The effects of mannitol diuresis on digoxin and phenobarbital handling by the kidney: implications for tubular reabsorption and secretion of the cardiac glycoside

The effect of mannitol diuresis on the renal clearance of digoxin and phenobarbital was studied in dogs. Mannitol diuresis significantly increased the clearance of digoxin and the ratio digoxin: inulin clearances (from 0.7 +/- 0.2 to 1.1 +/- 0.25). The increase in phenobarbital: inulin clearance ratio was significantly higher than the increase in the digoxin: inulin clearance ratio (4.9 fold vs 1.66 fold) (p less than 0.005). Mannitol diuresis did not significantly affect inulin clearance, nor digoxin protein binding during the experimental period while there was a significant increase in PAH clearance. Significant correlations were found between urine flow rate and digoxin renal clearance or digoxin: inulin clearance ratio. The increase in the ratio drug: inulin clearance with diuresis correlated inversely with the initial ratio; animals with more predominant net reabsorption had a higher increase in ratio. These studies suggest that the mannitol-induced increase in digoxin clearance stems from a combination of increased renal blood flow enhancing digoxin secretion, and increased urine flow rate inhibiting its reabsorption. We conclude that urine flow rate and renal blood flow are important determinants of the renal clearance of digoxin, independent of GFR. Any study assessing the effect of pathophysiological states or drug interactions on digoxin renal clearance must control for these factors.     

Effects of quinidine on the renal tubular and biliary transport of digoxin: in vivo and in vitro studies in the dog

Quinidine is known to inhibit the renal clearance of digoxin without affecting glomerular filtration rate. The renal interaction between these drugs was investigated by a combination of in vivo and in vitro methods. The uptake of digoxin by brush border membrane vesicles was not affected by quinidine. Similarly, digoxin did not inhibit the uptake of the cation N-methylnicotinamide by these vesicles and did not alter the binding kinetics of digoxin to the Na+, K+-adenosine triphosphatase by the antiluminal membrane vesicles. By using the in vivo multiple indicator dilution technique transtubular transport of digoxin was documented; renal-artery infusion of quinidine did not affect the recovery of digoxin in the renal vein or urine. Clearance studies documented that the decrease in the renal clearance of digoxin is paralleled by a significant fall in renal blood flow evidenced by a decrease in p-aminohippuric acid clearance. It is concluded that quinidine inhibits the renal excretion of digoxin not by competition at the tubular cell membrane level, but rather by decreasing renal blood flow. A parallel decrease in biliary clearance of digoxin is documented and may suggest a similar mechanism.     

Drug pharmacokinetics in the obese

In the obese, modifications in body constitution (higher percentage of fat and lower percentage of lean tissue and water) can affect drug distribution in the tissues. For slightly liposoluble molecules (e.g., digoxin, antipyrine), the equilibrium distribution volume (V), total and per kilogram weight, is significantly less than that of control subjects. With lipophilic drugs (e.g., barbiturates, benzodiazepines), this parameter is significantly increased, explaining the prolongation of the plasma elimination half-life. For drugs that are almost equally soluble in water and oil (methyl xanthines, aminoglycosides), the V is slightly increased in the obese. The other main factors involved in drug diffusion in the tissues are binding to plasma and tissue proteins, and regional blood flow. In the obese the binding of drugs to albumin does not seem to be altered. A marked increase in plasma alpha-glycoprotein acid and in propranolol binding has been reported in some studies; this has not been corroborated by other authors. Although the cardiac output and total blood volume are increased in the obese, the blood flow per gram of fat is less than in nonobese subjects. This could limit diffusion in the tissues of some lipophilic drugs. Studies on hepatic clearance of drugs are not available in the obese, but hepatic histological alterations have been described. In most publications concerning drugs with biotransformation as the principal elimination route, the total plasma clearance is not reduced. Up to the present, there are no reports of any impairment involving renal elimination of drugs in the obese. Dose-adjustment of hydrophilic drugs is assessed according to the ideal weight of the individual obese subject; with lipophilic drugs the loading dose can be fixed according to the total weight; calculation of the maintenance dose depends on possible changes in the total clearance.     

递增负荷运动对人体血清一氧化氮、肌酸激酶等指标的影响

目的了解递增负荷运动对人体一氧化氮(NO)活性及其他生物学指标的影响,为通过改变NO浓度来调节人体运动功能状态提供可能性。方法10名足球专业大学生在跑台上完成递增负荷运动直至力竭,测安静时、运动后即刻和恢复30min后的血清NO、血尿素氮、血清肌激酶(CK)和尿常规指标。结果运动后即刻NO出现显著升高(P<0.05),30min后虽仍高于安静值,但已无显著性差异。实验运动负荷未引起血尿素氮显著变化。CK活性在运动后即刻和恢复期30min后都非常显著地高于安静状态(P<0.01)。递增负荷力竭运动后受试者出现运动性蛋白尿。结论递增运动负荷导致血清NO一过性增高,血清肌激酶(CK)活性出现非常显著增高,出现运动性蛋白尿和较高的尿胆红素及尿胆原,提示剧烈运动引起肾小球通透性改变及血红蛋白的分解代谢增强。运动对血尿素氮未产生明显影响。     

Longitudinal assessment of a P-glycoprotein-mediated drug interaction of valspodar on digoxin.

OBJECTIVES: Valspodar is a P-glycoprotein modulator currently under development as a multidrug resistance reversal agent in clinical oncology. A multiple-dose drug interaction study was performed to assess the influence of valspodar on digoxin, a substrate for P-glycoprotein. METHODS: Twelve healthy volunteers received an oral digoxin loading dose of 1 mg on day 1, followed by 0.125 mg once daily to day 11. On day 7, a single oral 400-mg dose of valspodar was given, followed by a regimen of 200 mg twice daily from days 8 to 11. Serial blood samples and urine collections were obtained on days 6, 7, and 11 for digoxin pharmacokinetics and on days 7 and 11 for valspodar pharmacokinetics. On these days, blood pressure, pulse rate, and electrocardiograms were recorded at multiple time points. RESULTS: Coadministration of single-dose valspodar with steady-state digoxin on day 7 yielded an average 76% increase in digoxin AUC and a 62% decrease in digoxin renal clearance (both P = .0001). After a 5-day coadministration period, digoxin AUC increased by an average 211% and apparent total body clearance was decreased by 67% (day 11) compared with steady-state administration of digoxin alone (day 6). Contributing to the change in total body clearance were decreases in both renal clearance (73%) and apparent nonrenal clearance (58%). Both drugs were well tolerated throughout the study. There was no clinically relevant change in the effect of digoxin on vital signs or electrocardiographic parameters when administered with single- or multiple-dose valspodar compared with administration alone in volunteers with healthy cardiovascular systems. CONCLUSIONS: Coadministration of oral valspodar and oral digoxin resulted in a twofold to threefold increase in digoxin systemic exposure. On the basis of these data in healthy volunteers, an initial digoxin dose reduction of 50% would appear to be appropriate when beginning oral valspodar treatment. Throughout the period of coadministration, patients should be carefully monitored for clinical signs of digoxin toxicity in conjunction with digoxin therapeutic drug monitoring. Together, these should serve as the basis for individualized digoxin dose titration.     

Digoxin pharmacokinetics: role of renal failure in dosage regimen design.

Radioimmunoassayed serum concentration and urinary excretion data for digoxin from azotemic patients were characterized using a 2-compartment open model. Urinary excretion rates of digoxin as well as serum concentration data are needed to accurately characterize the disposition of the drug. Seven patients with renal failure showed highly variable steady-state volumes of distribution (V-ss-D equals 195 to 489 liters/1.73 m-minus2) and t1/2beta values (1.5 to 5.2 days). This variability is a major limiting factor in the use of dosage regimen nomograms that assume a constant V-ss-D and a rigorous relationship between t1/2beta and creatinine clearance (Cl-CR). Body clearance (Cl-B) is a parameter that is affected by both elimination and distribution of drugs. A linear relationship between Cl-B and renal clearance of digoxin or Cl-CR was found and was used to develop a model-independent approach to calculation of maintenance doses of digoxin. Several methods for calculating steady-state serum concentrations of digoxin (C-ss-p) were compared with actual measurements obtained in 16 chronically medicated patients. Optimum computation of C-ss-p is obtained by use of digoxin renal and body clearances. Variability in the digoxin:creatinine renal clearance ratio is the major limiting factor in prediction of digoxin dosage regimens.     

Removal of digoxin by column for specific adsorption of beta(2)-microglobulin: a potential use for digoxin intoxication.

BACKGROUND: A beta(2)-microglobulin adsorption column used for the treatment of dialysis-related amyloidosis removes serum beta(2)-microglobulin by recognition of lipophilic residue in the protein. No data are available for the adsorption of the highly lipophilic drug digoxin. METHODS: In vivo clearance of digoxin with the beta(2)-microglobulin column was measured by a single use of the column in 8 patients receiving hemodialysis with a therapeutic level of digoxin. In vitro adsorption was evaluated by use of incubation with adsorbent of the column and digoxin or ranitidine, a hydrophilic drug. Clearance with the beta(2)-microglobulin column was further compared with that obtained by use of activated charcoal in the dogs intoxicated with digoxin. RESULTS: Digoxin concentration was reduced from 1.11 +/- 0.25 ng/mL to 0.57 +/- 0.15 ng/mL at 240 minutes after initiation of hemoperfusion with the column in the patients. Digoxin clearance with the beta(2)-microglobulin column was about 145 +/- 20 mL/min, with a blood flow rate of 160 to 220 mL/min (80% of plasma flow rate). Eighty-five percent of digoxin was adsorbed in vitro, and the capacity of the beta(2)-microglobulin column was not saturated until a toxic level was reached (50 ng/mL). This value was higher than that obtained with use of charcoal. In dogs with digoxin intoxication, digoxin clearance was 38.9 +/- 1.5 mL/min, with a blood flow rate of 50 mL/min (95% of plasma flow rate), which was almost twice as that achieved with charcoal. The degree of thrombocytopenia and leukopenia was small with use of the beta(2)-microglobulin column. CONCLUSION: These data suggested that the beta(2)-microglobulin column selectively adsorbs digoxin. This column is a promising tool for the treatment of digoxin intoxication, especially in patients undergoing hemodialysis.     

Effect of physical activity on the day-to-day variation in serum digoxin concentration

Summary. Physical exercise has been found to increase digoxin binding in working skeletal muscle along with a concomitant decrease in serum digoxin concentration. In a recent study on healthy volunteers, moderate physical activity during maintenance digoxin treatment was shown to decrease the renal excretion of digoxin secondary to this redistribution of the drug, thereby affecting the body content of digoxin. In the present study the influence of changes in everyday physical activities, carried out during a 10-h period after ingestion of the daily maintenance digoxin dose, on the steady-state serum digoxin concentration (24 h after the last dose) was studied in 10 digoxin-treated outpatients (61–81 years of age). Compared to normal daily activity, complete bed rest for 10 h after ingestion of the maintenance dose did not affect the steady-state serum digoxin concentration. The lack of such an influence may be explained either by a low degree of everyday physical activity in the investigated patients or to a compensatory increase in the renal excretion of digoxin during the night preceding the serum digoxin measurement. Thus, standardization of physical activity 1–2 h before blood sampling is adequate when analysing the serum digoxin concentration in elderly outpatients.     

Population pharmacokinetic investigation of digoxin in Japanese neonates

OBJECTIVE: To establish the role of patient characteristics in estimating doses of digoxin for neonates using routine therapeutic drug monitoring data. METHOD: The steady-state blood level data (n = 129) after repetitive oral administration in 71 hospitalized neonates were analysed using Nonlinear Mixed Effects Modelling (nonmem), a computer program designed for analysing drug pharmacokinetics in study populations through pooling of data. Analysis of the pharmacokinetics of digoxin was accomplished using a one-compartment open pharmacokinetic model. The effect of a variety of developmental and demographic factors on digoxin disposition was investigated. RESULTS: Estimates generated by nonmem indicated that the clearance of digoxin (CL/F; L/h) was influenced by the demographic variables: total body weight (TBW), gestational age (GA) and neonate clearance factor (trough serum concentration of digoxin; Conc). These influences could be modelled by the equation CL/F = 0.0261 x TBW (kg)0.645 x Conc (ng/mL)(-0.724) x GA (weeks)0.8. The interindividual variability in digoxin clearance was modelled with proportional errors. The estimated coefficient of variation was 7.0%, and the residual variability was 13.1%. CONCLUSION: Clinical application of the model to patient care may permit selection of an appropriate initial maintenance dose, thus enabling the clinician to achieve the desired therapeutic effect. However, the digoxin dosage regimen for the individual patient should be based on a careful appraisal of their clinical need for the drug.     

Clinical utility of free drug monitoring.

Most drugs are bound to serum proteins to a various degree. Only unbound or free drug is pharmacologically active. Usually total drug is measured for therapeutic monitoring because there is equilibrium between bound and free drugs, and concentration of free drug can be predicted from total drug concentration. However, under certain conditions this equilibrium is disturbed and the measured free drug concentration can be significantly higher than expected from total drug concentrations, especially for strongly protein-bound drugs. In such case a patient may experience drug toxicity even if the total drug concentration is within the therapeutic range. Conditions like uremia, liver disease and hypoalbuminemia can lead to significant increases in free drug concentration. Therefore, monitoring free phenytoin and free valproic acid is recommended in these patients. Drug-drug interactions can also lead to a disproportionate increase in free drug concentration. One strongly protein-bound drug can significantly displace another strongly protein-bound drug if both drugs share the same binding site. Several over-the-counter pain medications such as salicylate, naproxen, and ibuprofen can cause significant displacement of both phenytoin and valproic acid from albumin binding site. Interestingly, such interactions are absent in uremic patients. Elderly patients may have increased free phenytoin or valproic acid due to hypoalbuminemia. Elevated free phenytoin concentrations have also been reported in patients with AIDS. Although digoxin is 25% bound to protein, monitoring free digoxin is useful in patients with elevated endogenous digoxin-like immunoreactive substances or in patients overdosed with digoxin and being treated with digibind. Monitoring free digoxin can also eliminate interference of Chinese medicines Chan Su and Danshen in serum digoxin measurement by certain immunoassays. However, free drug monitoring is not a routine procedure in clinical laboratories due to technical difficulties and lack of established reference ranges for free drugs.     

Substantial pharmacokinetic interaction between digoxin and ritonavir in healthy volunteers

BACKGROUND: Ritonavir is a potent in vitro inhibitor of several cytochrome P450 isozymes and ABC transporters including the efflux pump P-glycoprotein (P-gp). This study assessed the effect of repetitive ritonavir administration on digoxin distribution and total and renal digoxin clearance as a marker for P-gp activity in vivo. METHODS: In a randomized, placebo-controlled crossover study, 12 healthy male participants received oral ritonavir (300 mg twice daily) for 11 days. With the assumption that ritonavir steady state had been reached, 0.5 mg digoxin was given intravenously on day 3. Digoxin concentrations were determined in plasma and urine by radioimmunoassay, and plasma ritonavir concentrations were determined by liquid chromatography-tandem mass spectrometry. Digoxin kinetics was estimated by compartmental and noncompartmental analyses, by use of the area under the plasma concentration-time curve, and the corresponding digoxin amount excreted into urine was used for digoxin clearance calculations. RESULTS: Ritonavir significantly (P <.01) increased digoxin area under the plasma concentration-time curve from time 0 to infinity by 86% and its volume of distribution by 77% and decreased nonrenal and renal digoxin clearance by 48% and 35%, respectively. Digoxin terminal half-life in plasma increased by 156% (P <.01). CONCLUSION: This inhibition of renal digoxin clearance is likely caused by ritonavir inhibition of P-gp. Its extent is considerable and similar to the effect of other potent P-gp inhibitors on digoxin disposition such as quinidine. These findings may, therefore, indicate that the pharmacokinetics of P-gp substrates sharing the renal tubular elimination pathway will be affected when combined with therapeutic doses of ritonavir in antiretroviral treatment regimens. In addition and contrarily to quinidine, these data indicate that ritonavir promotes digoxin distribution in the body.     

Population analysis for the optimization of digoxin treatment in Japanese paediatric patients

BACKGROUND AND OBJECTIVES: Information about the pharmacokinetics of digoxin in paediatric patients is limited. We therefore aimed to investigate the effects of physiological factors on the digoxin clearance in Japanese paediatric patients. METHOD: We used routinely collected therapeutic drug monitoring data (n=544), derived from the steady-state serum concentrations of digoxin in 181 hospitalized paediatric patients. RESULTS: Of those physiological factors which have been examined in this study, age and total body weight were most closely correlated with digoxin clearance. Data on neonates within the first postnatal month indicated a tendency towards lower clearance for premature neonates than full-term neonates (P<0.01). Digoxin clearance was reduced by spironolactone in patients younger than 4 months (P<0.05). Patients with congestive heart failure showed a lower digoxin clearance than the others (P<0.001). Serum creatinine and gender did not have a statistically significant effect on digoxin clearance. CONCLUSION: Age and total body weight are important factors influencing digoxin clearance in children. Spironolactone affected digoxin clearance and needs to be considered when dosing paediatric subjects.     

Effect of aging on the incidence of digoxin toxicity

OBJECTIVE: To evaluate the relationship of the therapeutic serum digoxin concentration (SDC) range (0.5-2 ng/mL, as recommended in previous clinical studies) with the incidence of digoxin toxicity during digoxin maintenance therapy. METHODS: Subjects included all inpatients (n = 462) and outpatients (n = 437) receiving digoxin oral maintenance therapy for heart failure and/or atrial fibrillation with tachycardia at Kosei Hospital, Anjo, Japan. SDC and blood chemistry analysis were determined, and a 24-hour Holter electrocardiographic recording was performed when the SDC was at the presumed steady-state concentration. RESULTS: Analysis of clinical data showed that there was an overlapping (toxic and nontoxic) range of SDCs in which the incidence of digoxin toxicity was patient-dependent (1.4-2.9 ng/mL). No patient exhibited signs or symptoms of digoxin toxicity when the SDC was <1.4 ng/mL; all patients had evidence of toxicity when the SDC was >3 ng/mL. Additionally, it was shown that the concentration range of this overlapping range tended to broaden and shift to lower concentrations with increasing age. Patients with signs of toxicity when their SDCs were in the overlapping range had normal serum creatinine, blood urea nitrogen, digoxin clearance, creatinine clearance, and potassium concentrations, except for a significantly higher mean age than patients without toxicity. The incidence of digoxin toxicity was dependent on increasing age in patients whose SDCs were within the recommended therapeutic range. Moreover, clinical evidence of digoxin toxicity in patients >71 years old was 26.5%, despite their SDCs falling between 1.4 and 2 ng/mL. CONCLUSIONS: Increased age is most likely associated with enhanced susceptibility to digoxin toxicity, possibly due to unknown pharmacodynamic changes. This raises the possibility that patients >71 years show clinical evidence of digoxin toxicity despite having SDCs within the recommended therapeutic range.     

St. John's wort does not interfere with therapeutic drug monitoring of 12 commonly monitored drugs using immunoassays

St. John's wort, a popular herbal remedy for depression, is known to interact with many Western drugs because of the ability of its components to induce liver enzymes. Lower concentrations of various drugs due to increased clearance have been reported. Because immunoassays are commonly used in clinical laboratories for therapeutic drug monitoring, we studied the potential interference of St. John's wort with commonly monitored therapeutic drugs. Drug-free serum pools were supplemented with St. John's wort to achieve in vitro St. John's wort concentrations mimicking in vivo concentrations after both recommended use and overdose. Concentrations of digoxin, tricyclic antidepressants (TCAs), phenytoin, carbamazepine, theophylline, valproic acid, quinidine, phenobarbital, procainamide, and N-acetyl procainamide were measured in serum. Pooled serum specimens from patients who were taking a particular drug were also supplemented in vitro with concentrations of St. John's wort to investigate whether observed concentrations changed after supplementation with St. John's wort. The effect of St. John's wort on cyclosporine and tacrolimus (FK 506) was studied in whole blood. We found no significant interference from St. John's wort with any assay studied. Moreover, when drug-free serum was supplemented with very high concentrations of hypericin (2 microg/mL) and hyperforin (2 microg/mL) pure standard, we observed no apparent drug level with any immunoassay. The presence of both hypericin and hyperforin was also confirmed by thin layer chromatography (TLC) in both preparations of St. John's wort. We conclude that immunoassays may be used to measure levels of therapeutic drugs in patients who self-medicate with St. John's wort.     

Interindividual variability of drug transporters: Impact on opioid treatment in chronic renal failure

Some transmembrane transporters influence the absorption, the tissue distribution and the elimination of opioids, and their genetic variants may be an important factor in therapeutic efficacy and toxicity. Uptake and efflux transporters may facilitate or limit access of opioids to blood–brain barrier (BBB), modulating pain relief. As renal function is crucial in the metabolism and pharmacokinetic profile of any drug, renal failure and end-stage renal disease may alter drug disposition by affecting protein and tissue binding, and reducing systemic clearance of drugs.     

Population Pharmacokinetics of Digoxin in Duchenne Muscular Dystrophy (DMD) Patients

Routine clinical pharmacokinetic data collected from Duchenne muscular dystrophy (DMD) patients receiving digoxin have been analyzed to evaluate the role of patients' characteristics for estimating dosing regimens. The data were analyzed using NONMEM, a computer program designed for population pharmacokinetic analysis that allows pooling of data. The pharmacokinetic model of digoxin was described using a one-compartment steady-state model. The effect of factors on digoxin clearance was investigated. NONMEM estimates indicate that digoxin clearance was influenced by the variables of body weight and combination with diuretics. The interindividual variability in digoxin clearance was modeled with proportional error with an estimated coefficient of variation of 25%, and the intraindividual variability in digoxin concentration was modeled with equal error with an estimated standard deviation of 0.0828 ng ml(minus sign1). In order to determine whether the population parameters obtained in this study were accurate, we administered digoxin according to individual dosage regimens in four DMD patients, using these values obtained by the Bayesian method. As a result, we found that mean prediction error, which indicates the deviation of prediction accuracy for digoxin concentration in plasma, was small, as were mean absolute prediction error and root mean squared error, showing the accuracy of this prediction method. The dosing method based on clearance values obtained by NONMEM analysis allowed the prediction of the steady-state concentration as a function of maintenance dose with acceptable error for therapeutic drug monitoring.     

Increased Clearance of Antipyrine and d-Propranolol after Phenobarbital Treatment in the Monkey: RELATIVE CONTRIBUTIONS OF ENZYME INDUCTION AND INCREASED HEPATIC BLOOD FLOW

The effects of phenobarbital treatment for 12 days on the regional distribution of blood flow and on the disposition of two model drugs, antipyrine and d-propranolol, have been determined in six unanesthetized rhesus monkeys. Phenobarbital significantly increased total hepatic blood flow from 179+/-15 to 239+/-27 ml/min. Liver weight was increased to a similar degree (34%) in phenobarbital-treated animals as compared to control monkeys. The clearance of both antipyrine and d-propranolol was increased and the half-life decreased significantly by phenobarbital. Analysis of the data by a perfusion-limited pharmacokinetic model showed that the changes in antipyrine clearance were due almost entirely to enzyme induction. On the other hand, with d-propranolol, the increase in liver blood flow contributed as much to the enhanced clearance as did the stimulation of drug metabolism. The mechanism by which phenobarbital produces the frequently observed increase in drug clearance, therefore, depends upon the initial clearance value of the drug. For low clearance drugs like antipyrine, clearance changes occur largely as a result of enzyme induction. With higher clearance drugs, the effects of increased hepatic blood flow become progressively more important the greater the initial clearance value.     

Effect of hemorrhagic shock on cefazolin and gentamicin pharmacokinetics in dogs.

The physiologic response to traumatic injury may alter the disposition of drugs and thereby affect their therapeutic or toxic potential. A study was conducted in 10 mongrel dogs to determine the effect of experimental hemorrhagic shock with resuscitation on the pharmacokinetics of gentamicin and cefazolin. Single simultaneous intravenous doses of gentamicin (3 mg/kg) and cefazolin (25 mg/kg) were administered to each animal on an initial study day, after which serial blood and urine collections were performed. After 1 week, a standard hemorrhagic shock model was applied to each animal. Shock was continued for 1 h, after which the animal was resuscitated with either whole blood or saline. After stabilization for 20 min, a second dose of gentamicin and cefazolin was administered, and blood and urine were again collected. Drug clearance was not significantly altered, except for that of cefazolin after saline resuscitation, for which there was a significant increase in drug clearance. After both methods of resuscitation an increase in the volume of distribution was noted for cefazolin and gentamicin. Drug half-life was noted to be increased after shock for cefazolin by both resuscitation methods and for gentamicin after shock by saline resuscitation. Although alterations of pharmacokinetic parameters were noted, mean concentrations of gentamicin and cefazolin in serum were similar for pre- and postshock phases.     

Influence of everyday physical activity on the serum digoxin concentration in digoxin-treated patients

Summary. Thirteen patients admitted to hospital because of known or suspected cardiac disease who had been treated with digoxin within, at least, the previous month were investigated. Blood samples for serum digoxin analysis by radioimmunoassay were taken before and after 40 min rest in supine in the ward and later in the outpatient clinic, all samples taken about 24 h after the last dose of digoxin. The serum digoxin concentration measured before rest in the outpatient clinic was significantly lower than those measured in the ward before and after rest. This is possibly related to physical activity prior to blood sampling since after 40 min rest in the outpatient clinic the serum digoxin concentration had increased and the concentration after rest was not significantly different from the concentrations measured in the ward. In analogy with a previous finding of a decrease in serum digoxin concentration during exercise in healthy subjects ingesting digoxin, the present results suggest that everyday physical activity affects the serum digoxin concentration. This must be taken into account when interpreting the results of serum digoxin measurements.     

Endogenous digoxin-like immunoreactive factors: impact on digoxin measurements and potential physiological implications

Various laboratories have reported endogenous digoxin-like immunoreactive factor(s) (DLIF) in blood from patients in renal failure or liver failure, from newborn infants, and from third-trimester pregnant women. Similar immunoreactivity has been detected in amniotic fluid, in cord blood, and in urine and serum from normal subjects. The factor(s) giving rise to this immunoreactivity cross react with antibodies used in many currently available immunoassays for digoxin, sometimes causing apparent digoxin concentrations exceeding the therapeutic range obtained for exogenous digoxin, with consequent errors in measurement and in subsequent clinical interpretation of digoxin results. Here, I summarize findings in our laboratory and those of others. DLIF evidently exist in three states in serum: tightly protein-bound, weakly protein-bound, and unbound (free). In normal subjects, greater than 90% of the total DLIF in serum is tightly but reversibly bound to serum proteins and is not readily detectable by direct measurement of digoxin in serum with conventional immunoassays. However, there seems to be a redistribution of the more weakly bound and unbound components in patients with renal failure, pregnant women, and newborns. The increased values detected in these groups are ascribable to increased amounts of weakly bound and unbound DLIF rather than to increased total DLIF. Carrier proteins may play a prominent role in the transport of these factors in blood. I discuss the potential physiological and pharmacological implications of detecting endogenous immunoreactive factors that cross react with antibodies to drugs.