Therapeutic plasma concentrations

Determination of desipramine plasma concentrations is not routinely recommended but may be useful in identifying toxicity drug interactions, or noncompliance (adjustments in dosage should be made according to clinical response, not plasma concentrations) therapeutic level is 50-200 ng/ml... 

Once the steady-state concentration is known, the rate of dmg clearance determines how frequendy the dmg must be adininistered. Because most dmg elimination systems do not achieve saturation under therapeutic dosing regimens, clearance is independent of plasma concentration of the dmg. This first-order elimination of many dmgs means that a constant fraction of dmg is eliminated per unit time. In the simplest case, clearance can be deterrnined by the dose and the area under the curve (AUC) describing dmg concentration as a function of total time ... 

Procainamide may be adininistered by iv, intramuscular (im), or po routes. After po dosing, 75—90% of the dmg is absorbed from the GI tract. About 25% of the amount absorbed undergoes first-pass metaboHsm in the fiver. The primary metabolite is A/-acetylprocainamide (NAPA) which has almost the same antiarrhythmic activity as procainamide. This is significant because the plasma concentration of NAPA relative to that of procainamide is 0.5—2.5. In terms of dmg metabolism there are two groups of patients those that rapidly acetylate and those that slowly acetylate procainamide. About 15—20% of the dmg is bound to plasma proteins. Peak plasma concentrations are achieved in 60—90 min. Therapeutic plasma concentrations are 4—10 lg/mL. Plasma half-lives of procainamide and NAPA, which are excreted mainly by the kidneys, are 2.5—4.5 and 6 h, respectively. About 50—60% is excreted as unchanged procainamide (1,2). 

Disopyr mide. Disopyramide phosphate, a phenylacetamide analogue, is a racemic mixture. The dmg can be adininistered po or iv and is useful in the treatment of ventricular and supraventricular arrhythmias (1,2). After po administration, absorption is rapid and nearly complete (83%). Binding to plasma protein is concentration-dependent (35—95%), but at therapeutic concentrations of 2—4 lg/mL, about 50% is protein-bound. Peak plasma concentrations are achieved in 0.5—3 h. The dmg is metabolized in the fiver to a mono-AJ-dealkylated product that has antiarrhythmic activity. The elimination half-life of the dmg is 4—10 h. About 80% of the dose is excreted by the kidneys, 50% is unchanged and 50% as metabolites 15% is excreted into the bile (1,2). 

Time to peak plasma concentration depends on the rate of IV dosing but is usually achieved in 45—90 seconds. Therapeutic plasma concentrations are 1.5—5.0 )J.g/mL, and concentrations above 5 )J.g/mL maybe toxic. The elimination half-life after a bolus iv dose is 8 min the elimination half-life after a 24 h iv infusion is about 100 min. The dmg is eliminated by the kidneys. Ten percent is unchanged and the remainder is in the form of inactive metabolites... 

Phenytoin s absorption is slow and variable yet almost complete absorption eventually occurs after po dosing. More than 90% of the dmg is bound to plasma protein. Peak plasma concentrations are achieved in 1.5—3 h. Therapeutic plasma concentrations are 10—20 lg/mL but using fixed po doses, steady-state levels are achieved in 7—10 days. Phenytoin is metabolized in the fiver to inactive metabolites. The plasma half-life is approximately 22 h. Phenytoin is excreted primarily in the urine as inactive metabolites and <5% as unchanged dmg. It is also eliminated in the feces and in breast milk (1,2). Prolonged po use of phenytoin may result in hirsutism, gingival hyperplasia, and hypersensitivity reactions evidenced by skin rashes, blood dyscrasias, etc... 

Mexifitene is well absorbed from the GI tract and less than 10% undergoes first-pass hepatic metabolism. In plasma, 60—70% of the dmg is protein bound and peak plasma concentrations are achieved in 2—3 h. Therapeutic plasma concentrations are 0.5—2.0 lg/mL. The plasma half-life of mexifitene is 10—12 h in patients having normal renal and hepatic function. Toxic effects are noted at plasma concentrations of 1.5—3.0 lg/mL, although side effects have been noted at therapeutic concentrations. The metabolite, /V-methy1mexi1itene, has some antiarrhythmic activity. About 85% of the dmg is metabolized to inactive metabolites. The kidneys excrete about 10% of the dmg unchanged, the rest as metabolites. Excretion can also occur in the bile and in breast milk (1,2). 

EoUowing po administration moricizine is completely absorbed from the GI tract. The dmg undergoes considerable first-pass hepatic metabolism so that only 30—40% of the dose is bioavailable. Moricizine is extensively (95%) bound to plasma protein, mainly albumin and a -acid glycoprotein. The time to peak plasma concentrations is 0.42—3.90 h. Therapeutic concentrations are 0.06—3.00 ]l/niL. Using radiolabeled moricizine, more than 30 metabolites have been noted but only 12 have been identified. Eight appear in urine. The sulfoxide metabolite is equipotent to the parent compound as an antiarrhythmic. Elimination half-life is 2—6 h for the unchanged dmg and known metabolites, and 84 h for total radioactivity of the labeled dmg (1,2). 

Tocainide is rapidly and well absorbed from the GI tract and undergoes very fitde hepatic first-pass metabolism. Unlike lidocaine which is - 30% bioavailable, tocainide s availability approaches 100% of the administered dose. Eood delays absorption and decreases plasma levels but does not affect bio availability. Less than 10% of the dmg is bound to plasma proteins. Therapeutic plasma concentrations are 3—9 jig/mL. Toxic plasma levels are >10 fig/mL. Peak plasma concentrations are achieved in 0.5—2 h. About 30—40% of tocainide is metabolized in the fiver by deamination and glucuronidation to inactive metabolites. The metabolism is stereoselective and the steady-state plasma concentration of the (3)-(—) enantiomer is about four times that of the (R)-(+) enantiomer. About 50% of the tocainide dose is efirninated by the kidneys unchanged, and the rest is efirninated as metabolites. The elimination half-life of tocainide is about 15 h, and is prolonged in patients with renal disease (1,2,23). 

Encainide is almost completely absorbed from the GI tract. Eood may delay absorption without altering its bioavailabiUty. The dmg is rapidly metabolized in 90% of the patients to two principal metaboUtes, 0-demethylencainide (ODE) and 3-methoxy-O-demethylencainide (MODE), while the other 10% metabolize encainide slowly with Htde or no ODE or MODE formed. Encainide, ODE, and MODE are extensively protein bound 75—80% for encainide and ODE and 92% for MODE. Peak plasma concentrations are achieved in 30—90 min. Therapeutic plasma concentrations are very low the concentrations of ODE and MODE are approximately five times those of encainide. The findings with the metaboUtes are significant because ODE is 2—10 times and MODE, 1—4 times more effective than encainide as antiarrhythmics. The half-Hves for encainide in fast and slow metabolizers is 1—2 h and 6—12 h, respectively. The elimination half-life for ODE is 3—4 h and for MODE 6—12 h in fast metabolizers. Excretion occurs through the Hver and kidneys (1,2). 

Elecainide is weU absorbed and 90% of the po dose is bioavailable. Binding to plasma protein is only 40% and peak plasma concentrations are attained in about 1—6 h. Three to five days may be requited to attain steady-state plasma concentrations when multiple doses are used. Therapeutic plasma concentrations are 0.2—1.0 lg/mL. Elecainide has an elimination half-life of 12—27 h, allowing twice a day dosing. The plasma half-life is increased in patients with renal failure or low cardiac outputs. About 70% of the flecainide in plasma is metabolized by the Hver to two principal metaboUtes. The antiarrhythmic potency of the meta-O-dealkylated metaboUte and the meta-O-dealkylated lactam, relative to that of flecainide is 50 and 10%, respectively. The plasma concentrations of the two metaboUtes relative to that of flecainide are 3—25%. Elecainide is mainly excreted by the kidneys, 30% unchanged, the rest as metaboUtes or conjugates about 5% is excreted in the feces (1,2). 

About 97% of po dose is absorbed from the GI tract. The dmg undergoes extensive first-pass hepatic metaboHsm and only 12% of the po dose is bioavailable. More than 95% is protein bound and peak plasma concentrations are achieved in 2—3 h. Therapeutic plasma concentrations are 0.064—1.044 lg/mL. The dmg is metabolized in the Hver to 5-hyroxypropafenone, which has some antiarrhythmic activity, and to inactive hydroxymethoxy propafenone, glucuronides, and sulfate conjugates. Less than 1% of the po dose is excreted by the kidney unchanged. The elimination half-life is 2—12 h (32). 

Therapeutic plasma concentrations are 0.15—0.50 )J.g/mL. The elimination half-life of lorcainide is about 8 h and that of norlorcainide, 26 h (32). Lorcainide has low cardiovascular toxicity (32). 

Esmolol is iv adrninistered. Maximal P-adrenoceptor blockade occurs in 1 min. Its elimination half-life is about 9 min. EuU recovery from P-adrenoceptor blockade is within 30 min after stopping the infusion. The therapeutic plasma concentrations are 0.4—1.2 lg/mL. It is metabolized by hydrolysis in whole blood by red blood cell esterases resulting in the formation of a primary acid metabohte and free methanol. The metabohte is pharmacologically inactive. The resulting methanol levels are not toxic. Esmolol is 55% bound to plasma protein, the acid metabohte only 10%. Less than 2% of parent dmg and the acid metabohte are excreted by the kidneys. Plasma levels may be elevated and elimination half-hves prolonged in patients with renal disease (41). 

The GI absorption of the dmg after po adrninistration is slow and variable with estimates ranging from 20—55%. Once absorbed, 96% of the dmg is bound to plasma proteins and other tissues on the body. Whereas peak plasma concentrations may be achieved in 3—7 h, the onset of antiarrhythmic action may occur in 2—3 days or more. This may result, in part, from distribution to and concentration of the dmg in adipose tissue, Hver, spleen, and lungs. Therapeutic plasma concentrations are 1—2 p.g/mL, although there appears to be no correlation between plasma concentration and antiarrhythmic activity. The plasma half-life after discontinuation of the dmg varies from 13—103 days. The dmg is metabolized in the Hver and the principal metaboHte is desethylamiodarone. The primary route of elimination is through the bile. Less than 1% of the unchanged dmg is excreted in the urine. The dmg can also be eliminated in breast milk and through the skin (1,2). 

Because bretylium is poody absorbed from the GI tract (- 10%), it is adrninistered iv or im. Very litde dmg is protein bound in plasma. Bretylium is taken up by an active transport mechanism into and concentrated in postganglionic nerve terminals of adrenergicahy innervated organs. Peak plasma concentrations after im injections occur in about 30 min. Therapeutic plasma concentrations are 0.5—1.0 p.g/mL. Bretylium is not metabolized and >90% of the dose is excreted by the kidneys as unchanged dmg. The plasma half-life is 4—17 h (1,2). 

After po dosing, verapamil s absorption is rapid and almost complete (>90%). There is extensive first-pass hepatic metabolism and only 10—35% of the po dose is bioavahable. About 90% of the dmg is bound to plasma proteins. Peak plasma concentrations are achieved in 1—2 h, although effects on AV nodal conduction may be apparent in 30 min (1—2 min after iv adrninistration). Therapeutic plasma concentrations are 0.125—0.400 p.g/mL. Verapamil is metabolized in the liver and 12 metabolites have been identified. The principal metabolite, norverapamil, has about 20% of the antiarrhythmic activity of verapamil (3). The plasma half-life after iv infusion is 2—5 h whereas after repeated po doses it is 4.5—12 h. In patients with liver disease the elimination half-life may be increased to 13 h. Approximately 50% of a po dose is excreted as metabolites in the urine in 24 h and 70% within five days. About 16% is excreted in the feces and about 3—4% is excreted as unchanged dmg (1,2). 

FIGURE 8.23 Kinetic profiles of the plasma concentrations of three different drags taken by the oral route. If absorption is rapid, toxic effects may ensue (red line). If too slow, a therapeutically effective level may not be attained (blue line). 

FIGURE 8.25 Repeated oral administration of drags leads to steady-state plasma concentrations. If elimination is rapid and administration not often enough, then an elevated and therapeutically effective steady-state concentration may not be achieved (green lines). In contrast, if elimination is very slow (or administration too often), then an accumulation of the drag may be observed with no constant steady state (red line). Bine line shows a correct balance between frequency of administration and elimination. 

Intestinal absorption of digoxin is less complete compared to digitoxin. In order to improve absorption, acetylated- and methylated-digoxin derivates were developed. Digitoxin is metabolised in hepatic microsomal enzymes and can be cleared independently from renal function. The therapeutical serum level of digoxin is 0.5-2.0 ng/ml and 10-35 ng/ml of digitoxin. Steady state plateau of therapeutic plasma concentrations is reached after 4-5 half-life-times using standard daily doses [5]. 

PET studies show that at effective therapeutic plasma concentrations most neuroleptics occupy some 80% of brain Dj receptors (in the striatum at least) and this is therefore considered to be a requirement for efficacy (Pilowsky, Costa and Eli 1992 Farde 1996). If that is so then clozapine, which occupies only 20-40% of the Dj receptors at a therapeutic concentration, must have some other action which accounts for its therapeutic effectiveness. 

CYP450 inducer No Therapeutic serum/plasma concentrations Obtain blood level 1-1.5 mEq/L 10-12 hours for adult, postdose acute mania 1A2, 2C9/10, and 3A3/4 4-12 mcg/mL for adult, acute mania 3A3/4 No Unknown... 

For drugs which have a wide range of therapeutically acceptable plasma concentrations, it is reasonable to consider widening bioequivalence criteria [40]. 

Ward et al. [130] studied the pharmacokinetics of (+)- and (—)-primaquine in the isolated perfused rat liver preparation. The perfusate plasma concentrations of primaquine in the isolated, perfused rat liver, declined biexponentially following the addition of either (+)- or (—)-primaquine at doses 0.5-2.5 mg in the perfusate reservoir. There were no differences between pharmacokinetic profiles of the two isomers at the 0.5 mg dose. By contrast, the elimination of (—)-primaquine was greater than (+)-primaquine when either was added in a dose of 2.5 mg also, the clearance of the (—)-isomer was greater, the half-life was shorter, and the area under the plasma concentration curve was shorter. The volume of distribution was similar for the two isomers. These results are relevant to both the therapeutic efficacy and toxicity of primaquine. 

A 68-year-old female has AF, which is treated with an anti arrhythmic agent that blocks Na+ channels. On a recent office visit, she complained of recurrent attacks of feeling faint and of experiencing an episode of loss of consciousness. An EKG showed marked prolongation of the QT interval. Plasma concentration of the drug was in the therapeutic range. 

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