A novel catheter system for totally implantable intravenous drug therapy: assessment of catheter function and patency with trepostinil therapy.

BACKGROUND: Catheter failure, either due to dislodgment, occlusion or infection is the leading complication of chronic intravenous drug therapy. Better drug delivery techniques are required to advance life saving therapies that require this delivery method. This study evaluated the chronic performance of a fully implantable drug delivery system that incorporates a novel intravenous catheter. The system was designed to reduce complications associated with intravascular drug delivery including catheter occlusion, breakage, migration, and infection. METHODS: Twelve canines were implanted with a novel central venous catheter (Model 10642; Medtronic, Minneapolis, MN) connected to a totally implanted programmable drug pump (Model 8637 SynchroMed II, Medtronic). The drug delivery systems infused saline (n=6) or treprostinil (n=6) (Remodulin; United Therapeutics, Research Triangle Park, NC) for either 12 or 26 weeks at a continuous flow rate of 540 microL/day. Catheter performance was assessed at 0 (implant), 2, 4, 8, 12, 16, 20, and 24 weeks by quantifying delivery pressure, delivery volume and steady state Treprostinil concentrations. RESULTS: All catheters remained patent and free of complications for the duration of the study. Analysis of pressure waveforms during bolus delivery showed low and unchanged catheter resistance throughout the study. Measurement of pump delivery volume accuracy showed that the delivered volume was statistically similar to the calculated delivery (product of flow rate and elapsed time). Measurement of plasma treprostinil levels showed stable concentrations over the study period. There were no catheter dislodgments or breakage. Pathology showed all catheters free from fibrosis and thrombus and minimal changes to the vascular endothelium. CONCLUSIONS: The Model 10642 vascular catheter along with the SynchroMed II implantable drug delivery system showed promising performance in a chronic animal model.

Mechanism of antiarrhythmic drug-induced changes in defibrillation threshold: role of potassium and sodium channel conductance.

OBJECTIVES: We sought to determine which ion current predominantly affects defibrillation outcomes by using specific pharmacologic probes (lidocaine [a sodium channel blocking agent] and cesium [an outward potassium channel blocking agent]) in 26 swine. BACKGROUND: The effect of a drug on sodium or potassium channel conductance, or both, may affect defibrillation threshold values. However, it is unknown which ion channel predominates. METHODS: Each pig was randomly assigned to one of four treatment groups with two treatment phases: group 1 = placebo (D5W) in treatment phase I followed by placebo plus cesium in treatment phase II (n = 6); group 2 = lidocaine followed by lidocaine plus placebo (n = 7); group 3 = lidocaine followed by lidocaine plus cesium (n = 7); group 4 = placebo followed by placebo plus placebo (n = 6). Defibrillation threshold values and electrocardiographic measurements were obtained at baseline and at treatment phases I and II. RESULTS: Lidocaine increased defibrillation threshold values from baseline by 71% in group 2 (p = 0.02) and by 92% in group 3 (p < 0.01). There were no changes in defibrillation threshold values from baseline to D5W in groups 1 and 4. When D5W was added to lidocaine in group 2 and D5W in group 4, there were no significant changes in defibrillation threshold values. However, when cesium was added to lidocaine in group 3, the elevated defibrillation threshold values (mean +/- SD) returned to baseline values (from 15.7 +/- 3.46 to 7.55 +/- 3.19 J, p < 0.01). Cesium added to D5W in group 1 also significantly reduced defibrillation threshold values from 7.10 +/- 1.27 to 4.14 +/- 1.75 J (p < 0.01). The effect of cesium on defibrillation threshold values was similar between groups 1 and 3, regardless of lidocaine, such that these values were reduced by 40 +/- 14% and 51 +/- 18%, respectively (p = 0.28). CONCLUSIONS: Cesium, through potassium blockade, reverses lidocaine-induced elevation in defibrillation threshold values. The magnitude of defibrillation threshold reduction when cesium was added to lidocaine was similar to the defibrillation threshold reduction when cesium was added to placebo. Thus, inhibiting outward potassium conductance and prolonging repolarization decreases defibrillation threshold values independent of sodium channel blockade.

Metformin improves vascular function in insulin-resistant rats.

This study assessed the effect of metformin treatment on insulin, mean arterial pressure (MAP), and endothelial function in insulin-resistant (IR) rats. In addition, we assessed the direct effect of metformin in vitro. Sprague-Dawley rats were randomized to control (n=28) or IR (n=28) groups. Rats were further randomized to receive metformin (300 mg/kg) or placebo for 2 weeks. MAP and insulin were measured. Subsequently, a third-order branch of the superior mesenteric artery was isolated, and endothelial function was assessed. Specifically, dose-response experiments of acetylcholine (ACh) with or without N-nitro-L-arginine (LNNA) were performed. For in vitro experiments, mesenteric arteries were removed from untreated control and IR rats and treated with metformin (100 micromol/L) before ACh+/-LNNA. MAP and insulin levels were improved in IR-metformin compared with IR-placebo rats. Maximal relaxation (E(max)) to ACh was enhanced in IR-metformin (92+/-2%) compared with IR-placebo rats (44+/-4%) (P<0.05). Relaxation in response to ACh+LNNA was greater in IR-metformin (33+/-4%) than in IR-placebo rats (12+/-4%) but remained depressed compared with control rats (E(max)=68+/-5%). The control group was not affected by metformin. In vitro treatment of arteries with metformin in response to ACh produced results similar to those in the experiments with metformin-treated rats. Although metformin improves metabolic abnormality in IR rats, this action does not appear to mediate its effect on vascular function. Both in vivo and in vitro metformin improved ACh-induced relaxation in IR rats to control levels, apparently through nitric oxide-dependent relaxation. These data suggest that metformin improves vascular function through a direct mechanism rather than by improving metabolic abnormalities.

The pharmacokinetic and pharmacodynamic interaction between propafenone and lidocaine.

Although propafenone is a known substrate and inhibitor of the cytochrome P450 4-hydroxylation pathway of debrisoquin (CYP2D6 isozyme), its effects on other hepatic mixed- function oxidative isozymes have not been extensively evaluated. We studied the influence of propafenone on the disposition of continuously infused lidocaine in 12 healthy male volunteers. Placebo or propafenone (225 mg every 8 hours) was orally administered for 4 days before and during lidocaine administration (2 mg/kg/hr for 22 hours). In the 11 (92%) subjects phenotyped as extensive metabolizers, propafenone significantly increased the lidocaine area under the plasma concentration time curve (81.7 +/- 16.2 versus 76.3 +/- 15.6 micrograms.hr/ml; p < or = 0.05) and reduced systemic lidocaine clearance (9.53 +/- 1.77 versus 10.27 +/- 2.24 ml/min/kg; p < or = 0.05), but did not significantly affect volume of distribution at steady state (2.48 +/- 0.33 versus 2.64 +/- 0.45 L/kg; p = 0.10) or mean residence time (4.37 +/- 0.92 versus 4.47 +/- 0.87 hours; difference not significant) compared with placebo, respectively. Adverse central nervous system effects were significantly worse in severity and duration during the propafenone phase (p < or = 0.05). Propafenone minimally inhibits the metabolism of lidocaine. This suggests that the ability of propafenone to inhibit metabolic pathways exclusive of the CYP2D6 isozyme may be limited. In addition, potentiation of disturbing central nervous system adverse effects may occur during combination therapy of propafenone and lidocaine.

Disposition of digoxin immune Fab in patients with kidney failure.

Digoxin and digoxin immune Fab, its antidote, are eliminated renally. However, the disposition of Fab in severe kidney disease is poorly described. Therefore, the disposition of Fab and its relationship to total and free digoxin were studied in five digoxin-toxic patients with end-stage renal disease (n = 4) or severe renal dysfunction (n = 1) with a mean (+/- SD) serum creatinine of 5.9 +/- 1.2 mg/dl (four patients were receiving long-term hemodialysis). Serum was drawn after a clinically neutralizing Fab dose (80 to 160 mg) every 12 to 24 hours for 204 to 327 hours. Fab concentrations were assessed by radioimmunoassay, whereas total digoxin concentrations were assessed with a modified radioimmunoassay or fluorescence polarization immunoassay. The concentration-time profile of Fab appeared to be similar to the concentration-time profile of total digoxin. The mean (+/- SD) half-lives of the alpha and beta disposition phases of Fab were 13 +/- 5 hours and 96 +/- 31 hours, respectively, which were similar to the alpha and beta parameter estimates of total digoxin (14 +/- 4 and 123 +/- 16 hours, respectively). Steady-state volume of distribution and systemic clearance of Fab were 0.29 +/- 0.11 L/kg and 0.057 +/- 0.022 ml/min/kg, respectively. Thus, in comparison to values reported in patients with normal renal function, the elimination of Fab and total digoxin are markedly delayed in patients with end-stage renal disease, which may necessitate prolonged clinical monitoring.

Aging effects on the organic base transporter and stereoselective renal clearance.

OBJECTIVE: The organic base transporter is responsible for stereoselective renal excretion. Changes in activity of this system secondary to aging may affect the disposition of an organic base in a stereoselective manner. METHODS: Eight young men (age range, 22 to 33 years) and seven elderly men (age range, 62 to 79 years) were given 10 mg pindolol twice daily, pindolol with 200 mg trimethoprim once daily (a known inhibitor of organic base secretion) and pindolol with 1.5 gm ammonium chloride (NH4Cl) four times daily for 3 days on three occasions. On day 4, urine and plasma were collected over 24 hours to determine renal clearance (CLR) values of pindolol isomers. RESULTS: R(+)-Pindolol CLR values in young versus elderly men were 203 +/- 82 versus 150 +/- 87 ml/min, 128 +/- 51 versus 113 +/- 35 ml/min, and 480 +/- 248 versus 247 +/- 59 ml/min during the control, trimethoprim, and NH4Cl study phases, respectively. S(-)-Pindolol CLR values in young versus elderly were 279 +/- 81 versus 207 +/- 105 ml/min, 178 +/- 70 versus 136 +/- 42 ml/min, and 593 +/- 294 versus 276 +/- 49 ml/min during control, trimethoprim, and NH4Cl phases, respectively. NH4Cl increased R(+)-pindolol CLR by 138% (p < 0.05 versus pindolol alone) in young men, which was significantly greater than that observed in elderly subjects (66%; p < 0.05 versus pindolol alone; p = 0.016 young versus old). NH4Cl affected S(-)-pindolol CLR in a similar manner. Trimethoprim decreased R(+)-pindolol CLR in the young subjects by 37% (p < 0.05 versus pindolol alone), which was similar to that observed in the elderly subjects (26%; p < 0.05 versus pindolol alone; p = 0.94 young versus elderly). Trimethoprim affected S(-)-pindolol CLR in a similar manner. Stereoselective renal excretion of pindolol was unaffected by NH4Cl and trimethoprim, where the R(+)/S(-)-pindolol CLR ratio was unchanged (p = NS) from control in the young and elderly subjects. Comparison of the pindolol CLR isomer ratio between young and elderly groups showed no significant differences. Changes in pindolol clearance values resulted in significant changes in beta-blocking activity, assessed by isoproterenol (INN, isoprenaline) testing. CONCLUSIONS: Trimethoprim and NH4Cl significantly affect pindolol renal and total clearance values. Aging does not alter renal excretion of pindolol except for the magnitude by which renal excretion can be stimulated.

Pharmacokinetic aspects of digoxin-specific Fab therapy in the management of digitalis toxicity.

Digoxin intoxication occurs frequently and may require treatment with digoxin-specific Fab therapy. Little is known, however, regarding the biological fate of this compound. Pharmacokinetic studies have not been performed in healthy volunteers, but there are limited kinetic data from patients who have received therapy for the treatment of digoxin toxicity. Digoxin-specific Fab is eliminated via renal and nonrenal routes, having a volume of distribution slightly exceeding extracellular volume (0.40 L/kg) and an elimination half-life of 16 to 20 hours. Patients with renal impairment and end-stage renal disease have elimination half-life values that are prolonged up to 10-fold in magnitude, while volume of distribution is unaffected. Systemic clearance of digoxin-specific Fab is approximately 0.32 ml/min/kg in digoxin-toxic patients with preserved renal function. Renal failure also decreases Fab clearance by up to 75%. Therefore, Fab may reside in the serum of anephric patients for 2 to 3 weeks after administration. More important is the effect of Fab on the disposition of digoxin. Because digoxin-specific Fab has a stronger digoxin-binding affinity than do biological membranes, it can sequester tissue-bound and intracellular digoxin into the extracellular spaces. This results in a rapid increase in digoxin serum concentrations in the central compartment. Since the majority of digoxin is bound by Fab, it cannot interact with its biological receptor and thus reverses digoxin toxicity. The pharmacokinetic fate of total digoxin after administration of digoxin-specific Fab follows that of Fab. However, it appears that the elimination half-life of Fab is slightly shorter than that of total digoxin in patients with end-stage renal disease, suggesting that the clearance of Fab is slightly faster than that of total digoxin. Free digoxin concentrations fall rapidly after Fab administration and then rebound upwards within 12 to 24 hours. This rebound in free digoxin concentrations, however, is delayed by 12 to 130 hours in patients with renal dysfunction and end-stage renal disease. Rebound in free digoxin concentrations occurs during the initial phase of the biexponential decline of the serum concentration-time profile for digoxin-specific Fab, suggesting that distribution from the vascular spaces is the likely cause. Following the increase, free digoxin concentrations decline in a manner that is dependent on renal and nonrenal routes of elimination. During this time period it is evident that Fab retains it capability of binding digoxin while it resides in plasma. There is no evidence to support a dissociation between the Fab-digoxin complex over extended periods of time.(ABSTRACT TRUNCATED AT 250 WORDS)

Measurement and analysis of unbound drug concentrations.

The plasma protein binding of drugs has been shown to have significant effects on numerous aspects of clinical pharmacokinetics and pharmacodynamics. In many clinical situations, measurement of the total drug concentration does not provide the needed information concerning the unbound fraction of drug in plasma which is available for distribution, elimination, and pharmacodynamic action. Thus, accurate determination of unbound plasma drug concentrations is essential in the therapeutic monitoring of drugs. Many methodologies are available for determining the extent of plasma protein binding of drugs, however, in the clinical evaluation of drug therapy, equilibrium dialysis and ultrafiltration are the most routinely utilised methods. Both of these methods have been proven to be experimentally sound and to yield adequate protein binding data. Furthermore, the characterisation of the interactions between drug and protein molecules is essential for the assessment of the pharmacokinetic implications of drug-protein binding. Protein binding parameters which characterise the affinity of the drug-protein association, the number of classes of binding sites, the number of binding sites per class or protein and the binding capacity are useful for predicting unbound drug concentrations. Simple graphical methods have often been used to obtain protein binding parameters, but these methods have limitations and are not useful for drugs with more than 1 class of binding site. Therefore, the fitting of protein binding models which characterise the drug-protein binding interaction for experimental data is the preferred method of calculating binding parameters. Using the appropriate model, values for binding parameters are typically estimated by using nonlinear least-squares regression analysis.

Endotoxemia alters splanchnic capacitance.

The splanchnic circulation constitutes a major portion of the total capacitance vasculature and may affect venous return and subsequently cardiac output during low output states. This study assessed the effects of rapid (10 microg/kg over 5 min) and slow (10 microg/kg over 60 min) induction of endotoxin (Escherichia coli) shock on splanchnic blood volume in 8 farm swine. Blood volume was measured by using Tc99m-labeled erythrocytes and radionuclide imaging. Baseline arterial pressure (MAP), central venous pressure (CVP), and liver, splenic, mesenteric and total splanchnic volumes were stable during the 30-min baseline. Approximately 30 min after the rapid endotoxin infusion, splenic volume decreased by 45%, whereas liver volume increased by 40% and MAP decreased by 60% (P < 0.01). The reduction in splenic volume occurred within 10 min of the endotoxin infusion, whereas liver volume changes occurred after MAP reduction. The slow endotoxin infusion also reduced splenic volume by approximately 50% (P = 0.05), whereas MAP declined by 30% (P < 0.05). However, the slow endotoxin infusion lowered liver volume (P < 0.05). Mesenteric volume was unaffected by the fast or slow endotoxin infusion. Total splanchnic volume was unaffected by the fast infusion but decreased by 37% in the slow infusion group (P < 0.05). In summary, E. coli endotoxin reduces splenic blood volume and increases liver blood volume after acute hypotension ensues. Endotoxin does not increase total splanchnic blood volume and may actually decrease total splanchnic volume in the absence of circulatory collapse. This endotoxin shock model is not associated with blood volume pooling in the splanchnic capacitance circulation.

Influence of hypertonic saline solution infusion on defibrillation efficacy.

Hypertonic saline solution may enhance cardiac conduction via the fast inward sodium channel and alter transmembrane Ca+2 conductance via the sodium-calcium exchanger. Evidence suggests that both Ca+2 conductance and myocardial conduction velocity may affect ventricular defibrillation. Since hypertonic saline solution solutions (ie, sodium bicarbonate) may be administered to patients who have conditions that often require ventricular defibrillation (ie, cardiac arrest or hypovolemic shock), we studied the effect of hypertonic saline solution on the defibrillation threshold (DFT) in 16 pentobarbital-anesthetized domestic farm swine (20 to 30 kg). Defibrillation was performed using two interfaced epicardial electrode patches. DFTs were determined at baseline and during treatment phase. Pigs were randomly assigned to treatment consisting of either hypertonic saline solution (6 mmol/kg load, 2.0 to 3.0 mmol/kg infusion) to maintain serum sodium concentrations 10 to 15 mmol/L above baseline or control (D5W given in equal volume). DFT values (joules) that predicted 50% success were modeled from a best-fit histogram. Hypertonic saline solution did not change DFT values from baseline values (10.2 +/- 4.3 vs 10.8 +/- 7.0, respectively). Likewise, placebo (D5W) did not change DFT values from baseline values (10.1 +/- 4.5 vs 11.3 +/- 4.3). During treatment phase, DFT values were 99 +/- 28% of baseline values in the hypertonic saline solution group and 116 +/- 23% of baseline values in the D5W groups (p = 0.21). The administration of hypertonic saline solution also did not affect ventricular conduction velocity, right ventricular action potential duration, or right ventricular effective refractory period. These data indicate that hypertonic saline solution does not appreciably affect defibrillation efficacy or electrical treatment of ventricular fibrillation.

Disposition of intravenous amiodarone in subjects with normal and impaired renal function.

In a study designed to determine the influence of renal dysfunction on the disposition of amiodarone and its metabolite, desethylamiodarone (DEA), 30 subjects received a single 5 mg/kg intravenous dose of amiodarone over 15 minutes. Of the 30, 11 had normal renal function (group I; mean +/- SD glomerular filtration rate [GFR] = 118 +/- 20 mL/min/1.73 m2), 9 had renal impairment (group II; GFR = 23 +/- 10 mL/min/1.73 m2), and 10 were long-term hemodialysis patients (group III; 4 of these patients were studied during dialysis). Total and free concentrations of amiodarone and DEA were measured by high-performance liquid chromatography. There were no significant differences between the three groups in mean systemic clearance, steady state volume of distribution, or mean residence time of amiodarone. However, the area under the concentration-time curve (AUC) for amiodarone was significantly higher in group I than in group II, and this finding was related to total body weight. Free fraction was similar in groups I and III. The disposition of amiodarone and its metabolite DEA was similar in patients with normal renal function, moderate renal dysfunction, and end-stage renal disease. Thus, dosage adjustment in patients with renal impairment is not necessary based on this pharmacokinetic analysis.

Absorption of oral ciprofloxacin in a patient with cardiogenic shock.

Congestive heart failure and cardiogenic shock can alter the absorption process of some drugs. The absorption of ciprofloxacin has been studied in several disease states, but the effect of cardiogenic shock on its absorption is unknown. A 63-year-old man had a large myocardial infarction complicated by cardiogenic shock. When he began taking ciprofloxacin for pneumonia, he had renal and cardiac failure. Ciprofloxacin 500 mg was administered every 24 hours by nasogastric tube. Blood samples were collected 5 minutes prior to the second dose (20 hrs after the initial dose) and then regularly until 11 hours after the dose. Samples were analyzed using high-performance liquid chromatography. The trough concentration 20 hours after the initial dose was 3.7 micrograms/ml, and the serum concentrations after the second dose went from 5.6 to 4.94 micrograms/ml over the 11-hour sampling period. The peak concentration of 5.6 micrograms/ml occurred within 30 minutes after ciprofloxacin administration. It can be concluded from this case study that ciprofloxacin was adequately absorbed in this patient with multiple organ failure.

Angiotensin-converting enzyme inhibitors: mechanistic controversies.

Many studies have investigated the mechanisms responsible for the therapeutic effects of the angiotensin converting enzyme inhibitors. Initially, the hemodynamic changes that occur with these agents were attributed solely to the inhibition of the renin-angiotensin-aldosterone system in plasma. Further research suggested other mechanisms were operable as a relationship was not always evident between hemodynamic changes and inhibition of the plasma renin-angiotensin-aldosterone system. A relationship between the pharmacodynamics of these agents and the inhibition of vascular and tissue renin-angiotensin systems, however, has been observed. Mechanisms less likely to contribute to the actions of the angiotensin converting enzyme inhibitors are increases in bradykinin and prostaglandin concentrations, or inhibition in the renin-angiotensin system within the central nervous system. Ancillary cardiovascular effects of angiotensin converting enzyme inhibitors offer possible new therapeutic gains. An understanding of these mechanistic controversies and newly-defined cardiovascular actions of angiotensin converting enzyme inhibitors are important to clinicians using these agents.

Lidocaine does not affect myocardial electrical heterogeneity: implications for low proarrhythmic actions.

An area of unidirectional conduction block is one requirement for reentrant arrhythmias to occur. Functional block caused by dispersion of repolarization and refractoriness is the most probable mechanism of drug-induced unidirectional conduction block. We assessed the effects of lidocaine on spatial dispersion of myocardial repolarization and refractoriness in the intact porcine heart. Monophasic action potential duration at 90% repolarization, effective refractory period (ERP), and ventricular fibrillation cycle length (VFCL) were measured at two endocardial and one epicardial sites at baseline and during a treatment phase with D5W (n=11) or lidocaine 10 mg/kg/hour (n=12). Dispersion was calculated as the difference between the maximum and minimum values of the three recording sites. Lidocaine produced significant changes in ERP, VFCL, paced QRS duration, and intraventricular conduction time. It did not change basal levels of dispersion in repolarization and refractoriness. Lidocaine produced changes in myocardial electrophysiology that are uniform across the myocardium and thus did not change myocardial electrical heterogeneity. This may be a mechanism of the agent's lower proarrhythmic effects compared with other sodium channel blockers that increase myocardial electrical heterogeneity.

Evaluation and comparison of the adverse effects of streptokinase and alteplase.

The frequency and severity of adverse effects resulting from the administration of streptokinase and alteplase were determined in 126 consecutive patients who received standard dosages of these agents for the treatment of acute myocardial infarction. Evaluation was based on patient assessment by nursing staff, physicians, and the investigators before, during, and after thrombolytic administration. Overall, adverse effects occurred in 15 (41.7%) of 36 patients receiving streptokinase and 12 (13.3%) of 90 receiving alteplase (p = 0.001). No major bleeding or neurologic events were documented. Minor bleeding occurred in 13.9% and 7.8% of streptokinase and alteplase recipients, respectively (p = 0.47), and hypotension in 8 (22.2%) and 5 (5.6%), respectively (p = 0.01). The frequency of hypotension associated with streptokinase was significantly higher than that with alteplase. Thrombolytic-induced hypotension was easily managed and was not associated with sequelae.

Action potentials that mimic fibrillation activate sodium current.

Ventricular fibrillation (VF) has brief action potentials (50-70 ms) with short diastolic intervals (10-30 ms). Under these conditions ion channel activity may be grossly different to normal sinus rhythm (NSR). In particular, sodium channel activation may not contribute to the generation and propagation of action potentials during VF. This study determined if sodium channels can be activated when action potentials mimic VF. Isolated chick ventricular myocytes (n=7) were voltage-clamped to quantitate fast inward sodium current. The voltage clamp protocol simulated VF with a 10 pulse train at 10 Hz (100 ms cycle length (CL)) and depolarization interval (action potential duration) ranging from 90 to 20 ms. After each train a test pulse was delivered from holding (-80 mV) in 10-ms steps. The train preceded each step pulse. Peak sodium current for control and each VF protocol occurred at a membrane potential (V(m)) of -10 mV. Sodium current was evident during brief resting intervals as short as 20 ms, albeit 10-20% of baseline. Resting intervals less than 60 ms shifted the sodium conductance activation curve from Vm(0.5)-30 mV to -22 mV membrane potential. Similar findings occurred when resting potential was at -65 mV, although there was less sodium current with all tested protocols. There was significantly less inactivation of sodium current when the prepulse was shorter (100 v 1000 ms). There was approximately 20% greater sodium current when the test pulse followed a short v long depolarized (>-80 mV) prepulse. Although the longer depolarization pulses produce approximately 20% greater sodium current at membrane potentials more negative than -80 mV. Lastly the time for half recovery of sodium current from activation was significantly less when the inactivating prepulse was short v long (45.9+/-9 v 118+/-20 ms, P<0.05). In conclusion, sodium current is evident when the diastolic rest interval is as brief as 10-20 ms. Rest interval, length of membrane depolarization and membrane potential interact to affect sodium channel activation, inactivation and recovery from inactivation. These data demonstrate that the brief action potentials at more depolarized membrane potentials seen during VF allow for inward sodium current upon depolarization, less sodium channel inactivation, and a faster recovery from inactivation, thereby compensating for a short diastolic rest interval. Therefore, it is likely that the inward sodium channel contributes to wave front propagation during ventricular fibrillation.

Comparison of the pharmacokinetics and in vivo bioaffinity of DigiTAb versus Digibind.

The in vivo digoxin binding affinity and normal pharmacokinetic values of digoxin-immune Fab are unknown. Healthy subjects (n = 16) were randomized to one of the two digoxin-immune Fab products, DigiTAb or Digibind, to compare the in vivo digoxin binding affinity and pharmacokinetic disposition. Each subject received 1 mg of intravenous digoxin infused during 5 minutes followed 2 hours later by 76 mg of either DigiTAb or Digibind. Both Fab products reduced free digoxin serum concentrations to below assay detection with equal ability. Consequently, total digoxin serum concentrations increased approximately 10-fold. Peak total digoxin serum concentrations post-Fab dosing were similar to the pre-Fab peak digoxin concentration for both Fab products (45 +/- 14 and 44 +/- 11 for DigiTAb, pre and post, respectively) 50 +/- 17 and 41 +/- 9 for Digibind, pre and post, respectively) indicating in vivo equimolar binding affinity. While bioaffinity for digoxin was equal between groups, total digoxin area under the curve (AUC) and digoxin-immune Fab AUC were lower in the DigiTAb group compared with the Digibind group. Hence, systemic total digoxin and Fab clearance were greater in the DigiTAb-treated group. In conclusion, equimolar doses of both DigiTAb and Digibind completely bind digoxin in vivo. The ability of digoxinimmune Fab to bind to digoxin is not affected by the systemic disposition of the Fab product.

Regional hyperkalemia increases ventricular defibrillation energy requirements: role of electrical heterogeneity in defibrillation.

INTRODUCTION: Increased spatial electrical heterogeneity has been associated with impaired defibrillation efficacy. The current study investigated the relationship between electrical heterogeneity and defibrillation efficacy by manipulating spatial electrical heterogeneity. METHODS AND RESULTS: We increased spatial electrical heterogeneity by infusing potassium chloride (2 to 4 mEq/hour) or placebo in the left anterior descending artery in 13 pentobarbital anesthetized swine. Electrophysiologic measurements at five myocardial sites and defibrillation energy requirement (DER) values were determined at baseline and during regional hyperkalemia (n = 7) or placebo (n = 6). Regional potassium infusion was titrated to a 20% reduction in action potential duration in the perfused region. Regional hyperkalemia increased biphasic DER values by 87% (P = 0.02), whereas infusion of placebo did not alter defibrillation efficacy. Regional hyperkalemia decreased myocardial repolarization and refractoriness in the perfused region by 21% (P < 0.001) and 18% (P = 0.01), respectively. However, regional hyperkalemia increased ventricular fibrillation cycle length (VFCL) by 39% (P = 0.008). Consequently, dispersions of repolarization, refractoriness, and VFCL were significantly increased by 169%, 92%, and 200%, respectively. Regional hyperkalemia also increased ventricular conduction time to the perfused region by 54% (P = 0.006), indicating conduction velocity dispersion, while not affecting local pacing threshold or local voltage gradient. CONCLUSION: Regional hyperkalemia increased DER values. Regional hyperkalemia likely impairs defibrillation by increasing myocardial electrical heterogeneity, which supports the theory that electrical heterogeneity promotes nonuniform propagation of early postshock activations, thereby inhibiting defibrillation.

Role of exogenous adenosine as a modulator of theophylline toxicity.

OBJECTIVE: In animal models, exogenous adenosine can reverse theophylline-induced neurologic toxicity. Thus, we examined the ability of adenosine to oppose the cardiovascular toxicity of theophylline. DESIGN: Open-label, dose-response trial. SETTING: Animal laboratory within a college of pharmacy. SUBJECTS: Ten chloral hydrate-anesthetized male Sprague-Dawley rats. INTERVENTIONS: Indwelling catheters were surgically inserted into the right carotid artery and right external jugular vein. Subsequently, escalating doses of adenosine (5 to 2000 micrograms) were given at theophylline doses of 0, 10, 20, 30, 40, and 50 mg/kg until a maximum slowing in heart rate occurred. MEASUREMENTS AND MAIN RESULTS: Left ventricular systolic pressure and maximum positive maximal change in pressure over time (+dP/dt) were determined at baseline and at the time of maximum heart slowing, during adenosine, for each theophylline dose (0 to 50 mg/kg). Escalating doses of adenosine resulted in progressive heart rate slowing until maximum slowing occurred. The adenosine doses required to reach maximum slowing of heart rate were 118 +/- 24, 410 +/- 197, 620 +/- 256, 855 +/- 264, 944 +/- 329 and 1062 +/- 463 (SD) micrograms at theophylline doses of 0, 10, 20, 30, 40, and 50 mg/kg, respectively, which were correlated (r2 = .57, p < .001). At baseline, increasing theophylline doses produced a progressive reduction in left ventricular systolic pressure. However, adenosine at maximum slowing doses reversed this effect where left ventricular systolic pressure at 0 mg/kg of theophylline was similar to left ventricular systolic pressure at 50 mg/kg of theophylline (p < .05). At baseline, 10 to 50 mg/kg of theophylline had no significant effect on +dP/dtmax. However, adenosine (at maximum slowing) decreased +dP/dtmax before theophylline administration (p < .01). Theophylline at doses of 10 to 50 mg/kg reversed adenosine's negative inotropic effect, where +dP/dtmax values at maximum slowing were greater than values at 0 mg/kg of theophylline (p < .05). CONCLUSIONS: Adenosine can reverse theophylline-induced electrophysiologic and hemodynamic instability, whereas theophylline can reverse the negative inotropic actions of adenosine. However, higher adenosine doses are needed to elicit these changes as the theophylline dose increases.