Comprehensive Echocardiographic Assessment of Right Ventricle Function in a Rat Model of Pulmonary Arterial Hypertension.

Pulmonary arterial hypertension (PAH) is a progressive disease caused by vasoconstriction and remodeling of the small arteries in the lungs. This remodeling leads to increased pulmonary vascular resistance, worsened right ventricular function, and premature death. Currently approved therapies for PAH largely target pulmonary vasodilator pathways; however, recent emerging therapeutic modalities are focused on other novel pathways involved in the pathogenesis of the disease, including right ventricle (RV) remodeling. Imaging techniques that allow longitudinal assessment of novel therapeutics are very useful for determining the efficacy of new drugs in preclinical studies. Noninvasive trans-thoracic echocardiography remains the standard approach to evaluating heart function and is widely used in rodent models. However, echocardiographic evaluation of the RV can be challenging due to its anatomical position and structure. In addition, standardized guidelines are lacking for echocardiography in preclinical rodent models, making it difficult to carry out a uniform assessment of RV function across studies in different laboratories. In preclinical studies, the monocrotaline (MCT) injury model in rats is widely used to evaluate drug efficacy for treating PAH. This protocol describes the echocardiographic evaluation of the RV in naïve and MCT-induced PAH rats.

A nephroprotective iodinated contrast agent with cardioprotective properties: A pilot study.

BACKGROUND AND PURPOSE: Evaluation and treatment of acute ischemic syndromes, in the heart and brain, require vessel visualization by iodinated X-ray contrast agents. However, these contrast agents can induce injury, in both the kidneys and target organs themselves. Sulfobutylether beta cyclodextrin (SBECD) added to iohexol (SBECD-iohexol) (Captisol Enabled-iohexol, Ligand Pharmaceuticals, Inc, San Diego, CA) is currently in clinical trials in cardiovascular procedures, to determine its relative renal safety in high-risk patients. Preclinical studies showed that SBECD-iohexol reduced contrast-induced acute kidney injury in rodent models by blocking apoptosis. The current study was undertaken to determine whether SBECD-iohexol is also cardioprotective, in the male rat ischemia-reperfusion model, compared to iohexol alone. METHODS: After anesthesia, the left coronary artery was ligated for 30 min and the ligation released and reperfusion followed for 2 h prior to sacrifice. Groups 1-4 were injected in the tail vein 10 min prior to ischemia with: (1) vehicle; (2) iohexol; (3) SBECD; and (4) SBECD-iohexol. Infarct size, hemodynamics, and serum markers were measured. RESULTS: An eight-fold increase in serum creatine kinase in the iohexol-alone group was observed, compared with no increase in the SBECD-iohexol group. The mean arterial pressure and rate pressure product were depressed in the iohexol-alone group, but not in the SBECD-iohexol group, or controls. No difference in infarct size or serum creatinine among the groups was observed. CONCLUSION: The results of this study suggest that SBECD-iohexol is superior to iohexol alone, for both the preservation of cardiomyocyte integrity and preservation of myocardial function in myocardial ischemia.

The hypotensive effect of intravenous amiodarone is sustained throughout the maintenance infusion period.

1. Hypotension frequently occurs with use of intravenous amiodarone and is managed by slowing the rate of administration. This response has been attributed to the cosolvents in the formulation and is believed to be solely related to the initial loading dose. The present study was performed to determine whether intravenous amiodarone-induced hypotension persists beyond the loading dose and into the maintenance infusion period and also whether hypotension occurs with maintenance level dosing alone. 2. Anaesthetized beagle dogs (n = 7/group) were instrumented to assess haemodynamics. Animals were treated with the human-equivalent dosing regimen (loading dose followed by maintenance infusion) of intravenous amiodarone or control (5% dextrose in water). 3. No haemodynamic changes were observed in the control group during the 6 h study. In contrast, administration of the standard intravenous amiodarone regimen produced rapid and significant decreases in mean aortic pressure, cardiac output and maximum rate of change of left ventricular pressure that persisted throughout the 6 h maintenance infusion period. Administration of amiodarone as the maintenance infusion dose alone produced haemodynamic changes that were similar in magnitude to those observed with administration of the full dosing regimen, but were delayed in onset by approximately 60 min. 4. Dosing with a cosolvent-free formulation of amiodarone (PM101) caused no haemodynamic effects during the 6 h dosing period, indicating that the cardiodepressant effects of intravenous amiodarone were due to its cosolvents. 5. These data suggest that consideration should be given to intravenous amiodarone as a potential cause for sustained hypotension during prolonged infusion.

Characterization of binding, functional activity, and contractile responses of the selective 5-HT1F receptor agonist lasmiditan.

BACKGROUND AND PURPOSE: Triptans are 5-HT1B/1D receptor agonists (that also display 5-HT1F receptor affinity) with antimigraine action, contraindicated in patients with coronary artery disease due to their vasoconstrictor properties. Conversely, lasmiditan was developed as an antimigraine 5-HT1F receptor agonist. To assess the selectivity and cardiovascular effects of lasmiditan, we investigated the binding, functional activity, and in vitro/in vivo vascular effects of lasmiditan and compared it to sumatriptan. EXPERIMENTAL APPROACH: Binding and second messenger activity assays of lasmiditan and other serotoninergic agonists were performed for human 5-HT1A , 5-HT1B , 5-HT1D , 5-ht1E , 5-HT1F , 5-HT2A , 5-HT2B , and 5-HT7 receptors, and the results were correlated with their potency to constrict isolated human coronary arteries (HCAs). Furthermore, concentration-response curves to lasmiditan and sumatriptan were performed in proximal and distal HCA, internal mammary, and middle meningeal arteries. Finally, anaesthetized female beagle dogs received i.v. infusions of lasmiditan or sumatriptan in escalating cumulative doses, and carotid and coronary artery diameters were measured. KEY RESULTS: Lasmiditan showed high selectivity for 5-HT1F receptors. Moreover, the functional potency of the analysed compounds to inhibit cAMP increase through 5-HT1B receptor activation positively correlated with their potency to contract HCA. In isolated human arteries, sumatriptan, but not lasmiditan, induced contractions. Likewise, in vivo, sumatriptan decreased coronary and carotid artery diameters at clinically relevant doses, while lasmiditan was devoid of vasoconstrictor activity at all doses tested. CONCLUSIONS AND IMPLICATIONS: Lasmiditan is a selective 5-HT1F receptor agonist devoid of vasoconstrictor activity. This may represent a cardiovascular safety advantage when compared to the triptans.

Preclinical Studies of a Kidney Safe Iodinated Contrast Agent.

BACKGROUND AND PURPOSE: Contrast-induced acute kidney injury (CI-AKI) is a serious complication of the use of iodinated contrast agents. This problem is particularly acute in interventional neurology and interventional cardiology, probably due to the intra-arterial route of injection, high contrast volumes, and preexisting risk factors of these patients. In an attempt to develop a contrast agent that is less damaging to the kidneys, we have studied the effects of adding a small amount of the substituted cyclodextrin, sulfobutyl-ether-ß-cyclodextrin (SBECD), to iohexol in rodent models of renal toxicity. METHODS: Renally compromised mice and rats were injected with iohexol and iohexol-SBECD via the tail vein. The renal pathology, creatinine clearance, and survival benefits of iohexol-SBECD were studied. The safety of direct intra-arterial injection of the iohexol-SBECD formulation was studied in a dog heart model system. Mechanism of action studies in cell culture model using a human kidney cell line was performed using flow cytometry. RESULTS: Nephrotoxicity was significantly reduced using iohexol-SBECD compared to iohexol alone, at mole ratios of iohexol:SBECD of 1:0.025. SBECD increased survival from 50% to 88% in a rat survival study. In the dog heart model, iohexol-SBECD was safe. Cell culture studies suggest that SBECD interferes with the early stages of contrast-induced apoptosis in a human renal cell line. CONCLUSION: We have shown that the addition of a small amount of SBECD (one molecule of SBECD per 40 iohexol molecules) significantly protects rodent kidneys from CI-AKI. Further development of this new formulation of iodinated contrast is warranted.

C-122, a novel antagonist of serotonin receptor 5-HT2B, prevents monocrotaline-induced pulmonary arterial hypertension in rats.

Pulmonary arterial hypertension (PAH) is a chronic disease characterized by sustained elevation of pulmonary arterial pressure that leads to right ventricle failure and death. Pulmonary resistance arterioles in PAH undergo progressive narrowing and/or occlusion. Currently approved therapies for PAH are directed primarily at relief of symptoms by interfering with vasoconstrictive signals, but do not halt the microvascular cytoproliferative process. In this study we show that C-122 (2-amino-N-(2-{4-[3-(2-trifluoromethyl-phenothiazin-10-yl)-propyl]-piperazin-1-yl}-ethyl)-acetamide trihydrochloride, a novel antagonist of serotonin receptor 5-HT(2B) (Ki=5.2 nM, IC(50)=6.9 nM), when administered to rats for three weeks in daily oral 10mg/kg doses, prevents not only monocrotaline (MCT)-induced elevations in pressure in the pulmonary arterial circuit (19 ± 0.9 mmHg vs. 28 ± 2 mmHg in MCT-vehicle group, P<0.05) and hypertrophy of the right ventricle (right ventricular wt./body wt. ratio 0.52 ± 0.02 vs. 0.64 ± 0.04 in MCT-vehicle group, P<0.05), but also muscularization of pulmonary arterioles (23% vs. 56% fully muscularized in MCT-vehicle group, P<0.05), and perivascular fibrosis in the lung. C-122 is orally absorbed in the rat, and partitions strongly into multiple tissues, including heart and lung. C-122 has significant off-target antagonist activity for histamine H-1 and several dopamine receptors, but shows no evidence of crossing the blood-brain barrier after a single 10mg/kg oral dose in rats. We conclude that C-122 can prevent microvascular remodeling and associated elevated pressures in the rat MCT model for PAH, and offers promise as a new therapeutic entity to suppress vascular smooth muscle cell proliferation in PAH patients.

PM101: a cyclodextrin-based intravenous formulation of amiodarone devoid of adverse hemodynamic effects.

Intravenous amiodarone (Amiodarone i.v.) is widely used to treat cardiac arrhythmias. The most frequent clinical adverse event associated with Amiodarone i.v. administration is systemic hypotension which has been attributed to the cosolvents used in the formulation, polysorbate 80 and benzyl alcohol. To minimize hypotension Amiodarone i.v. is diluted in 5% dextrose in water prior to administration and slowly infused. PM101 is a novel intravenous formulation that uses sulfobutylether-7-beta-cyclodextrin to solubilize amiodarone, and thus should be devoid of the untoward hemodynamic effects associated with polysorbate 80 and benzyl alcohol. Beagle dogs (n=7/group) were anesthetized with morphine and alpha-chloralose and instrumented to assess aortic blood pressure, cardiac output, cardiac contractility, and heart rate. Animals were treated with the U.S. approved human-equivalent loading dose (2.14 mg/kg) of Amiodarone i.v., PM101, and their respective vehicle controls. Administration of Amiodarone i.v. rapidly and significantly decreased mean aortic pressure, cardiac output, and cardiac contractility. A significant increase in heart rate was also observed as was a transient, but not significant, decrease in systemic vascular resistance. A similar pattern of rapid and significant hemodynamic changes was produced by the Amiodarone i.v. Vehicle (polysorbate 80/benzyl alcohol) alone. In marked contrast, PM101 and its vehicle produced no significant hemodynamic effects. This study provides a useful model for the continued search for a safe and effective intravenous amiodarone formulation devoid of the hypotensive risk associated with the current commercial formulation.

Comparison of the cardiac electrophysiology and general toxicology of two formulations of intravenous amiodarone in dogs.

Intravenous amiodarone (AIV) must be administered slowly after dilution to avoid hypotension, which is due to the cosolvents polysorbate 80 and benzyl alcohol used in its formulation. PM101 is a formulation of amiodarone devoid of these cosolvents, which enables bolus administration. We evaluated any potential toxicity or exaggerated adverse cardiac electrophysiologic effects of PM101 compared with AIV and control. Beagle dogs were treated with the human-equivalent amiodarone loading dose (2.14 mg/kg) with PM101 (bolus push) or AIV (10 min infusion in the toxicology study and bolus push in the electrophysiology study) followed by maintenance infusion (0.014 mg kg(-1) min(-1) through 6 h followed by 0.007 mg kg(-1) min(-1) through 14 days) or a control. General toxicology was assessed in conscious dogs over 14 days. Cardiac electrophysiology was assessed in a separate cohort of anesthetized dogs during the first 20 min of dosing. In the toxicology study, dosing in all animals in the AIV group was terminated within 17 min of initiation due to a severe hypersensitivity reaction. There were no acute adverse clinical signs in the PM101 or control groups. There were no significant effects on body weight or ECG parameters, and no adverse histomorphologic changes were seen in dogs that received PM101 or AIV. No significant exaggerated cardiac electrophysiologic effects of the approved doses PM101 or AIV were observed. PM101 may represent a formulation of intravenous amiodarone that could be administered rapidly without dilution in the setting of life-threatening cardiac arrhythmias.

The dog's role in the preclinical assessment of QT interval prolongation.

During the development of a new therapeutic, few pharmacodyamic outcomes currently receive as much scrutiny as the effect of a potential medication on the electrocardiographic QT interval. The recent withdrawal from marketing of several drugs due to potential drug-related cardiac arrhythmias have greatly increased concern about drug-related changes on the QT interval. In order to reduce the incidence of these idiosyncratic episodes, regulatory agencies have suggested that sponsors use more rigorous methodology during the safety evaluation of new pharmaceuticals. Along with enhanced electrocardiographic assessments during clinical trials, advanced preclinical examinations of effect on QT interval and ventricular repolarization have become de rigueur. In this arena, the beagle dog is the preclinical species often associated with the most reliable predictivity for human safety assessment. To this end, canine models of cardiovascular safety assessment are discussed along with the relevance of these assays to human electrocardiography.