Myocardial region (right or left ventricle) and aetiology of heart failure can influence the inotropic effect of ouabain in failing human myocardium.

AIMS: To investigate whether the inotropic effect of ouabain in failing human myocardium varies according to the heart chamber tested (right or left ventricle) or the aetiology of the heart disease, i.e. ischaemic or idiopathic. METHODS: The inotropic effect of ouabain was measured, as the percentage change in baseline tension, in myocardial strips isolated from right (RV; n=21) and left ventricles (LV; n=21) of hearts explanted from patients with idiopathic (IDC; n=11) and ischaemic cardiomyopathy (CAD; n=10). Concentration-effect curves obtained with ouabain (0.05-1.6 micromol l-1 ) were analysed using the Emax sigmoidal model, and the following parameters were calculated: Emax, EC50, n and EC10 (threshold concentration). The influence of ventricular chamber and heart failure aetiology on these parameters was evaluated by means of a two-way anova. RESULTS: Age and baseline haemodynamic parameters did not differ between IDC and CAD patients. Baseline strip contractility was highly variable (range: 0.48-10.0 mN), but neither ventricular chamber nor aetiology could explain such variability. A two-way anova showed that EC10 was greater in CAD than in IDC preparations (0.097+/-0.013 micromol l-1 vs 0.059+/-0. 009 micromol l-1; 95% C.I. for difference 0.043, 0.071) and Emax was lower in RV than in LV (121+/-21% vs 250+/-38%; 95% C.I. -221, -36), while EC50 and n were not significantly different between groups. CONCLUSIONS: The inotropic effect of ouabain in human myocardium may vary according to aetiology of heart failure and the ventricle being tested. Although our results do not support the hypothesis of increased sensitivity to cardiac glycosides in CAD patients, they may explain the diminished effect observed in patients with RV failure.

Acute effects of the oral administration of midodrine, an alpha-adrenergic agonist, on renal hemodynamics and renal function in cirrhotic patients with ascites.

The effects of the acute administration of arterial vasoconstrictors on renal plasma flow (RPF) and urinary sodium excretion (UNaV) in cirrhotic patients with ascites with or without hepatorenal syndrome (HRS) are still controversial. As a consequence, vasoconstrictors are not actually used in the treatment of renal sodium retention or HRS in these patients, regardless of the several lines of evidence suggesting that these renal functional abnormalities are related to a marked arterial vasodilation. The lack of an orally available effective arterial vasoconstrictor probably represents a further reason for this omission. Consequently, the present study was made to evaluate the acute effects of the oral administration of midodrine, an orally available -mimetic drug, on systemic and renal hemodynamics and on UNaV in cirrhotic patients with ascites. Mean arterial pressure (MAP), heart rate (HR), cardiac index (CI), systemic vascular resistance (SVR), left forearm blood flow (LFBF), left leg blood flow (LLBF), RPF, glomerular filtration rate (GFR), UNaV, plasma renin activity (PRA), plasma concentration of antidiuretic hormone (ADH), and the serum levels of nitrite and nitrate (NOx) were evaluated in 25 cirrhotic patients with ascites (17 without HRS and 8 with type 2 HRS) before and during the 6 hours following the oral administration of 15 mg of midodrine. During the first 3 hours after the drug administration, a significant increase in MAP (89.6 +/- 1.7 vs. 81.80 +/- 1.3 mm Hg; P < .0001) and SVR (1, 313.9 +/- 44.4 vs. 1,121.2 +/- 60.1 dyn . sec . cm-5; P < .0001) accompanied by a decrease in HR (69 +/- 2 vs. 77 +/- 3 bpm; P < .005) and CI (2,932.7 +/- 131.4 vs. 3,152.5 +/- 131.4 mL . min-1 . m2 BSA; P < .0025) was observed in patients without HRS. No change was observed in LFBF and LLBF. The improvement in systemic hemodynamics, which was also maintained during the the 3- to 6-hour period after midodrine administration, was accompanied by a significant increase in RPF (541.5 +/- 43.1 vs. 385.7 +/- 39.9 mL . min-1; P < .005), GFR (93.1 +/- 6.5 vs. 77.0 +/- 6.7 mL . min-1; P < .025), and UNaV (92.7 +/- 16.4 vs. 72.2 +/- 10.7 microEq . min-1; P < .025). In addition, a decrease in PRA (5.33 +/- 1.47 vs. 7.74 +/- 2.17 ng . mL-1 . h; P < .05), ADH (1.4 +/- 0.2 vs. 1.7 +/- 0.2 pg . mL-1; P < .05), and NOx (33.4 +/- 5.0 vs. 49.3 +/- 7.3 micromol-1; P < .05) was found. In patients with HRS, the effects of the drug on the systemic hemodynamics was smaller and shorter. Accordingly, regardless of a significant decrease in PRA (15.87 +/- 3.70 vs. 20.70 +/- 4.82 ng . mL-1 . h; P < .0025) in patients with HRS, no significant improvement was observed in RPF, GFR, or UNaV. In conclusion, the acute oral administration of midodrine is associated with a significant improvement in systemic hemodynamics in nonazotemic cirrhotic patients with ascites. As a result, renal perfusion and UNaV also improve in these patients. By contrast, midodrine only slightly improves systemic hemodynamics in patients with type 2 HRS, with no effect on renal hemodynamics and renal function.

Cardiac effects of quinidine on guinea-pig isolated perfused hearts after in vivo quinidine pretreatment.

1 Experimental and clinical studies suggest that class I and class III antiarrhythmic drugs may be subject to pharmacological tolerance during long term treatment, leading to loss of therapeutic effectiveness. 2 The aim of this study was to ascertain whether prolonged in vivo treatment with the Class Ia agent quinidine can modify cardiac (electrical and mechanical) responses to the drug. 3 A group of guinea-pigs (n = 7) was treated intraperitoneally (q.d.) for 6 days with 75 mg kg-1 quinidine sulphate. Preliminary pharmacokinetic experiments indicated that this dose could attain Plasma concentrations similar to those that are therapeutic in man (2-5 mg l-1). A control group (n = 7) received a saline solution for the same period. 4 Twenty-four hours after the last administration hearts were removed and retrogradely perfused at constant flow (stimulation frequency: 2.5 Hz). The following parameters were measured: maximal derivative of intraventricular pressure (dP/dtmax); coronary perfusion pressure (Cp); PR, QRS and JT intervals, on surface ECG. The effects of quinidine on these parameters were measured at different concentrations (2, 4, 8, 12, 16, 20 microns) and compared in the two experimental groups. 5 In the group quinidine decreased in a dose-dependent manner dP/dt and increased PR and QRS intervals. JT interval was increased at the lowest concentrations and decreased at the highest (biphasic effect). Cp did not change significantly. 6 In the pretreated group quinidine qualitatively produced the same effects on dP/dt and ECG intervals as in control group. Also the magnitude of these effects was not significantly different between the two groups. In contrast with findings in control experiments. Cp was significantly decreased by increasing quinidine concentration. Mean baseline Cp was higher in pretreated than in the control group (though not significantly, P = 0.072) and quinidine addition abolished this difference. Thus, it is suggested that quinidine withdrawal induced a rebound increase in coronary tone, due to the unmasking of vasoconstrictor homeostatic mechanisms elicited by the in vivo vasodilating effect of the drug. 7 In conclusion, our data do not support the possibility that tolerance ensues during long term quinidine treatment, at least as far as electrophysiological and contractility effects are concerned. Further experimental work is needed to explain the appearance of a coronary vasodilating effect in pretreated hearts.

Adaptation of the QT interval to heart rate changes in isolated perfused guinea pig heart: influence of amiodarone and D-sotalol.

The inadequacy of the QT interval to shorten following heart rate increase is a feature of the inherited long QT syndrome and may have a role in the genesis of the typical arrhythmias associated with this syndrome (torsade des pointes). The aim of our study was to evaluate whether drugs that prolong the QT interval, such as amiodarone and D-sotalol, may also impair the ability of the QT interval to adapt to sudden heart rate changes. Experiments were carried out on isolated perfused guinea pig hearts (Langendorff preparation). Driving frequency was changed, in steps, every two minutes (Hz: 2.5-3-2.5-3.75-2.5-5-2.5), while epicardial ECG was continuously recorded on magnetic tape. QT interval was automatically measured by means of a beat-by-beat analysis program. D-sotalol was added to the perfusion medium at a concentration of 4 micrograms ml-1, while amiodarone was administered, before in vitro evaluation, for seven days (50 mg kg-1 per day, intraperitoneally). In control experiments two phases of QT adaptation were identified: an abrupt QT shortening at the first beat after frequency change (QT1), followed by a gradual, exponential QT shortening that reached a new steady state in about 1 min (half life: 13 sec). The electrical restitution curve (the relation between QT1 and the corresponding diastolic interval) had a rate constant of 57 +/- 8 ms. Neither drug changed the slow component of QT adaptation. However, both drugs increased the ability of QT to shorten upon premature stimulation: D-sotalol by increasing the rate constant of the restitution curve and amiodarone by decreasing the y-intercept. Our results indicate that D-sotalol and amiodarone do not impair QT shortening during tachycardia but, on the contrary, they may favour QT adaptation, thus reducing the likelihood of the potentially lethal 'R on T phenomenon'. This may be an additional mechanism by which these drugs can exert their antifibrillatory action.

Tolerance to the repolarization effects of rac-sotalol during long-term treatment.

AIMS: To establish whether tolerance to the QT effect could ensue during maintenance treatment with rac-sotalol. METHODS: The effect of rac-sotalol on QT interval duration was studied in 10 patients after single oral administration (160 mg) and after 6-day multiple oral dosing (80 mg two or three times daily). In order to separate the pure Class III effect from the bradycardia-related QT prolongation, heart rate/QT relationship was preliminarly assessed in each patient after the administration of a pure beta-adrenoceptor blocker (propranolol, 80 mg orally). Repolarization changes were quantified as percent difference between the measured QT and the expected QT on the basis of the individual heart rate/QT relationship. RESULTS: In all patients QT interval prolongation was linearly correlated with rac-sotalol log plasma concentration. The maximal QT prolongation and peak plasma concentration were not significantly different following acute and chronic administrations (QT effect: +18.1+/-6.3% vs +14.2+/-3.3%; peak concentration: 1.64+/-0.49 mg l(-1) vs 1.83+/-0.66 mg l(-1)). Line slopes were also unchanged following chronic treatment (21.8+/-8.9 vs 21.1+/-9.2). In four cases a significant rightward shift of the line occurred during repeated administrations, consistent with the appearance of pharmacodynamic tolerance. The inconstancy of this change in responsiveness may either be ascribed to a genetically determined individual susceptibility or to a variable interplay between Class III effect, gradual QT prolongation due to long-term beta-adrenoceptor blockade and tolerance development. CONCLUSIONS: During maintenance treatment with rac-solatol, partial loss of repolarization effects occurred in some patients suggesting pharmacological tolerance.

Evaluation of the regional responsivity to ryanodine of human myocardium from patients with idiopathic dilated cardiomyopathy and secondary cardiomyopathies.

The aim of the study was to compare the contractile response to ryanodine of human heart preparations taken from right and left ventricles of patients affected by idiopathic (IDCM) and secondary (SCM) end-stage dilated cardiomyopathies. Right and left ventricle myocardial strips were obtained from hearts of patients undergoing orthotopic heart transplantation and suspended in an oxygenated bath (T = 35 degrees C; stimulation frequency = 0.5 Hz). After an equilibration period, a cumulative dose-response curve for contractility (peak tension) was obtained with ryanodine (0.5, 1, 2, 4, 8, 16, 32, 64 microM). Basal contractility was not significantly different between right and left ventricles or between IDCM and SCM preparations. Ryanodine reduced peak myocardial tension but failed to completely suppress it, even at concentrations which achieved maximum effect. Ryanodine effect still persisted after a 45'-60' washout. The concentration-effect curves from IDCM right ventricle, IDCM left ventricle, SCM right ventricle and SCM left ventricle were compared: IDCM left ventricle was less sensitive to ryanodine than IDCM right ventricle and SCM left ventricle, while no difference was detectable between SCM left ventricle and SCM right ventricle. Thus, the overall sensitivity ranking was: IDCM left ventricle < IDCM right ventricle = SCM right ventricle = SCM left ventricle. IDCM left ventricle showed, in addition, a biphasic response with a shift from negative to positive inotropic effect at concentrations higher than approximately 10 microM. These findings indicate that the cardio-depressant effect of ryanodine, a drug which interferes with intracellular Ca release from the sarcoplasmic reticulum, differs quantitatively and qualitatively in IDCM left ventricle from both IDCM right ventricle and SCM left ventricle. This suggests that some specific alteration in the intracellular Ca signalling in IDCM exists and, from a methodological point of view, stresses the need for a "bi-ventricular" approach to studying biochemical and functional abnormalities of advanced congestive heart failure.

Electrocardiographic interactions between pinacidil, a potassium channel opener and class I antiarrhythmic agents in guinea-pig isolated perfused heart.

1. Drugs that shorten action potential duration could decrease the Na-channel blocking effect of class I antiarrhythmic agents by reducing the availability of Na channel in the inactivated state. 2. This hypothesis was tested in guinea-pig perfused heart, measuring the surface ECG effects of three class I drugs endowed with different binding kinetics (15 microM mexiletine, 10 microM quinidine and 3 microM flecainide) in the presence of increasing concentrations of pinacidil (10 microM, 30 microM, 50 microM), a potassium channel opener that shortens action potential duration. 3. The ECG parameters measured were: the QRS interval, i.e. the intraventricular conduction time; the JT interval, which reflects the duration of ventricular repolarization; the ratio between JT peak (the time from the end of QRS and the peak of T wave) and JT interval, which quantifies changes in the morphology of the T wave. 4. At the concentrations tested all the antiarrhythmic drugs widened the QRS complex by 55-60%. Flecainide did not significantly change JT interval, but quinidine prolonged and mexiletine shortened it. Mexiletine also decreased the JT peak/JT ratio. Pinacidil by itself decreased the JT interval and the JT peak/JT ratio in a dose-dependent way, but did not affect QRS duration. 5. In the presence of fixed antiarrhythmic drug concentrations, however, pinacidil decreased the QRS prolongation induced by mexiletine (-17%) and quinidine (-8%), but not that induced by flecainide: this effect was already maximal at the lower concentration tested (10 microM) and there was no relationship between pinacidil-induced JT shortening and QRS changes. To explain this unexpected result it has been supposed that, at the driving frequency used (4 Hz), myocardial cells were partially depolarized and that pinacidil could repolarize them, thus decreasing the number of inactivated Na channels and the effects of drugs that (mainly or partly) block the channels in the inactivated state. In agreement with this hypothesis, an additional series of experiments carried out with 15 microM mexiletine at a lower stimulation rate (2 Hz) showed only a negligible loss of QRS effect (- 2.3%) at any pinacidil concentration.6. Flecainide, but not quinidine and mexiletine, antagonized the JT shortening induced by pinacidil;furthermore, no drug modified the JTp/JT decrease induced by pinacidil.7. These results indicate that: (a) an antagonism between class I antiarrhythmic drugs and pinacidil is possible; (b) mexiletine is the most involved among the drugs tested; (c) the interaction is not related to pinacidil-induced repolarization shortening, but probably to changes in membrane resting potential. The possible clinical implications need to be defined.

Verapamil and norverapamil plasma levels in infants and children during chronic oral treatment.

Verapamil and norverapamil trough plasma levels were measured in 22 children, aged from 15 days to 17 years, under chronic oral treatment with the drug (mean daily dose +/- SD: 4.9 +/- 1.4 mg/kg) for supraventricular tachyarrhythmias (n = 20) or hypertrophic cardiomyopathy (n = 2). Overall, 67 determinations were available (1 to 11 per patient) and the mean concentration values (+/- SD) were 43.3 +/- 36.4 ng/ml for verapamil and 41.7 +/- 28.9 ng/ml for norverapamil. Verapamil and norverapamil trough concentrations were correlated with the daily dose (p < 0.05) but a wide intersubject variability was present at any given dose and the regression line did not pass through the origin of axes (x-axis intercept: 1.2 mg/kg for verapamil, 0.9 mg/kg for norverapamil). To study the influence of age on drug kinetics, verapamil plasma concentrations corrected by daily dose/kg ([V]/D) and norverapamil to verapamil concentration ratios (N/V) (taken as an index of metabolic clearance) were divided according to age quartiles. The median [V]/D was higher in the first and in the fourth age quartile than in the other two age groups. On the contrary, median N/V ratio increased with age, suggesting that drug metabolism was improving during the first year of life. Four children developed typical adverse reactions to the drug (bradycardia, AV block, hypotension). In one case verapamil plasma levels were definitely high (294 ng/ml). In the other three cases, concomitant factors (such as very young age and heart disease) seem to have contributed to drug toxicity.

Pharmacokinetics and electrophysiological effects of intravenous ajmaline.

The pharmacokinetics of ajmaline were studied in 10 patients with suspected paroxysmal atrioventricular block who received a 1 mg/kg intravenous dose over 2 minutes for diagnostic purposes (ajmaline test). Plasma concentration decay followed a triexponential time course with a final half-life much longer (7.3 +/- 3.6 hours) than that previously found by other investigators (about 15 minutes). Mean total plasma clearance and renal clearance were 9.76 ml/min/kg and 0.028 ml/min/kg, respectively. Although most of the dose was eliminated through the extrarenal route (only 3.5% of the intravenous dose was recovered in urine), no fluorescent metabolites could be detected either in plasma or urine. The steady-state volume of distribution averaged 6.17 L/kg, and plasma protein binding ranged between 29 and 46%. Three patients developed a transient atrioventricular block after ajmaline administration. In the remainder, the drug prolonged atrio-His bundle (AH interval), His bundle-ventricular (HV interval) and intraventricular (QRS interval) conduction times. Corrected ventricular repolarisation time (QTc interval) showed less marked changes, which were biphasic at times. The mean maximum ajmaline-induced increase in HV interval was 98%, in QRS was 58%, in AH was 30%, and in QTc was 17%. In most cases the time course of electrocardiographic changes lagged behind that of plasma concentrations, suggesting a delayed equilibrium of plasma concentrations with the site of action (hysteresis). Despite that, the pharmacokinetic-pharmacodynamic model, which accounted for hysteresis, failed to fit the experimental data adequately.(ABSTRACT TRUNCATED AT 250 WORDS)

Influence of age and gender on the in vitro serum protein binding of flecainide.

The in vitro protein binding of flecainide was studied by equilibrium dialysis in relation to serum concentrations of albumin and alpha 1-acid glycoprotein (AAG) in 22 healthy subjects of both sexes aged between 23 and 89 years. In the range of flecainide concentrations tested, protein binding of flecainide was not saturable and the percent value of the unbound fraction ranged between 0.48 and 0.68, mean value (SD) = 0.59 (+/- 0.06), without any significant difference between males and females or between young and old subjects. The flecainide unbound fraction was significantly correlated with serum albumin concentrations but not with total serum proteins or AAG concentrations.

Effect of dobutamine on left ventricular relaxation and filling phase in patients with ischemic heart disease and preserved systolic function.

The beneficial effects of dobutamine on left ventricular systolic and diastolic phases have been described in patients with congestive heart failure. Its influence on left ventricular diastolic phase in patients with preserved systolic function, absence of dys- or akinetic areas, and left ventricular dilatation has not yet been adequately investigated. Thus a simultaneous echo-Doppler and hemodynamic study was performed in 15 patients with ischemic heart disease and preserved systolic function in order to assess the effect of dobutamine on left ventricular relaxation and filling phase. The infusion of dobutamine at a rate of 10 micrograms/kg/min induced a marked inotropic action, as shown by the significant increase in positive dP/dt (from 1392 +/- 224 to 2192 +/- 295 mmHg/sec, p < 0.001), dP/dt/P (from 32 +/- 8.1 to 50 +/- 17 sec-1; p < 0.0001), and in peak of systolic pressure (from 143 +/- 25 to 168 +/- 36 mmHg; p < 0.005). In addition, dobutamine reduced the end-systolic volume index (from 30 +/- 16 to 26 +/- 19 ml/m2; p < 0.05), the end-systolic stress (from 222.2 +/- 65.3 to 198.4 +/- 84 g/cm2; p < 0.006), and had favorable effects on relaxation and the early filling phase.(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacodynamic variability of flecainide assessed by QRS changes.

The effect of flecainide on the QRS interval was studied in 10 patients who were receiving long-term oral treatment (50 to 150 mg twice daily) for arrhythmias that were refractory to other drugs. Total and free drug plasma levels and QRS durations were measured at intervals after the morning administration. Free drug plasma levels were linearly correlated with QRS duration in each patient and the slope of the line was widely variable in the population studied. Even after the data from one patient with an unusually high slope (0.454) was excluded from the analysis, the slope range was 0.0284 to 0.144. Pharmacodynamic variability could not be explained by heart rate changes, active metabolites, electrolyte disturbances, or free drug concentration. None of the pharmacokinetic parameters measured (average steady-state concentration, fluctuation of maximum and minimum concentrations, time to peak concentration, final half-life, and protein binding) showed an intersubject variability greater than 4.4 times. Our findings suggest that the determination of flecainide free plasma concentration may not be sufficient to forecast electrophysiologic effects in individual patients.

Determination of lorajmine and its metabolite ajmaline in plasma and urine by a new high-performance liquid chromatographic method.

Lorajmine is a monochloroacetyl derivative of ajmaline with electrophysiological properties somewhat different from those of the compound of origin. Since lorajmine is rapidly hydrolyzed to ajmaline by plasma and tissue esterases, it is crucial to measure plasma levels of both drugs separately. A major problem in assaying lorajmine is its chemical instability in plasma both after blood sampling and during the extraction procedure. Furthermore, lorajmine (unlike ajmaline) is not fluorescent and has a very low UV absorbance, so the standard detectors for high-performance liquid chromatography cannot be used. We describe a new method that solves the problems of instability and sensitivity. Plasma esterases are first blocked pharmacologically (neostigmine); ajmaline is then measured by direct on-column injection of samples. Last, lorajmine is completely converted to ajmaline, extracted, and measured with a fluorescence detector. The molar concentration of ajmaline obtained in the last step, minus that found by direct injection, gives the concentration of lorajmine. Some examples of pharmacokinetic applications are also given.

Effect of digoxin on the in vitro secretion of renin and angiotensin II/III immunoreactivity by the human adrenal gland.

Cardiac glycosides in man inhibit renin secretion, probably through a direct effect at the renal level (i.e. inhibition of juxtaglomerular cell Na/K ATPase). Since there is evidence that the human adrenal possesses an intrinsic renin-angiotensin system, we investigated the effect of digoxin on the in vitro generation of renin and angiotensin II/III, as well as of aldosterone, by the human adrenal gland. Minced normal adrenal tissues were studied in a superfusion system, measuring in the 15-min superfusate fractions active renin by immunoradiometric assay and angiotensin II/III and aldosterone by radioimmunoassay, respectively. In a first set of four experiments using different concentrations of digoxin in sequence for 45 min periods, digoxin 10(-5), but not 10(-8) and 10(-6) mol/l, significantly reduced renin and angiotensin II/III output from adrenals, while no change in aldosterone was observed. In a second set of three experiments, the addition of digoxin 10(-5) mol/l for 120 min caused a sustained reduction of renin and angiotensin II/III, but not of aldosterone. In the final experiment, the decrease of renin and angiotensin II/III during superfusion with digoxin 10(-5) mol/l was significantly greater than that observed during superfusion with digoxin in the presence of antidigoxin antibodies. Our data indicate that digoxin at high doses reduces renin and angiotensin II/III but not aldosterone secretion by the human adrenal gland. This suggests two different effects of digoxin, probably both mediated by inhibition of the Na/K ATPase activity, on the adrenal renin-angiotensin- and aldosterone-secreting cells.

Effects of pinacidil on guinea-pig isolated perfused heart with particular reference to the proarrhythmic effect.

1. The effects of pinacidil (10, 30, 50 microM) on contractility (+dP/dtmax), coronary perfusion pressure (cP), and ECG intervals (PR, QRS, QT) have been studied on constant-flow perfused guinea-pig hearts, driven at four frequencies (2.5, 3, 3.5, 4 Hz). 2. Pinacidil decreased +dP/dtmax, cP and the QT interval in a dose-dependent manner, whereas the PR interval was increased. QRS duration was not modified. All these effects were independent of driving frequency. Pinacidil decreased the interval from Q-wave to T-wave peak (QTpeak) to a greater extent than the QT interval, thus decreasing the QTpeak/QT ratio. This effect, unlike that on QT interval, was more evident at the highest frequency of stimulation. 3. In 4 out of 20 hearts treated with pinacidil sustained ventricular fibrillation (VF) occurred following a short run of premature ventricular beats (R on T phenomenon). 4. In separate experiments, an attempt to induce VF electrically was made at drug concentrations ranging from 10 microM to 100 microM (8 experiments for each concentration). In control conditions and at the lowest concentrations of pinacidil tested (10 microM) VF could never be induced; in the presence of 30 microM pinacidil VF was induced in 5 out of 8 experiments. Drug concentrations higher than 50 microM permitted the induction of VF in every case. 5. Although the concentrations of pinacidil producing ventricular fibrillation are 30-40 times higher than those found in patients under long term treatment with this agent, it is suggested that caution should be used in prescribing this drug, at least in patients suffering from myocardial ischaemia.