The equation log(concentration) = a + bl V'TTTO + c + d -(T -4) was used to calculate serum level curves from individual data sets of drug serum concentrations, obtained from experiments with orally administered drugs. These curves were subsequently used to calculate peak values, times for onset of peak, area, and other pharmacokinetic parameters that ought to be independent of any preconceived theory about the behavior of the drug in the system. A program is described by which parameters for individual data sets can be calculated and a mean curve with a peak value, time for onset of peak, and area equal to the arithmetic mean of the corresponding values for the participating subjects, is produced. The results of this method are compared to those of the ''one-compartment model with lag time" and shown to be superior in all the test cases. In particular, the proposed method performs well with data from a highly protein-bound drug, for which the one-compartment model fails completely. Data sets of six to eight samples taken over the entire period of detectable serum levels, with 10% analytical error in the results, gave estimates of peak value and area with a coefficient of variation of 6 to 9%, whereas the variation in the estimates for different subjects in a treatment group amounted to 20 to 60%. This shows that the proposed method, although able to cope with a short series of imprecise measurements available in practical work, is still sufficiently sensitive to detect real differences between the individual subjects. This model implies that the following conditions are true. (i) At the moment of application, (T = 0), the whole dose is instantaneously transferred to the sites of absorption. (ii) The absorption then takes place at a rate proportional to the remaining, unabsorbed part of the drug, all of which is gradually absorbed into the blood stream. Diffusion processes through membranes do not influence the absorption process, and drug loss by destruction in the stomach or excretion through the intestines can be ignored. (iii) Either no reversible exchange of drug takes place between serum and the various body organs or the equilibrium concentrations for such exchanges are established at a rate much greater than the absorption and elimination proper. Drug loss from these organs in ways other than through the blood stream is negligible. (iv) If alternative routes of elimination compete, e.g., metabolization and renal excretion, each of these processes must be of the first order, i.e., proceed at a rate proportional to the drug concentration in the serum. (v) If part of the drug is eliminated via the enterohepatic system, reabsorption in the intestines can be ignored.Equation 1 should not be used for a drug that is suspected of violating one or more of the above-mentioned conditions. Many drugs may belong to this category, and many modifications of the basic model have been proposed to counteract the effects of such deviations. The simplest modification is the introduction of a lag time, 4, to account for the ...
