Effects of verapamil on regional myocardial blood flow and ST segment. Role of the induced bradycardia

Indocyanine green/doxorubicin-encapsulated functionalized nanoparticles for effective combination therapy against human MDR breast cancer

To overcome low therapeutic efficacy of chemotherapy against multidrug resistance (MDR) breast cancer, a combination therapy system based upon functionalized polymer nanoparticles comprising poly(γ-glutamic acid)-g-poly(lactic-co-glycolic acid) (γ-PGA-g-PLGA) as the major component was developed. The NPs were loaded with doxorubicin (DOX) and indocyanine green (ICG) for dual modality cancer treatment and coated with cholesterol-PEG (C-PEG) for MDR abrogation in treatment of human MDR breast cancer. The in vitro cellular uptake of the DOX/ICG loaded nanoparticles (DI-NPs) by MDR cancer cells was significantly enhanced owing to effective inhibition of the P-gp activity by C-PEG and γ-PGA receptor-mediated endocytosis. DOX localization in cytoplasm and nucleus was observed particularly with the photo-thermal effect that facilitated intracellular drug release. As a result, the C-PEG coated DI-NPs after photo-irradiation exhibited a synergistic effect of combination (chemo/thermal) therapy to depress the proliferation of MDR cancer calls. The ex vivo biodistribution study revealed an enhanced tumor accumulation of C-PEG (2000) coated DI-NPs in MCF-7/MDR tumor-bearing nude mice due to the excellent EPR effects by the NP surface PEGylation. The MDR tumor growth was almost entirely inhibited in the group receiving combination therapy from CP2k-DI-NPs and photo-irradiation along with substantial cell apoptosis of tumor tissues examined by immunohistochemical staining. The results demonstrate a promising dual modality therapy system, CP2k-DI-NPs, developed in this work for effective combination therapy of human MDR breast cancer.

pH-Responsive therapeutic solid lipid nanoparticles for reducing P-glycoprotein-mediated drug efflux of multidrug resistant cancer cells

In this study, a novel pH-responsive cholesterol-PEG adduct-coated solid lipid nanoparticles (C-PEG-SLNs) carrying doxorubicin (DOX) capable of overcoming multidrug resistance (MDR) breast cancer cells is presented. The DOX-loaded SLNs have a mean hydrodynamic diameter of ~100 nm and a low polydispersity index (under 0.20) with a high drug-loading efficiency ranging from 80.8% to 90.6%. The in vitro drug release profiles show that the DOX-loaded SLNs exhibit a pH-controlled drug release behavior with the maximum and minimum unloading percentages of 63.4% at pH 4.7 and 25.2% at pH 7.4, respectively. The DOX-loaded C-PEG-SLNs displayed a superior ability in inhibiting the proliferation of MCF-7/MDR cells. At a DOX concentration of 80 μM, the cell viabilities treated with C-PEG-SLNs were approximately one-third of the group treated with free DOX. The inhibition activity of C-PEG-SLNs could be attributed to the transport of C-PEG to cell membrane, leading to the change of the composition of the cell membrane and thus the inhibition of permeability glycoprotein activity. This hypothesis is supported by the confocal images showing the accumulation of DOX in the nuclei of cancer cells and the localization of C-PEG on the cell membranes. The results of in vivo study further demonstrated that the DOX delivered by the SLNs accumulates predominantly in tumor via enhanced permeability and retention effect, the enhanced passive tumor accumulation due to the loose intercellular junctions of endothelial cells lining inside blood vessels at tumor site, and the lack of lymphatic drainage. The growth of MCF-7/MDR xenografted tumor on Balb/c nude mice was inhibited to ~400 mm³ in volume as compared with the free DOX treatment group, 1,140 mm³, and the group treated with 1,2 distearoyl-sn-glycero-3-phosphoethanolamine-N-[methoxy(polyethylene glycol)] solid lipid nanoparticles, 820 mm³. Analysis of the body weight of nude mice and the histology of organs and tumor after the administration of DOX-loaded SLNs show that the SLNs have no observable side effects. These results indicate that the C-PEG-SLN is a promising platform for the delivery of therapeutic agents for MDR cancer chemotherapy.

Effect of cicletanine on overpacing-induced ST-segment elevation in conscious rabbits. A comparison with verapamil

We compared the effects of cicletanine (10 mg/kg i.v.) and verapamil (0.1 mg/kg i.v.) on heart rate, ventricular effective refractory period, systolic and diastolic arterial blood pressure and overpacing-induced ST-segment elevation detected by right ventricular intracavital electrogram in conscious rabbits. Cicletanine significantly reduced overpacing-induced ST-segment elevation, which is an indicator of myocardial ischemia, and heart rate, but did not influence blood pressure and ventricular effective refractory period. Verapamil did not significantly influence ventricular effective refractory period, blood pressure or heart rate, but reduced the ST-segment elevation induced by frequency loading. These results suggest that acute treatment with cicletanine induces an anti-ischemic effect in the overpaced heart of conscious rabbits.

Diproteverine (BRL 40015): a new type of calcium antagonist with potential antianginal properties

The calcium channel-blocking activity and associated cardiovascular effects of diproteverine, a novel compound derived from papaverine, were investigated. Electrophysiological measurements in sheep Purkinje fibres showed diproteverine to reduce the amplitude of the slow action potential (IC30 = 2 microM) and to shorten the duration of the fast action potential at 50% repolarisation (IC30 = 2.5 microM). Higher concentrations (4-5 times) were required to block block the sodium channel, as assessed by a reduction in Vmax of the fast action potential. Papaverine was found to possess marginal membrane channel-blocking activity and to be much more potent than diproteverine as a cAMP-phosphodiesterase inhibitor. The most significant haemodynamic property of diproteverine, seen in anaesthetised dogs and conscious dogs pretreated with atropine, was to cause a reduction in heart rate. This appeared to be a particular feature of diproteverine as the other calcium antagonists studied produced either a smaller decrease in heart rate or tachycardia as a reflex response to hypotension. In a chronic myocardial infarct model in dogs, diproteverine caused a redistribution of the available coronary blood flow, to the benefit of an ischaemic area of the myocardium. Diproteverine resembled diltiazem in its effects on coronary blood flow, with both these agents being preferable to nifedipine and verapamil, which caused coronary steal in this model. The combination of the reduction in heart rate, to lower cardiac oxygen demand, with the beneficial action on coronary blood flow should result in diproteverine being particularly beneficial for the treatment of angina pectoris.

Effects of four angiotensin I converting enzyme inhibitors on regional myocardial blood flow and ischemic injury during coronary artery occlusion in dogs

The effects of 4 angiotensin I converting enzyme inhibitors (ACEI), captopril, enalapril, ramipril, and trandolapril, were investigated on regional myocardial blood flow (RMBF, radioactive microspheres) distribution in ischemic and nonischemic zones and on ST-segment elevation in ischemic zones during intermittent coronary artery occlusion in anesthetized dogs. The 4 ACEI inhibited plasma ACE activity to an almost similar extent. All similarly reduced systemic blood pressure, an effect related to a decrease in systemic vascular resistance. Heart rate and myocardial contractility were not affected, but myocardial oxygen consumption presumably decreased because of the reduction in afterload. RMBF and their distribution (between epicardial and endocardial layers and between nonischemic and ischemic zones) were not modified by ACEI. Coronary vascular resistance was slightly decreased in nonischemic zones. ACEI had no effect on ST-segment elevation in ischemic zones. Thus, in this experimental model, all ACEI exhibited the same profile, including no change in RMBF and affording no protection against ischemic injury.

Vasodilator synchronized retroperfusion: quantitative assessment of flow-function relation in acutely ischemic canine myocardium

To investigate whether addition of vasodilator drugs can increase the beneficial effects on the ischemic myocardium of diastolic synchronized retroperfusion (DSR), low doses of verapamil (2 micrograms/kg/min) or nitroglycerin (0.7 microgram/kg/min) were infused through DSR in open-chest dogs undergoing 180 minutes of proximal left anterior descending coronary artery occlusion. Verapamil-DSR (n = 6), nitroglycerin-DSR (n = 6) or DSR alone (n = 8, controls) were started 10 minutes after the onset of occlusion and maintained for 170 minutes. Regional myocardial blood flow (MBF) (microspheres) and left ventricular function (endocardial ultrasonic crystals) were simultaneously assessed in nonischemic and ischemic zones in the 3 groups, before and after 10 and 180 minutes of coronary occlusion. DSR alone significantly increased ischemic regional MBF, endocardial/epicardial flow ratio and endocardial segmental length shortening. Verapamil DSR increased both nonischemic and ischemic regional MBF but reduced the endocardial/epicardial flow ratio and worsened ischemic contractile function. Nitroglycerin DSR did not modify ischemic transmural flow compared with DSR alone, but abolished the beneficial endocardial/epicardial blood flow redistribution, resulting in no additional improvement of contractile function. Thus, ischemic MBF and function are not improved by addition of small amounts of verapamil or nitroglycerin to the arterial retroperfusate in this model of acute myocardial ischemia.

Effects of calcium-channel blockers on myocardial preservation during experimental acute myocardial infarction

Calcium antagonists have become accepted agents for the attenuation of myocardial ischemia when it becomes manifest as angina pectoris. However, it is not known whether these agents can protect ischemic myocardium during the early evolution of an acute myocardial infarct. Calcium antagonists could potentially improve myocardial perfusion, by relieving coronary spasm or improving collateral blood flow, and reduce the energy demands of the ischemic myocardium either directly or by reducing heart rate or contractility. In some studies, calcium antagonists have decreased the rate of adenosine triphosphate depletion in ischemia and reduced functional or structural indexes of ischemic injury after relatively brief periods (up to 2 hours) of injury. We have assessed the ability of verapamil to protect severely ischemic myocardium in dogs with a 40-minute test period of circumflex occlusion followed by reperfusion. After 4 days of recovery, infarcts were sized by histologic methods. Untreated dogs had subendocardial infarcts (the more moderately ischemic subepicardial region being salvaged by reperfusion). Pretreatment with verapamil reduced the size of these subendocardial infarcts from 34 +/- 8 to 8 +/- 3% of the ischemic circumflex vascular bed (anatomic area at risk). Thus, verapamil prevented cell death in a substantial proportion of the severely ischemic subendocardial region that otherwise would have died as a result of the 40-minute test period of ischemia. To establish whether verapamil could prevent cell death for a longer period of time in the less severely ischemic subepicardial region, a 3-hour period of coronary occlusion with reperfusion was studied.

Effects of verapamil in patients with acute myocardial infarction: hemodynamics and function of normal and ischemic left ventricular myocardium

We evaluated the effects of intravenous verapamil, a calcium antagonist, on hemodynamics and regional left ventricular (LV) performance in patients with acute myocardial infarction (AMI). Twenty patients having uncomplicated infarction or moderate heart failure were randomized to receive either verapamil or placebo and were studied a mean of 12 hours after onset of symptoms. Verapamil, 7.5 mg intravenously, acutely reduced systolic arterial pressure (p less than 0.0005), systemic vascular resistance, and LV stroke work (p less than 0.005) and rate-pressure product (p less than 0.05); the heart rate did not alter. The Frank-Starling relationship by Swan-Ganz catheter did not change for 1 hour. Segmental wall motion amplitudes were recorded from eight standardized segments around the left ventricle by a multidirectional M-mode echocardiographic technique. The systolic wall motion of the uninvolved LV segments and LV cavity size did not change after verapamil. Verapamil improved mechanical performance in the ischemic segments (p less than 0.005). Therefore, the overall regional contractile function of the left ventricle improved as well (by 11% to 13%, p less than 0.05). This echocardiographic improvement continued after the acute vasodilatory response of intravenous verapamil subsided and was preserved for 1 week, the patients having had oral verapamil, 240 mg daily. Chest pain was relieved in five of the six patients having ongoing slight pain before verapamil injection. No sequential hemodynamic or echocardiographic changes occurred in the placebo-treated patients. Thus, in patients with uncomplicated AMI, verapamil improve contractile function of the acutely ischemic LV segments by hemodynamic unloading and/or by direct myocardial effect, without manifest depression of the uninvolved myocardium.

Comparison of two calcium antagonists, verapamil and fendiline, in an experimental model of myocardial ischaemia mimicking classical angina on effort

1 The effects of verapamil (0.15/kg) and fendiline (3 mg/kg) were studied in anaesthetized, thoracotomised dogs with a critical constriction of the left anterior descending coronary artery, paced in excess of the initial rate by 60-70 beats/min. Epicardial ST-segment elevation and changes in lactate uptake were used to assess the severity of myocardial ischaemia. 2 Both drugs prevented the ST-segment elevation and the reduced lactate uptake that resulted from atrial pacing. 3 The anti-ischaemic effect of fendiline is mainly due to its negative chronotropic action, whereas that of verapamil is due in part to bradycardia and in part to the reduced preload and afterload. In addition, both agents increase coronary flow to the ischaemic area and thus improve the myocardial oxygen supply/oxygen requirement ratio.

Hemodynamic action of verapamil in dogs with controlled aortic pressure--influence of sympathetic activation

Verapamil was given to 18 anesthetized dogs (alpha-chloralose 100 mg/kg) as a bolus injection (200 micrograms/kg) followed by constant rate infusion (10 micrograms/kg per min). Hemodynamic parameters were evaluated before and during verapamil administration. After a suitable period of time for complete reversal of hemodynamic effects, verapamil administration as well as hemodynamic measurements were repeated during graded aortic occlusion. This technique stabilized central aortic pressure so that the level of reflex baroreceptor stimulation could be kept constant. Atrio-ventricular conduction disturbances observed in 5 dogs during balloon occlusion are attributed to lack of sympathetic stimulation. Without balloon occlusion, verapamil produced significant decreases in peripheral systemic vascular resistance and pressure and marked increases in cardiac output. Heart rate, pulmonary arterial and pulmonary wedge pressures did not change significantly. During graded aortic occlusion, systemic resistance and cardiac output were less markedly affected but there was an increase in both pulmonary arterial and wedge pressures.

The effect of verapamil on mechanical performance of acutely ischemic and reperfused myocardium in the conscious dog

The effect of verapamil, an inhibitor of transmembrane calcium flux, was studied in intact conscious dogs with myocardial ischemia produced by inflating a balloon cuff implanted on the left anterior descending coronary artery. Six dogs received a continuous infusion of verapamil (10 microgram/kg per min) beginning prior to coronary occlusion, and six received normal saline infusions. Systolic ejection shortening (SES) was measured from subendocardial ultrasonic crystals implanted in the central ischemic zone (IZ) and border zone (BZ), and in a nonischemic control zone (CZ). Hearts were paced at a constant heart rate with periodic introduction of closely coupled extrasystoles. SES was measured both for normally paced beats and during postextrasystolic potentiation (PESP). Regional myocardial blood flow was measured by injecting radioactive microspheres before, during, and after coronary occlusion. There were no significant differences between verapamil-treated dogs and saline control dogs in mean aortic pressure, heart rate, left ventricular end-diastolic pressure or dP/dt, cardiac output, or regional myocardial blood flow in IZ, BZ, or CZ. Differences in mechanical performance between two groups were noted, however. In the IZ, SES was abolished completely for normally paced beats in both groups but was significantly preserved for PESP beats in the verapamil-treated animals. In the BZ, SES was significantly reduced for normally paced beats only in the saline controls, and PESP responses were preserved to a significantly greater degree in the verapamil-treated animals. These results indicate that verapamil pretreatment exerts beneficial effects upon mechanical performance of ischemic myocardium. Since no changes in systemic hemodynamics or regional myocardial blood flow were observed, the effect may be due to the calcium-antagonistic properties of the agent.

Antianginal and myocardial metabolic properties of verapamil in coronary artery disease

To determine the metabolic cost of administering an experimental calcium antagonist, verapamil, to patients with coronary artery disease, 12 such patients were studied at rest and during stress with atrial pacing before and after intravenous treatment with verapamil (bolus dose of 0.1 mg/kg body weight, followed by infusion at 0.005 mg/kg per min). The mean (+/- standard deviation) aortic pressure at rest (98 +/- 22 mg Hg), coronary sinus blood flow (88 +/- 17 ml/min) and myocardial oxygen consumption (10.7 +/- 2.4 ml O2/min) decreased to 88 +/- 20 mm Hg (p < 0.0004), 77 +/- 14 ml/min (p < 0.03) and 8.8 +/- 2.5 ml O2/min (p < 0.01), respectively, after administration of verapamil. With atrial pacing, these values were 105 +/- 25 mm Hg, 151 +/- 50 ml/min and 18.5 +/- 6.4 ml O2/min, respectively, before infusion of verapamil, and then decreased to 87 +/- 14 mm Hg (p < 0.006), 107 +/- 31 ml/min (p < 0.0002) and 13.3 +/- 4.4 ml O2/min (p < 0.001) during infusion. Angina occurred in all patients with atrial pacing before verapamil (threshold to pain: 93 +/- 67 seconds). After verapamil, the threshold to pain in six patients increased to 191 +/- 183 seconds; and no pain was experienced by the remaining six (p < 0.0005). Before administration of verapamil lactate extraction decreased from 24 +/- 9 to 10 +/- 11 percent (p < 0.0002) during atrial pacing, and 9 (75 percent) of the 12 patients exhibited electrocardiographic S-T segment depressions. After administration of verapamil lactate extraction normalized to 22 +/- 9 percent during atrial pacing, and the electrocardiogram reverted to baseline in all but one patient. These findings indicate that verapamil decreases left ventricular myocardial metabolic demands, and concomitantly greatly increases the threshold to angina.

Effect of myocardial ischaemia and antilipolytic agents on lipolysis and fatty acid metabolism in the in situ dog heart

Myocardial metabolism was studied in open-chest dogs before and during induction of myocardial ischaemia by coronary artery occlusion. Blood was sampled from a local coronary vein draining ischaemic tissue and from coronary sinus draining predominantly nonischaemic tissue. In the basal state, induction of myocardial ischaemia stimulated myocardial lipolysis as shown by release of glycerol from the ischaemic zone. During isoprenaline infusion, free fatty acids (FFA) extraction across the ischaemic myocardium was substantially increased, but no glycerol release occurred. Pretreatment with nicotinic acid or sodium salicylate markedly depressed FFA extraction across ischaemic myocardium, both during basal and isoprenaline stimulated lipolysis and nicotinic acid most likely inhibited lipolysis in the ischaemic zone. Thus, reduced severity of acute ischaemic injury by antilipolytic treatment might be due to a combination of inhibited myocardial lipolysis and reduced FFA extraction.

The role of beta-adrenoceptors in coronary blood flow distribution in normal and ischemic canine myocardium

beta-Adrenoceptor agonists increase myocardial ischemic injury, mainly by elevating myocardial oxygen consumption. Moreover, it has been shown that isoprenaline may "steal" regional myocardial blood flow (RMBF) from ischemic to non ischemic areas and from epicardium to endocardium. The mechanisms of these two isoprenaline-induced redistributions of RMBF have been investigated by the use of radioactive microspheres in an experimental model of canine myocardial ischemia with simultaneous measurement of ST-segment elevation. Isoprenaline increased RMBF in both epi- and endocardial non ischemic areas and in epicardial ischemic areas, leading to a significant decrease in the endo/epi ratio. After atenolol, isoprenaline still increased RMBF but to a lesser extent and the endo/epi ratio was still decreased. Salbutamol, in doses inducing no significant changes in cardiac parameters or myocardial oxygen consumption, produced effects similar to those of isoprenaline. These results indicate a non-homogeneous beta2-stimulation-induced vasodilation in endo- and epicardium, which might be due either to the higher epicardial coronary vasocilatory reserve or to a heterogeneous distribution of transmural beta2-adrenoceptors. Isoprenaline also decreased the ischemic/non ischemic total blood flow ratio (I/NI) and caused further increases in ST-segment elevation. These effects were abolished by atenolol pretreatment, indicating the deleterious effects of isoprenaline-induced tachycardia in this I/NI decrease and in the ischemic injury.

Effects of atenolol on regional myocardial blood flow and ST segment elevation in the canine myocardium

1 The effects of atenolol on regional myocardial blood flow (RMBF) and on ST segment elevation were studied both in normal and ischaemic regions of the myocardium in dogs. Some of the experiments were performed with cardiac pacing or after bilateral stellectomy. 2 In the absence of cardiac pacing, atenolol (1 mg/kg, i.v.) induced a marked reduction in heart rate and contractile force and a decrease in RMBF, which was of the same magnitude in normal and ischaemic areas. There was no modification in the endo/epi flow ratio. ST segment elevation in ischaemic areas was significantly reduced. 3 Bilateral stellectomy induced similar effects to those of atenolol. Atenolol after bilateral stellectomy exhibited no additional effects. 4 In dogs submitted to cardiac pacing, atenolol no longer decreased RMBF and ST segment elevation. 5 These results demonstrate that with atenolol, there is no correlation between bradycardia and the endo/epi flow ratio while there is one between bradycardia and reduction in ST segment elevation.