Comparative pharmacokinetics of verapamil and norverapamil in normal and ulcerative colitis rats after oral administration of low and high dose verapamil by UPLC-MS/MS.

In this study, UC rat model was established by administration of 5% (w/v) dextran sulfate sodium, and the pharmacokinetics of verapamil and norverapamil were evaluated in normal and UC rats using UPLC-MS/MS after oral administration of 5 mg/kg and 50 mg/kg verapamil.The peak concentration (Cmax) and the area under plasma concentration-time curves (AUC) of verapamil in UC rats after oral administration of 5 mg/kg were significantly greater (2.5 times and 2 times, respectively) than those in normal rats, but the clearance rate (Cl) was significantly lower (by 50%). For norverapamil, Cmax and AUC were significantly greater (2.8 times and 2.5 times, respectively), and Cl was significantly lower (by 45%). But, pharmacokinetic parameters of verapamil and norverapamil after oral administration of 50 mg/kg were no significant differences between UC and normal rats.The better absorption and poor excretion for low-dose verapamil may be attributed to down-regulation of P-gp expression in the intestine and kidney. No significant differences of pharmacokinetic parameters for high-dose verapamil may be explained as the saturation of an efflux mechanism.The findings of this study suggested that in UC patients, doses of verapamil should be decreased when low-dose verapamil was orally administrated.

A pharmacokinetic drug-drug interaction model of simvastatin and verapamil in humans.

BACKGROUND: Verapamil is a calcium channel blocker commonly used in treatments of hypertension. Verapamil and its active metabolite, norverapamil, are known to be CYP3A4 inhibitors. Co-administration of verapamil with CYP3A4 substrates can alter the pharmacokinetics of the substrates. Simvastatin, a commonly used HMG-CoA reductase inhibitor for the treatment of hypercholesterolemia is extensively metabolized by CYP3A4. Therefore, concomitant use of simvastatin and verapamil can increase simvastatin plasma concentration levels, resulting in a higher risk of rhabdomyolysis, a serious adverse drug reaction. Even though, pharmacokinetic data regarding the interaction between both drugs have been published, their use is limited to semiquantitative applications. Therefore, we aimed to develop a mathematical model describing drug-drug interaction between simvastatin and verapamil in humans. METHODS: Eligible pharmacokinetic interaction study between simvastatin and verapamil in humans was selected from PubMed database. The concentration-time courses from this study were digitally extracted and used for model development. RESULTS: The drug-drug interaction between simvastatin and verapamil was modeled simultaneously with a two compartment model for verapamil with its active metabolite, norverapamil and a one compartment model for simvastatin with its active form, simvastatin hydroxy acid. The effects of verapamil and norverapamil on pharmacokinetics of simvastatin and its active form, simvastatin hydroxy acid were described by Michaelis-Menten equation. Simulated simvastatin and simvastatin hydroxy acid concentrations obtained from the final model produced a good fit to the dataset from a literature. The final model adequately describes pharmacokinetic interaction between simvastatin and verapamil which can be helpful in prediction of rhabdomyolysis in patients with concurrent use of these drugs.

Effect of Huang-Lian-Jie-Du-Decoction on pharmacokinetics of verapamil in rats.

OBJECTIVES: The aim was to investigate the effect of Huang-Lian-Jie-Du-Decoction (HLJDD) on the pharmacokinetic behaviour of verapamil in rats. METHODS: Rats orally received 3.33 g/kg of HLJDD extract for 14 days, and pharmacokinetics of verapamil was investigated after oral and intravenous verapamil. Norverapamil formation for assessing cytochrome P450 3A activity in hepatic and intestinal microsomes of the HLJDD-treated rats was investigated. The inhibitory effect of berberine on the formation of norverapamil in intestinal and hepatic microsomes was also evaluated. KEY FINDINGS: HLJDD treatment increased the plasma concentration of verapamil and decreased the plasma concentration of norverapamil, resulting in a 24% increase in the AUC(0-480) of verapamil and a 25% reduction in the AUC(0-480) of norverapamil after oral administration. However, HLJDD did not alter the pharmacokinetic behaviour of verapamil after intravenous administration. Norverapamil formation showed biphasic kinetics in both intestinal and hepatic microsomes. HLJDD treatment significantly decreased the intrinsic clearance of verapamil in intestinal microsomes, but had no effect on the hepatic metabolism of verapamil. Berberine also inhibited norverapamil formation in both intestinal and hepatic microsomes; the extent of inhibition was larger in intestinal microsomes. CONCLUSIONS: HLJDD displayed a route-dependent effect on the pharmacokinetics of verapamil in rats. HLJDD treatment increased the bioavailability of verapamil partly via inhibiting first-pass verapamil metabolism in the intestine.

Effects of angiotensin II blockade on inflammation-induced alterations of pharmacokinetics and pharmacodynamics of calcium channel blockers.

BACKGROUND AND PURPOSE: Inflammation elevates plasma verapamil concentrations but diminishes pharmacological response. Angiotensin II is a pro-inflammatory mediator. We examined the effect of angiotensin II receptor blockade on the pharmacokinetics and pharmacodynamics of verapamil, as well as the binding properties and amounts of its target protein in calcium channels, in a rat model of inflammation. EXPERIMENTAL APPROACH: We used 4 groups of male Sprague-Dawley rats (220-280 g): inflamed-placebo, inflamed-treated, control-placebo and control-treated. Inflammation as pre-adjuvant arthritis was induced by injecting Mycobacterium butyricum on day 0. From day 6 to 12, 30 mg kg(-1) oral valsartan or placebo was administered twice daily. On day 12, a single oral dose of 25 mg kg(-1) verapamil was administered and prolongation of the PR interval measured and plasma samples collected for verapamil and nor-verapamil analysis. The amounts of the target protein Ca(v)1.2 subunit of L-type calcium channels in heart was measured by Western blotting and ligand binding with (3)H-nitrendipine. KEY RESULTS: Inflammation reduced effects of verapamil, although plasma drug concentrations were increased. This was associated with a reduction in ligand binding capacity and amount of the calcium channel target protein in heart extracts. Valsartan significantly reversed the down-regulating effect of inflammation on verapamil's effects on the PR interval, and the lower level of protein binding and the decreased target protein. CONCLUSIONS AND IMPLICATIONS: Reduced responses to calcium channel blockers in inflammatory conditions appeared to be due to a reduced amount of target protein that was reversed by the angiotensin II antagonist, valsartan.

Effect of naringin pretreatment on bioavailability of verapamil in rabbits.

The aim of present study is to investigate the effect of naringin on the pharmacokinetics of verapamil and its major metabolite, norverapamil in rabbits. The pharmacokinetic parameters of verapamil and norverapamil were determined after administering verapamil (9 mg/kg) orally to rabbits in the pretreated with naringin (1.5, 7.5, and 15 mg/kg). Naringin pretreatment significantly altered the pharmacokinetic parameters of verapamil. Compared with the control group (given verapamil alone), the Ka, Cmax and AUC of verapamil were significantly (p<0.05 or p<0.01) increased in the pretreatment of naringin, However there were no significant change in Tmax and t1/2 of verapamil. Consequently, pretreatment of naringin significantly (p<0.05, p<0.01) increased the AB% of verapamil significantly in a dose dependent manner (p<0.05 or p<0.01), and elevated the RB% of verapamil by 1.26- to 1.69-fold. the MR of verapamil were significantly (p<0.05) increased in the pretreatment of naringin, implying that pretreatment of naringin may effectively inhibit the CYP3A4-mediated metabolism of verapamil. In conclusion, pretreatment of naringin enhanced the oral bioavailability of verapamil. Based on these results, the verapamil dosage should be adjusted when given with naringin or a naringin-containing dietary supplement.

Multidrug reverting activity toward leukemia cells in a group of new verapamil analogues with low cardiovascular activity.

The development of refractory disease is often associated with the overexpression of multidrug resistance (MDR) proteins, especially in several hematological malignancies, such as acute myeloid leukemias (AML), multiple myeloma (MM) and non-Hodgkin's lymphomas (NHL). Since the recognition of these proteins, several attempts have been made to modulate their expression and activity (protein kinase C inhibitors, anti-MDR-1 oligonucleotides, pharmacological competitors and transcriptional inhibitors). Six new compounds (MM 36, CTS 4, CTS 9, CTS 12, CTS 27 and CTS 41), derived from verapamil (VRP), were designed and synthesized to improve their MDR-reverting activity and reduce cardiovascular effects. Cytotoxicity (WST-1 methods) and functional (calcein-acetoxymethyl (Calcein-AM)) assays were performed on a resistant cell line K-562/doxR and on the mononuclear cells (MNCs) of patients with AML. Furthermore, the six molecules were tested for their vasodilator, inotropic and chronotropic activity on guinea pig aortic strip and isolated atrium preparations, respectively. Comparison between survival plots and relative ID50, obtained from the K-562/doxR cells treated with Idarubicin (IDA), in the presence or absence of inhibitors, showed that these compounds function well. All the resistance modifying agents potentiated IDA activity inducing a significant reduction (P<0.01) in ID(50) values in comparison to VRP at each of the concentrations tested, but MM 36, CTS 27 and CTS 41 demonstrated the strongest activity. Results obtained from the MNCs were superimposible to K-562/doxR. Further studies on pump functional analysis confirmed the cytotoxic test results: MM 36, CTS 27 and CTS 41 showed a striking inhibition of P-glycoprotein (Pgp) efflux in K-562/doxR and MNCs. Cardiovascular activity of MM 36, CTS 27 and CTS 41, that are the most interesting compounds as MDR inhibitors, followed this course: MM 36>CTS 27>CTS 41, the last one presenting no cardiovascular activity. Chemosensivity to IDA in K-562/doxR cells and AML blasts could be enhanced in vitro by the adjuvant use of the six new VRP analogues. Compared to VRP, all the new compounds presented good MDR-reverting- and reduced cardiovascular activities along with no vasorelaxant effects. The particularly favourable results in some cases (MM 36, CTS 27 and CTS 41) suggests that anti-MDR activity should be further evaluated in clinical trials in patients with myeloid malignancies.

Opposite effects of a single IIIS5 mutation on phenylalkylamine and dihydropyridine interaction with L-type Ca2+ channels.

Replacement of L-type Ca(2+) channel alpha(1) subunit residue Thr-1066 in segment IIIS5 by a tyrosine residue conserved in the corresponding positions of non-L-type Ca(2+) channels eliminates high dihydropyridine sensitivity through a steric mechanism. To determine the effects of this mutation on phenylalkylamine interaction, we exploited the availability of Ca(v)1.2DHP(-/-) mice containing the T1066Y mutation. In contrast to dihydropyridines, increased protein-dependent binding of the phenylalkylamine (-)-[(3)H]devapamil occurred to Ca(v)1.2DHP(-/-) mouse brain microsomes. This effect could be attributed to an at least 2-fold increase in affinity as determined by saturation analysis and binding inhibition experiments. The latter also revealed a higher affinity for (-)-verapamil but not for (-)-gallopamil. The mutation caused a pronounced slowing of (-)-[(3)H]devapamil dissociation, indicating a stabilization of the drug-channel complex. The increased affinity of mutant channels was also evident in functional studies after heterologous expression of wild type and T1066Y channels in Xenopus laevis oocytes. 100 mum (-)-verapamil inhibited a significantly larger fraction of Ba(2+) inward current through mutant than through WT channels. Our results provide evidence that phenylalkylamines also interact with the IIIS5 helix and that the geometry of the IIIS5 helix affects the access and/or binding of different chemical classes of Ca(2+) channel blockers to their overlapping binding domains. Mutation of Thr-1066 to a non-L-type tyrosine residue can be exploited to differentially affect phenylalkylamine and dihydropyridine binding to L-type Ca(2+) channels.

Methanethiosulfonate derivatives of rhodamine and verapamil activate human P-glycoprotein at different sites.

The human multidrug resistance P-glycoprotein (P-gp, ABCB1) actively extrudes a broad range of potentially cytotoxic compounds out of the cell. Key steps in understanding the transport process are binding of drug substrates in the transmembrane domains, initiation of ATPase activity, and subsequent drug efflux. We used cysteine-scanning mutagenesis of the transmembrane segment residues and reaction with the thiol-reactive drug substrate analog of rhodamine, methane-thiosulfonate-rhodamine (MTS-rhodamine), to test whether P-gp could be trapped in an activated state with high levels of ATPase activity. The presence of such an activated P-gp could be used to further investigate P-gp-drug substrate interactions. Single cysteine mutants (149) were treated with MTS-rhodamine, and ATPase activities were determined after removal of unreacted MTS-rhodamine. One mutant, F343C(TM6), showed a 5.8-fold increase in activity after reaction with MTS-rhodamine. Pre-treatment of mutant F343C with rhodamine B protected it from activation by MTS-rhodamine, indicating that residue Cys-343 contributes to the rhodamine-binding site. The ATPase activity of MTS-rhodamine-treated mutant F343C, however, was not stimulated further by colchicine or calcein-AM. By contrast, verapamil and Hoechst 33342 stimulated and inhibited, respectively, the ATPase activity of the MTS-rhodamine-treated mutant F343C. These results indicate that the MTS-rhodamine binding site overlaps that of colchicine and calcein-AM but not that of verapamil and Hoechst 33342 within the common drug-binding pocket.

New multidrug resistance reversal agents.

Multidrug resistance (MDR) to antitumor agents represents a significant challenge to effective chemotherapy. The use of MDR modulators is a promising approach to overcome the undesired MDR phenotype. The more effective MDR modulators are urgently needed for clinical use. This review focuses on literatures published in 1998-2001.

Pharmacokinetic and pharmacodynamic effects of high-dose continuous intravenous verapamil infusion: clinical experience in the intensive care unit.

OBJECTIVE: Our study aimed at evaluating the pharmacokinetic, cardiovascular, and metabolic effects of high-dose verapamil continuous intravenous infusion in cancer patients. DESIGN: Prospective clinical and pharmacokinetic study. SETTING: Intensive care unit of a Cancer Research Institute. PATIENTS: Nine patients (age range 31 to 57 yrs) with progressive cancer disease and without cardiovascular, renal, or hepatic dysfunctions. INTERVENTIONS: After a loading dose (0.15 mg/kg followed by 12 hrs of continuous intravenous infusion at 0.20 mg/kg/hr), the infusion rate of verapamil was increased every 24 hrs (0.25, 0.30, 0.35, and 0.40 mg/kg/hr). The highest rate was maintained for 48 hrs. Doxorubicin was given from the 60 th to the 108 th hr. Hydrochlorothiazide (25 mg/day) and potassium (36 mmol/day) were given orally. Altogether, 17 courses were completed. MEASUREMENTS AND MAIN RESULTS: Steady state concentration (C(SS) and systemic clearance of verapamil and nor-verapamil (active metabolite) for each infusion rate were calculated. Mean arterial pressure (MAP), central venous pressure (CVP), heart rate (HR), PR, QT and QTc intervals, and left ventricular ejection fraction (LVEF) were measured, as well as daily body weight, blood glucose and potassium. C(SS) of verapamil and nor-verapamil increased more than proportionally to the infusion rate (p<.001). Systemic clearance of verapamil decreased over the range of the infusion rate (p<.005). MAP and HR decreased at the 12th hr (p<.001) and then plateaued. CVP increased (p<.01). The relationship between MAP, HR, CVP, and verapamil plasma concentrations was significant (r2 = .25, .14, and .35, respectively; p<.0001). LVEF did not change. Six patients (11 courses) developed junctional rhythm. Three patients (six courses) showed a PR interval increase (p<.05). Patients with junctional rhythm had higher Css of verapamil (p<.009). Overall, QT and QTc intervals increased (p<.01). A linear relationship was observed between verapamil plasma concentrations and QT intervals (r2 = .09, p<.01). Cardiovascular side effects did not determine treatment withdrawal in any patient. Body weight, blood glucose, and potassium did not show significant changes. CONCLUSIONS: Our data suggest a capacity-limited clearance of high-dose verapamil. In the absence of heart disease, following a step by step increase of the dosage, the high plasma verapamil concentrations (617 to 2970 ng/mL) produce frequent but well tolerated hemodynamic and electrocardiogram changes.

(S)-emopamil attenuates acute reduction in regional cerebral blood flow following experimental brain injury.

We examined the effects of (S)-emopamil, a phenylalkylamine calcium channel blocker with serotonin receptor antagonist properties, on regional cerebral blood flow (rCBF) following experimental brain injury in the rat. Animals were subjected to fluid percussion brain injury of moderate severity (2.1 atm), and received (S)-emopamil (20 mg/kg, i.p., n = 10) or saline (n = 10) at 20 minutes postinjury and 2.5 hours after the first injection of the drug. Consecutive rCBF measurements were performed: (1) prior to injury, (2) 15 minutes, (3) 90 minutes, and (4) 4 hours postinjury, using the radiolabeled microsphere technique. Brain injury produced an acute and significant reduction of rCBF at 15 minutes postinjury in all the regions examined (p < 0.05). At 90 minutes postinjury, rCBF remained significantly depressed in the forebrain regions. All brain regions showed a recovery of rCBF to normal by 4 hours following injury in saline-treated animals, with the exception of injured left parietal cortex and bilateral hippocampi, where rCBF remained significantly depressed. A significant attenuation of the trauma-induced reduction in rCBF was observed at 70 minutes after the first administration of (S)-emopamil in the forebrain regions and cerebellum (p < 0.05). Following the second (S)-emopamil injection, the significant improvement in rCBF observed in left injured cortex was maintained. These results suggest that (S)-emopamil may be efficacious in reversing post-traumatic alterations in rCBF, which may contribute to the post-traumatic pathophysiologic sequelae.

[The antiarrhythmic activity of the polymeric forms of quinidine, trimecaine, etatsizin, propranolol and verapamil]. / Antiaritmicheskaia aktivnost' polimernykh form khinidina, trimekaina, étatsizina, propranolola i verapamila.

The antiarrhythmic activity and acute toxicity of polymeric formulations of quinidine, trimecaine, ethacizine, propranolol, verapamil which had been immobilized on a cellulose carrier (monocarboxylcellulose) and low molecular analogues were studied in various experimental animals (rats, mice, dogs). The polymeric formulations of trimecaine and verapamil were found to have a higher antiarrhythmic activity in different arrhythmia models than trimecaine and verapamil. The toxicity of all new compounds was no more than the values of conventional antiarrhythmic drugs.

Effects of levemopamil on neurologic and histologic outcome after cardiac arrest in cats.

BACKGROUND AND METHODS: A study was performed to examine the effects of the calcium-channel blocker levemopamil on neurologic outcome and neuropathology in a clinically relevant model of complete global cerebral ischemia (ventricular fibrillation in cats). Levemopamil was administered to cats starting 5 mins after resuscitation from 14 mins of cardiac arrest. In a "blinded" manner, 46 animals received levemopamil 1 mg/kg over 15 mins followed by 10 micrograms/kg.min for 16 hrs or vehicle. In a nonblinded manner, eight additional animals were pretreated with levemopamil beginning 45 mins before cardiac arrest. After resuscitation, levemopamil was infused at 10 micrograms/kg.min for 16 hrs. Animals in all three groups remained sedated, paralyzed, and mechanically ventilated for 24 to 30 hrs after resuscitation. Neurologic examinations were performed at 2, 4, and 7 days after resuscitation. Thirty-five cats were entered into data analysis (16 levemopamil posttreated, 14 vehicle-treated, and 5 levemopamil pretreated). RESULTS: Neurologic deficit scores and over-all neuropathologic scores did not differ among groups at any interval after resuscitation. However, the occipital cortex and CA1 region of the pretreated animals showed less severe damage than was observed in the animals that received levemopamil or vehicle, starting after resuscitation (p less than .01). CONCLUSIONS: Postarrest administration of levemopamil was not associated with improved neurologic or neuropathologic outcome. However, the data suggest that prearrest administration may result in regionally selective improvement in neuropathology.

Instant and sustained-release verapamil in the treatment of essential hypertension.

In a series of controlled studies for periods of 4 to 6 weeks comprising 103 patients altogether, and in 1 long-term trial for 1 year, various dosages of instant and sustained-release verapamil were administered in the treatment of mild and moderate essential hypertension. One of these trials was a double-blind comparison with nifedipine, in which the 2 calcium antagonists had an equally good effect on blood pressure. A significant blood pressure reduction was achieved with verapamil both at rest and during isometric work in most patients. About 10% of the patients were nonresponders. Pharmacokinetic studies demonstrated great interindividual variations in plasma concentrations of verapamil and its active metabolite norverapamil. Except for 1 study, no significant correlation was found between drug concentration and blood pressure reduction. All formulations of verapamil were well tolerated by the patients, and adverse effects were generally mild and often transient. No negative metabolic effects were observed during long-term treatment; serum lipids, in particular, were unaffected. PQ intervals on the electrocardiogram were significantly but moderately prolonged. QRS and QT intervals were unchanged. No increase in body weight occurred. It is concluded that verapamil is an efficacious, safe drug and a first-line treatment alternative in mild and moderate essential hypertension. The recently developed sustained formulation of the drug renders a simple dosage regimen possible.