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Pharmacokinetics, sometimes described as what the body does to a drug, refers to the movement of drug into, through, and out of the body—the time course of its absorption, bioavailability, distribution, metabolism, and excretion. Pharmacodynamics (see Pharmacodynamics), described as what a drug does to the body, involves receptor binding, postreceptor effects, and chemical interactions. Drug pharmacokinetics determines the onset, duration, and intensity of a drug's effect. Formulas relating these processes summarize the pharmacokinetic behavior of most drugs (see Table 1: Pharmacokinetics: Formulas Defining Basic Pharmacokinetic Parameters).
Table 1
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Formulas Defining Basic
Pharmacokinetic
Parameters
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Category
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Parameter
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Formula
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Absorption
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Absorption rate constant
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Rate of drug absorption ÷ Amount of drug remaining to be absorbed
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Bioavailability
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Amount of drug absorbed ÷ Drug dose
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Distribution
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Apparent volume of distribution
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Amount of drug in body ÷ Plasma drug concentration
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Unbound fraction
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Plasma concentration of unbound drug ÷ Plasma drug concentration
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Elimination
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Rate of elimination
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Renal excretion + Extrarenal (usually metabolic) elimination
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Clearance
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Rate of drug elimination ÷ Plasma drug concentration
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Renal clearance
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Rate of renal excretion of drug ÷ Plasma drug concentration
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Metabolic clearance
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Rate of drug metabolism ÷ Plasma drug concentration
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Fraction excreted unchanged
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Rate of renal excretion of drug ÷ Rate of drug elimination
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Elimination rate constant
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Rate of drug elimination ÷ Amount of drug in body
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Clearance ÷ Volume of distribution
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Biologic half-life
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0.693 ÷ Elimination rate constant
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Pharmacokinetics of a drug depends on patient-related factors as well as on the drug's chemical properties. Some patient-related factors (eg, genetic makeup, sex, age) can be used to predict pharmacologic response of populations. For example, the half-life of some drugs, especially those that require both metabolism and excretion, may be remarkably long in the elderly (see Fig. 1: Pharmacokinetics: Comparison of pharmacokinetic outcomes for diazepam in a younger man (A) and an older man (B).). In fact, physiologic changes with aging affect many aspects of pharmacokinetics (see Drug Therapy in the Elderly: Pharmacokinetics in the Elderly). Other factors are related to individual physiology. The effects of some individual factors (eg, renal failure, obesity, hepatic failure, dehydration) can be reasonably predicted, but other factors are idiosyncratic and thus have unpredictable effects. Because of individual differences, drug administration must be based on each patient's needs—traditionally, by empirically adjusting dosage until the therapeutic objective is met. This approach is frequently inadequate because it can delay optimal response or result in adverse effects. Knowledge of pharmacokinetic principles helps prescribers adjust dosage more accurately and rapidly.
Fig. 1
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Comparison of pharmacokinetic outcomes for diazepam in a younger man (A) and an older man (B).
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Diazepam is metabolized in the liver to desmethyldiazepam through P-450 enzymes. Desmethyldiazepam is an active sedative, which is excreted by the kidneys. 0 = time of dosing. (Adapted from Greenblatt DJ, Allen MD, Harmatz JS, Shader RI: Diazepam disposition determinants. Clinical Pharmacology and Therapeutics 27:301–312, 1980.)
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Last full review/revision November 2007 by Karen Birckelbaw Kopacek, RPh
Content last modified November 2007
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