from a computational cardiovascular system model. RESULTS: Clinically relevant responses were observed when stimulating with low current intensities and relatively low frequencies delivered with a single contact. Selecting a biphasic, charge-balanced square wave for VNS with a current amplitude of 500 µA, frequency of 10 Hz, and pulse width of 200 µs, we obtained heart rate reduction of 7.67 ± 5.19 beats per minute, systolic pressure reduction of 5.75 ± 2.59 mmHg, and diastolic pressure reduction of 3.39 ± 1.44 mmHg. CONCLUSION: Heart rate modulation was obtained without inducing any observable adverse effects, underlining the high selectivity of the intraneural approach.

High-Resolution Cardiac Positron Emission Tomography/Computed Tomography for Small Animals.

Positron emission tomography (PET) and computed tomography (CT) are among the most employed diagnostic imaging techniques, and both serve in understanding cardiac function and metabolism. In preclinical research, dedicated scanners with high sensitivity and high spatio-temporal resolution are employed, designed to cope with the demanding technological requirements posed by the small heart size and very high heart rates of mice and rats. In this paper, a bimodal cardiac PET/CT imaging protocol for experimental mouse and/or rat models of cardiac diseases is described, from animal preparation and image acquisition and reconstruction to image processing and visualization. In particular, the 18F-labeled fluorodeoxyglucose ([18F]FDG)-PET scan allows for the measurement and visualization of glucose metabolism in the different segments of the left ventricle (LV). Polar maps are convenient tools to display this information. The CT part consists of a time-resolved 3D reconstruction of the entire heart (4D-CT) using retrospective gating without electrocardiography (ECG) leads, allowing the morphofunctional evaluation of the LV and the subsequent quantification of the most important cardiac function parameters, such as ejection fraction (EF) and stroke volume (SV). Using an integrated PET/CT scanner, this protocol can be executed within the same anesthesia induction without the need to reposition the animal between different scanners. Hence, PET/CT can be seen as a comprehensive tool for the morphofunctional and metabolic evaluation of the heart in several small animal models of cardiac diseases.