On the role of alpha 1-acid glycoprotein in lignocaine accumulation following myocardial infarction

Pharmacokinetics in older persons

BACKGROUND

Physiologic changes and disease-related alterations in organ function occur with aging. These changes can affect drug pharmacokinetics in older persons.

OBJECTIVE

This article reviews age-related changes in pharmacokinetics and their clinical relevance.

METHODS

A PubMed search was conducted using the terms elderly and pharmacokinetics. Other reviews were also included for literature searching. The review includes literature in particular from 1990 through April 2004. Some articles from before 1990 were included to help illustrate principles of age-related pharmacokinetics.

RESULTS

There are minor changes in drug absorption with aging. The effect of aging on small-bowel transporter systems is not yet fully established. Bioavailability of highly extracted drugs often is increased with age. Transdermal absorption may be delayed, especially in the case of water-soluble compounds. Fat-soluble drugs may distribute more widely and water-soluble drugs less extensively in older persons. Hepatic drug metabolism shows wide interindividual variation, and in many cases, there is an age-related decline in elimination of metabolized drugs, particularly those eliminated by the cytochrome enzyme system. Any decrement in cytochrome enzyme metabolism appears nonselective. Synthetic conjugation metabolism is less affected by age. Pseudocapillarization of the sinusoidal endothelium in the liver, restricting oxygen diffusion, and the decline in liver size and liver blood flow may influence age-related changes in rate of hepatic metabolism. Frailty, physiological stress, and illness are important predictors of drug metabolism in older individuals. Inhibition of drug metabolism is not altered with aging, but induction is reduced in a minority of studies. Renal drug elimination typically declines with age, commensurate with the fall in creatinine clearance. Renal tubular organic acid transport may decline with age, while the function of the organic base transporter is preserved but may be less responsive to stimulation.

CONCLUSION

Changes in pharmacokinetics occur due to age-related physiologic perturbations. These changes contribute to altered dose requirements in older persons, particularly in the case of drugs eliminated by the kidney. Interindividual variation, disease, frailty, and stress may overshadow age-related changes.

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.

Human alpha-1-glycoprotein and its interactions with drugs

For about half a century, the binding of drugs to plasma albumin, the "silent receptor," has been recognized as one of the major determinants of drug action, distribution, and disposition. In the last decade, the binding of drugs, especially but not exclusively basic entities, to another plasma protein, alpha 1-acid glycoprotein (AAG), has increasingly become important in this regard. The present review points out that hundreds of drugs with diverse structures bind to this glycoprotein. Although plasma concentration of AAG is much lower than that of albumin, AAG can become the major drug binding macromolecule in plasma with significant clinical implications. Also, briefly reviewed are the physiological, pathological, and genetic factors that influence binding, the role of AAG in drug-drug interactions, especially the displacement of drugs and endogenous substances from AAG binding sites, and pharmacokinetic and clinical consequences of such interactions. It can be predicted that in the future, rapid automatic methods to measure binding to albumin and/or AAG will routinely be used in drug development and in clinical practice to predict and/or guide therapy.

Effect of alpha(1)-acid glycoprotein on the pharmacokinetics of tamsulosin in rats treated with turpentine oil

The pharmacokinetics of tamsulosin (TAM) was investigated using male Sprague-Dawley rats in which plasma alpha(1)-acid glycoprotein (alpha(1)-AGP) levels were elevated by the subcutaneous injection of 0.2 mL/kg of turpentine oil. alpha(1)-AGP levels increased about eight times after turpentine oil treatment, causing a threefold decrease in plasma unbound fraction (f(u)) of TAM. When 0.3 mg/kg of TAM was dosed intravenously, total and nonrenal clearances (CL(tot) and CL(nr)) in turpentine-treated rats were 47% and 44% lower than those in nontreated controls, respectively. The area under the concentration-time curve of plasma unbound TAM (AUC(inf,u)) was lower than that in the control. When 1 mg/kg of TAM was dosed orally, oral clearance (CL(oral)) in alpha1-AGP-induced rats was 65% lower than in the control. The AUC(inf,u) and unbound oral clearance (CL(oral,u)) were nearly equal in both groups. Moreover, a positive correlation was observed between fu and CL(oral) of TAM (r(2) = 0.603, P < 0.01), whereas no correlation was observed between f(u) and CL(oral,u). The absolute bioavailability (BA) increased from 19.2% to 46.9% by induction of alpha(1)-AGP. These results suggest that decreased f(u) caused by the elevation of plasma alpha(1)-AGP level affects the pharmacokinetics of TAM, but does not affect the CL(oral,u,) which represents the hepatic metabolism of TAM.

Effects of intravenous infusion of lidocaine on its pharmacokinetics in conscious instrumented dogs

In this study, potential alterations in hepatic blood flow, plasma protein binding, hepatic tissue binding, and enzyme activities induced by LD iv infusion of lidocaine (LD) were evaluated using a chronically instrumented dog model. Four conscious female mongrel dogs (19.0-23.5 kg) were each given, on days 1 and 10, a 5-min infusion of a mixture of unlabeled LD at approximately 2 mg/kg and 14C-labeled LD at approximately 25 microCi and, on day 8, a 12-h constant rate iv infusion of LD (approximately 76 microg/kg/min). During LD infusion, there was a 11-79% increase in total hepatic blood flow, mainly due to a 1.6-9.2-fold increase in hepatic arterial flow. Despite similar blood clearance (27.5 +/- 6.0 mL/min/kg vs 27.5 +/- 3.5 mL/min/kg), volume of distribution at steady state (1.38 +/- 0.08 L/kg vs 1.36 +/- 0.17 L/kg), and free fraction values of LD between days 1 and 10 (p > 0.05), intrinsic clearance values were consistently reduced (1224 +/- 859 mL/ min/kg vs 285 +/- 104 mL/min/kg; p = 0.034). Furthermore, hepatic tissue uptake of LD and/or its metabolites was less on day 10 than on day 1 (39.7 +/- 14.5 micromol vs 30.1 +/- 15.1 micromol; p = 0.072). The extent of N-dealkylation of LD to MEGX was unaltered, whereas sequential biotransformation of MEGX was impaired. Hence, these findings suggested that LD infusion led to a reduction of hepatic intrinsic clearance, although the change was not significant enough to alter its conventional kinetic parameters.

Pharmacokinetics of tamsulosin hydrochloride in patients with renal impairment: effects of alpha 1-acid glycoprotein

The pharmacokinetics of tamsulosin hydrochloride in patients with renal impairment were compared with those in healthy volunteers, and the factors that influenced plasma levels of tamsulosin were elucidated. A single oral dose of 0.2 mg of tamsulosin was given and blood and urine samples were obtained for 36 hours after administration. Unbound plasma concentration of tamsulosin was measured by a combination of equilibrium dialysis and liquid chromatography tandem mass spectrometry methods to examine the effect of protein binding on the pharmacokinetics of tamsulosin. Mean values for maximum concentration (Cmax) and area under the concentration-time curve (AUC) of total drug (Cmax,t and AUC1) in patients with renal impairment were 73% and 211% greater, respectively, than those in healthy volunteers. Mean Cmax and AUC of unbound drug (Cmax,u and AUCu), however, were almost the same in the two groups. A high correlation was found between alpha 1-acid glycoprotein (alpha 1-AGP) concentration and AUCt, but no correlation was found between alpha 1-AGP concentration and AUCu,0-36) or between creatinine clearance (ClCR) and AUCu,0-36). These results show that in patients with renal impairment, the pharmacokinetics of tamsulosin are affected by the change in protein binding that is associated with alteration of plasma alpha 1-AGP concentration, but are not largely affected by the decrease in the renal excretion. Although total tamsulosin levels increased as plasma protein binding increased, unbound tamsulosin levels (which are directly associated with the pharmacologic effects) remained unchanged in these patients.

Purification method for alpha-1-acid glycoprotein with subsequent high-performance liquid chromatographic determination of monosaccharides in plasma of healthy subjects and patients with renal insufficiency

A simple purification method for human plasma alpha-1-acid glycoprotein (AAG) using an ion-exchange and hydroxyapatite column was developed. The recovery of the method was found to be high. We also improved a determination method for N-acetylneuraminic acid and monosaccharides in the carbohydrate moiety of AAG by using an ion-exchange column and pulse-amperometric detection. By this method, a composition analysis of the carbohydrate moiety of AAG (N-acetylneuraminic acid, fucose, N-acetyl glucosamine, galactose and mannose) was possible with 1.0 ml of plasma. We compared these carbohydrate concentrations in the AAG of patients with renal insufficiency with those of healthy subjects. In the AAG of the patients, the concentrations of N-acetylglucosamine, galactose and mannose were significantly higher than those in the AAG of the healthy subjects.

Rapid and simple method for the determination of alpha 1-acid glycoprotein in serum by column liquid chromatography

A rapid and simple method for the determination of alpha 1-acid glycoprotein (AAG) in serum was developed by using an anion-exchange column for clean-up of serum and a hydroxyapatite column for high-performance liquid chromatography (HPLC). A good correlation was observed between this HPLC method and the conventional radial immunodiffusion method. The method may also be used to determine the AAG concentration in the serum of experimental animals.

Nonlinear pharmacokinetics: clinical Implications

Nonlinear pharmacokinetics (in other words, time or dose dependences in pharmacokinetic parameters) can arise from factors associated with absorption, first-pass metabolism, binding, excretion and biotransformation. Nonlinearities in absorption and bioavailability can cause increases in drug concentrations that are disproportionately high or low relative to the change in dose. One of the more important sources of nonlinearity is the partial saturation of presystemic metabolism exhibited by such drugs as verapamil, propranolol and hydralazine. In such cases, circulating drug concentrations are sensitive not only to dose size but also to rate of absorption: slower absorption may decrease the overall systemic availability. The binding of drugs to plasma constituents, blood cells and extravascular tissue may exhibit concentration dependence. This can cause pharmacokinetic parameters based on total blood or serum drug concentrations to be concentration-dependent. Often, in these cases, parameters based on free drug concentration appear linear. An important consideration in regard to concentration-dependent serum binding is the difficulty in relating total concentration to a usual therapeutic range if free concentration is a better indicator of drug effect. Measurement of free concentration is needed in these cases, particularly if the intersubject variability in binding is high. An example of this behaviour is valproic acid. Partial saturation of elimination pathways can result in the well known behaviour typical of Michaelis-Menten pharmacokinetics. Small changes in dosing rate can make much larger differences in steady-state concentration. The time to achieve a given fraction of steady-state becomes longer as the dosing rate approaches the maximum elimination rate. Alcohol and phenytoin are examples of drugs that exhibit such behaviour. The sensitivity of steady-state concentration and cumulation rate to changes in dosing rate are both influenced by the magnitude of parallel first-order elimination pathways: even a first-order pathway that is only 1 to 2% of maximum clearance (which occurs at very low concentration) can be an important determinant of steady-state concentration and cumulation rate when concentrations are high. Theophylline and salicylate have significant parallel first-order elimination pathways as well as saturable pathways. Autoinduction causes an increase in clearance with long term administration. In some cases, dosage adjustment must be made to compensate for the increase, and the possibility that the degree of induction may be dose- or concentration-dependent must be kept in mind. Carbamazepine is a major example of autoinduction. It is fortunate that only a few of the many hundreds of drugs in use exhibit nonlinear behaviour that leads to clinical implications.(ABSTRACT TRUNCATED AT 400 WORDS)

Disease-induced variations in plasma protein levels. Implications for drug dosage regimens (Part II)

Part I of this article, which appeared in the previous issue of the Journal, discussed the implications of variations in plasma protein levels in a number of diseases: hepatic and renal disease, acute myocardial infarction, burns, cancer, diabetes mellitus, hyperlipidaemia and inflammatory diseases. In Part II the authors continue their review with a further range of disease states, and consider their import for drug dosages.

Poisoning due to class 1B antiarrhythmic drugs. Lignocaine, mexiletine and tocainide

Since most of the toxicity associated with class 1B antiarrhythmic drugs is dose-related, this review examines adverse effects seen in both therapeutic practice and accidental or premeditated overdose. Toxicity is very common with these agents and can be life-threatening. A high percentage of patients must discontinue therapy because of adverse effects. Mexiletine and tocainide are structural analogues of lignocaine (lidocaine) and toxicity is similar with all 3 drugs. With gradual intoxication (the most common form) central nervous system effects such as lightheadedness, dizziness, drowsiness and confusion are seen first. Seizures and respiratory arrest can occur. Cardiovascular toxicity is manifested by progressive heart block, reduced cardiac contraction, hypotension and asystole. Both mexiletine and tocainide may have proarrhythmic effects. Gastrointestinal toxicity is also common. Shock, hypotension, cardiac failure and beta-blocker therapy reduce lignocaine clearance and enhance the risk of intoxication during routine therapy. Both lignocaine and mexiletine elimination is impaired in severe liver disease while tocainide clearance is reduced in renal failure. Management of toxicity is largely supportive and symptomatic. Lignocaine infusion must be discontinued and decontamination of the gut in the case of oral preparations is recommended. Serious intoxication requires intensive care unit admission. Haemodialysis or haemoperfusion may be helpful in serious lignocaine and tocainide poisoning. In institutions where extracorporeal circulatory assistance is available, massive lignocaine poisoning has been successfully treated with this intervention. In the therapeutic setting serious toxicity can be prevented by close clinical surveillance and appropriate dose reduction in patients with reduced drug clearance. Because of the large interindividual variation in lignocaine pharmacokinetic parameters, therapeutic drug monitoring is recommended if results can be reported quickly. Mexiletine and tocainide have stereoselective metabolism and assays do not distinguish the more active isomers. Therapeutic drug monitoring is less useful in this situation.

Factors affecting free (unbound) lignocaine concentration in suspected acute myocardial infarction

1. Free plasma lignocaine concentrations were measured for up to 48 h after constant infusion of the drug in 41 subjects with suspected acute myocardial infarction. 2. The free plasma lignocaine clearance at 12 h was significantly and proportionately related to body weight and to the presence of mild (Killip Class II) heart failure, with an 18% reduction in free clearance in the latter condition. 3. The free plasma lignocaine was not related to sex, age or the presence of confirmed acute myocardial infarction, when corrected for the effects of body weight and presence of heart failure. 4. Free plasma lignocaine concentration 1 h after a fixed loading dose were also significantly related to body weight and presence of heart failure but not to sex, age or proven acute myocardial infarction. 5. The data indicate that correction of loading and maintenance infusion for body weight and presence of (even mild) heart failure should somewhat reduce variability in free (and presumably active) plasma lignocaine concentrations but that the free plasma lignocaine concentration at 12 h is most accurately predicted by measuring the free (and to a lesser extent total) plasma lignocaine concentration at 1 h.

Effects of cardiovascular disease on pharmacokinetics

The pathophysiologic changes occurring in cardiovascular disease can affect the kinetics of drugs in several different ways. The present review examines these modifications and the underlying mechanisms. The kinetics of specific agents, such as antiarrhythmic, antihypertensive, cardiotonic, and other drugs are considered, and the clinical implications are outlined. The clinician should be aware of these modifications, because they require an adjustment of the dosage regimen. A rational basis for a correct therapeutic choice can be provided by adequate knowledge of these modifications.

Systemic absorption of tetracycline and lidocaine following intrapleural instillation

Seven patients with symptomatic pleural effusions (six) and recurrent pneumothorax (one) underwent attempted pleurodesis using tetracycline. Lidocaine (150 mg), followed immediately by tetracycline (20 mg/kg), was instilled into the pleural space through a chest tube. Venous blood was obtained at 0, 15, 30, 60, and 120 minutes following instillation in order to determine concentrations of lidocaine and tetracycline. The mean peak serum concentration of lidocaine was 1.3 mu/ml +/- 0.4 microgram/ml (mean +/- SE) (range, 0.3 microgram/ml to 3.2 microgram/ml), and the mean time to peak serum concentration of lidocaine was 86 +/- 13 minutes. The mean peak serum concentration of tetracycline was 3.6 microgram/ml +/- 0.9 microgram/ml (range, 1.0 microgram/ml to 5.0 micrograms/ml), and the mean time to peak serum concentration of tetracycline was 96 +/- 16 minutes. Therapeutic serum concentrations of lidocaine were found in four of the seven patients and therapeutic serum levels of tetracycline in four of five patients. With systemic absorption of lidocaine and tetracycline following intrapleural instillation, patients are at risk for potential toxic effects. If lidocaine is used in a dosage of less than 3 mg/kg, toxic levels of the drug are unlikely to occur. Furthermore, use of tetracycline or lidocaine in pleurodesis is contraindicated in patients with known sensitivity to the drugs.

The pharmacokinetics of lignocaine and beta-adrenoceptor antagonists in patients with acute myocardial infarction

Lignocaine (lidocaine) and beta-adrenoceptor antagonists are widely used after acute myocardial infarction. The therapeutic value of these agents depends on the achievement and maintenance of safe and effective plasma concentrations. Lignocaine pharmacokinetics after acute myocardial infarction (MI) are controlled by a number of variables. The single most important is left ventricular function, which affects both volume of distribution and plasma clearance. Other major factors include bodyweight, age, hepatic function, the presence of obesity, and concomitant drug therapy. Lignocaine is extensively bound to alpha 1-acid glycoprotein, a plasma protein which is also an acute phase reactant. Increases in alpha 1-acid glycoprotein concentration occur after an acute MI, decreasing the free fraction of lignocaine in the plasma and consequently decreasing total plasma lignocaine clearance without altering the clearance of non-protein-bound lignocaine. Complex changes in lignocaine disposition occur with long term infusions, and therefore early discontinuation of lignocaine infusions (within 24 hours) should be undertaken whenever possible. Because the risk of ventricular tachyarrhythmia declines rapidly after the onset of an acute MI, lignocaine therapy can be rationally discontinued within 24 hours in most patients. Lignocaine has a narrow toxic/therapeutic index, so that pharmacokinetic factors are critical in dose selection. In contrast, beta-adrenoceptor antagonists' adverse effects are more related to the presence of predisposing conditions (such as asthma, heart failure, bradyarrhythmias, etc.) than to plasma concentration. The pharmacokinetics of beta-adrenoceptor antagonists are important to help assure therapeutic efficacy, to provide information about the anticipated time course of drug action, and to predict the possible role of ancillary drug effects (such as direct membrane action) and loss of cardioselectivity. Lipid solubility is the main determinant of the pharmacokinetic properties of a beta-adrenoceptor antagonist. Lipid-soluble agents like propranolol and metoprolol are well absorbed orally, and undergo rapid hepatic metabolism, with important presystemic clearance and a short plasma half-life. Water-soluble drugs like sotalol, atenolol, and nadolol are less well absorbed, and are eliminated more slowly by renal excretion. Clinical assessment of beta-adrenoceptor antagonism is more valuable than plasma concentration determinations in evaluating the adequacy of the dose of a particular beta-adrenoceptor antagonist.(ABSTRACT TRUNCATED AT 400 WORDS)

The pharmacokinetics and pharmacodynamics of lignocaine and MEGX in healthy subjects

Lignocaine clearance declines during continuous intravenous infusion in man and in vitro studies suggest that this may partly be due to inhibition by MEGX, a metabolite of lignocaine. MEGX is pharmacologically active in animals, but this is not yet proven in man. This study examined the pharmacokinetics and pharmacodynamics of lignocaine and MEGX in eight healthy male volunteers given lignocaine HCl 120 mg, MEGX HCl 120 mg, lignocaine HCl 120 mg + MEGX HCl 120 mg, and placebo, administered according to a randomized double-blind protocol. One-, two-, or three-compartment models were fitted to drug and metabolite blood concentration-time profiles and clearance, volume (Vss), and half-life values were calculated and compared by paired t-test. Systolic time intervals and QT interval were recorded and compared by repeated measures ANOVA. When administered in combination with MEGX, lignocaine clearance was significantly reduced from 58 +/- 18 to 48 +/- 13 L hr-1 (p less than 0.02). The Vss was unchanged and there was a trend toward an increase in terminal half-life. Lignocaine, MEGX, and the combination significantly reduced QT interval up to 30 min after injection and this was maintained to 2 hr with the lignocaine and the combination. Transient side effects were experienced with all active treatments, but were most pronounced with the combination. Thus, lignocaine clearance was inhibited by MEGX, which was pharmacologically active in man.

Pharmacokinetics and toxicity of high-dose human alpha 1-acid glycoprotein infusion in the rat

The pharmacokinetics of high-dose human alpha 1-acid glycoprotein (AAG) was studied in rats to determine the feasibility of using AAG to alter the tissue distribution of basic drugs. alpha 1-Acid glycoprotein (2.2 g/kg) was administered iv to six male Holtzman rats over a period of 30 min, and serum AAG concentrations were measured by a specific radial immunodiffusion assay. The AAG concentrations were computer fit to a biexponential equation to generate pharmacokinetic constants for an open two-compartment model. The peak serum AAG concentration was 1830 +/- 180 mg/dL at the end of infusion; greater than 20 times the normal value for rats. The central volume of distribution and steady state volume of distribution were 0.09 +/- .02 and 0.15 +/- 0.02 L/kg, respectively. Total body clearance of AAG was 0.065 +/- 0.005 L/kg/h, and the terminal elimination half-life was 19.3 +/- 1.5 h. The AAG administration was tolerated without adverse effect and did not alter systolic blood pressure, the electrocardiogram, creatinine clearance, weight gain, or survival. The results of the histologic examination of various tissues by light microscopy at 30 d post AAG treatment were normal. These data demonstrate that high doses of human AAG can be safely administered to rats and that they produce supraphysiologic serum AAG concentrations.

The plasma protein binding of basic drugs

The plasma protein binding of basic drugs appears to vary more than was at first assumed and is related to the marked intra-and interindividual differences in one of the chief binding proteins, AAG. Changes in AAG concentrations will result in alterations in the distribution and metabolism of basic drugs which will complicate the interpretation of the relationship between total drug concentration and drug efficacy or toxicity. For some drugs, e.g. lignocaine, direct measurement of free concentrations may improve their clinical use but rapid and reliable techniques are as yet not readily available.

Protein binding of propisomide

This paper describes the protein binding of propisomide to human serum and isolated proteins using equilibrium dialysis. The drug is exclusively bound to alpha1-acid glycoprotein with high affinity. The binding is saturable even at low concentrations of the drug. Thus, the fraction unbound varied from 0.05 to 0.60 with decreasing serum concentration. The major metabolite of the drug or other drugs with affinity for alpha1-acid glycoprotein can displace propisomide from its binding site only when present in serum at high levels. Two ultrafiltration techniques are compared to equilibrium dialysis for the determination of serum protein binding of propisomide. Ultrafiltration does not give reliable results. Equilibrium dialysis is retained as an accurate method for the determination of the fraction unbound of propisomide.

The acute changes in serum binding of disopyramide and flecainide after myocardial infarction

In the serum basic drugs are principally bound to alpha1-acid glycoprotein (AAG). Following acute myocardial infarction it has been shown that the levels of AAG rise. The serum levels of total protein, albumin, AAG and the protein binding of 2 antiarrhythmic drugs which are bases, disopyramide and flecainide, was measured in vitro with blood samples from eleven patients taken over the first 5 days following myocardial infarction. Mean AAG levels significantly increased from 1.04 g/l on Day 1 to 1.80 g/l on Day 5. The binding of disopyramide, which is highly bound, rose from 80% to 87%, representing a 35% decrease in free drug concentration. In contrast the binding of flecainide fell from 61% to 53%, a 20% increase in free drug concentration. These data suggest that although the binding of strongly bound drugs responds appropriately to increases in binding protein after acute myocardial infarction, poorly bound drugs are displaced from binding sites possibly by endogenous substances. Since the pharmacological effects of a drug are related to its free (unbound) concentration, the changes in the proportions of free to bound drug after myocardial infarction may have important clinical implications.

The protein binding of timegadine determined by equilibrium dialysis

The protein binding of timegadine to albumin, serum, plasma and plasma enriched with the acute phase reactants alpha 1-acid glycoprotein, alpha 1-anti-trypsin and C-reactive protein was determined by equilibrium dialysis. The effects of other analgesic and anti-inflammatories (indomethacin, ketoprofen, paracetamol and sodium salicylate) and other basic drugs (disopyramide, lignocaine, propranolol and quinidine) on the binding of timegadine were also determined. Timegadine binding was concentration-dependent up to 0.5 micrograms/ml, but independent above this level up to 10.0 micrograms/ml, the mean and standard error being 93.8 +/- 0.5%. Albumin accounted for only 32.4% of timegadine bound to plasma. Plasma enrichment with the acute phase reactants led to significant increases in timegadine binding. Simultaneous dialysis with other drugs caused significant decreases in timegadine binding.

Pharmacokinetic and pharmacodynamic considerations in drug therapy of cardiac emergencies

In the drug therapy of cardiac emergencies, it is necessary to rapidly achieve therapeutic drug concentrations and adjust drug dose as the patient's clinical status changes. Cardiac dysfunction is often present and may alter drug pharmacokinetics. Circulatory failure causes sympathetically mediated vasoconstriction in most tissues, with relative sparing of the brain and heart due to autoregulation. Blood flow to vasoconstricted tissues is reduced, and the available cardiac output is redistributed so that the heart and brain receive a greater fraction. Drug distribution to tissues is therefore slowed, and the initial concentration of drug in blood is higher when circulatory failure is present than when it is absent. This higher blood concentration is reflected by higher concentrations of drug in the brain and heart, which are relatively well perfused. Initial doses of many drugs need to be reduced in patients with circulatory failure to prevent cardiac or central nervous system toxicity. Cardiac output is markedly diminished during cardiopulmonary resuscitation (CPR), but blood flow distribution is qualitatively similar to that of circulatory failure with spontaneous circulation. Pneumatic trousers increase lower extremity vascular resistance and may produce a similar redistribution of blood flow. Drug distribution during the use of CPR or pneumatic trousers should be similar to that of circulatory failure with spontaneous circulation, but few data are available to guide drug dosing during the use of these interventions. Animal data suggest that the central volume of distribution of some drugs during CPR may be as small as one-tenth of normal. Drug metabolism in circulatory failure may be impaired by reduced hepatic blood flow resulting in decreased clearance of highly extracted drugs, or by hepatocellular dysfunction resulting in decreased clearance of poorly extracted drugs. Drug excretion may be impaired by reduced renal blood flow resulting in decreased filtration or secretion and increased reabsorption. The maintenance dose of many drugs must therefore be reduced in the presence of circulatory failure. Intravenous drug administration is preferred in patients with circulatory failure. The central intravenous route is often convenient but must be used cautiously when administering potentially cardiotoxic drugs. Intratracheal administration appears to be a promising alternative for some drugs, such as adrenaline (epinephrine). Intracardiac injections are hazardous and offer no demonstrated advantage over other routes.(ABSTRACT TRUNCATED AT 400 WORDS)

Antiarrhythmic therapy: clinical pharmacology update

Currently available antiarrhythmic agents are limited by side effects and the potential for increasing arrhythmias. In addition, drug interactions, altered disposition of drug as a result of changes in protein binding or concomitant disease processes, active metabolites, and poorly defined therapeutic ranges with great interpatient variability are some of the factors which complicate therapy. An awareness of the possible contribution of these factors in the use of antiarrhythmics is invaluable in both the choice of agent and the establishment of an optimum benefit-to-risk ratio for the patient.

Rapid prediction of individual dosage requirements for lignocaine

The mean and standard deviation of lignocaine (lidocaine) pharmacokinetic parameters in a patient population were determined on the basis of 327 serum concentration measurements obtained in 42 patients treated for ventricular arrhythmias. The application of a Bayesian forecasting method, which uses the estimates of the population parameters and 1 or 2 serum concentration measurements as feedback information, was tested retrospectively in 17 of the 42 patients (group I, 32 levels), and prospectively in 10 additional patients (group II, 20 levels). With 1 individual feedback concentration, sampled 2 to 4 hours after the start of lignocaine infusion, serum concentrations at 12 and 24 hours could be accurately predicted. The prediction error (measured minus predicted concentration) ranged between -1.2 and +1.6 (mean -0.03) mg/L in group I, and from -0.7 to +1.5 mg/L (mean +0.13) mg/L in group II; the correlation coefficient of measured and predicted levels were 0.92 and 0.86, respectively. In contrast, a prediction of lignocaine concentrations in these patients using only population parameters without feedback was poor: range of the prediction error = -3.1 to +3.0 mg/L (mean = +0.001 mg/L, r = 0.63, groups I and II, n = 52). The results demonstrate that with the Bayesian forecasting technique, accurate assessment of individual dosage requirements can be obtained within a few hours after starting lignocaine therapy.

Influence of smoking on serum protein composition and the protein binding of drugs

The influence of smoking an alpha 1-acid glycoprotein (alpha 1-AGP) and serum albumin concentrations and the protein binding of phenytoin and propranolol in healthy volunteers was investigated. alpha 1-AGP concentrations were found to be statistically different (P less than 0.05) in the smokers (mean = 84.3 mg dl-1) versus non-smokers (mean = 62.8 mg dl-1). There was a trend for lower serum albumin concentrations and lower fraction unbound of propranolol in the smokers. Smoking did not affect the protein binding of phenytoin.

Effects of beta-adrenoceptor antagonists on the pharmacokinetics of lignocaine

In theory, beta-adrenoceptor antagonists could lower the clearance of free lignocaine in three ways (a) by decreasing hepatic blood flow, (b) by competing for plasma binding sites or (c) by inhibiting the enzymes responsible for metabolising lignocaine. The first mechanism has been demonstrated for propranolol and is probably common to all agents lacking intrinsic sympathomimetic activity. The second mechanism is discounted by data showing that propranolol, one of the more highly bound beta-adrenoceptor antagonists, does not alter the free fraction of lignocaine in plasma. In vitro studies support the third mechanism for the more lipid-soluble beta-adrenoceptor antagonists, as does the fact that observed decreases in the clearance of lignocaine in vivo are generally greater than the anticipated maximum lowering of hepatic blood flow.

alpha 1-Acid glycoprotein and plasma lidocaine binding

The relationship between the degree of plasma binding of lidocaine (lignocaine) and the concentration of the acute phase reactant, alpha 1-acid glycoprotein (AAG), is reviewed. Studies in normal subjects and patients with myocardial infarction, renal disease, hepatic failure and receiving antiepileptic drug therapy have all shown a remarkably good relationship between AAG concentration and the binding ratio for lidocaine. In situations where AAG is altered, particularly myocardial infarction, the usual therapeutic range for total plasma lidocaine concentrations may not apply and must be interpreted appropriately. This provides the strongest rationale for monitoring free rather than total drug concentration as an aid in lidocaine therapy.

Protein binding displacement interactions and their clinical importance

The binding of drugs to proteins is an important pharmacokinetic parameter. Many methods are available for the study of drug protein binding phenomena and there are also many ways to interpret the binding data. Although much emphasis has been placed on the binding of drugs in the plasma, binding also takes place in the tissues. Displacement interactions involving plasma or tissue binding sites have been implicated as the causative mechanisms in many drug interactions. However, the importance of plasma binding displacement as a mechanism of drug interactions. However, the importance of plasma binding displacement as a mechanism of drug interaction has been overestimated and overstated, being based largely on in vitro data. Because displaced drug can normally distribute out of the plasma compartment, increases of free drug concentrations are usually transient and therefore will not give rise to changed pharmacological effects in the patient. Those clinically important drug interactions formerly considered to be caused via displacement from plasma binding sites usually have another interaction mechanism involved; commonly decreased metabolism or renal elimination also takes place. Plasma binding displacement interactions, however, do become important clinically in certain specific situations, namely, when the displacing drug is administered quickly to the patient by the intravenous route, during therapeutic drug monitoring, and in certain drug disposition studies which involve the use of a heparin lock for blood sampling. Tissue binding displacement interactions have a greater potential to cause adverse effects in the patient as in this case drug will be forced from extravascular sites back into the plasma. The resulting increased drug plasma levels will lead to enhanced pharmacological effects and, possibly, frank toxicity. Displacement of drugs from binding sites simultaneously in both the plasma and in the tissues will combine the effects seen after displacement from the separate areas. Due to decreased binding in both areas, the free drug concentration in the plasma will increase leading to overactivity of the displaced drug.