General pharmacological properties of Sho-seiryu-to (TJ-19) extracts.

The general pharmacological properties of TJ-19 extracts were orally investigated in various experimental animals. TJ-19 extracts showed no effect on general behavior and on central nervous system such as spontaneous locomotor activity, proconvulsant and anti-convulsant responses, analgesic activity, body temperature and hexobarbital sleeping time at all doses of 0.5, 1 and 2 g/kg in mice. Further, TJ-19 extracts showed no effect on contractile responses of isolated guinea pig ileum induced by acetylcholine, histamine and BaCl2 at concentrations of 10(-6), 10(-5), and 10(-4) g/ml. TJ-19 extracts, however, increased the respiratory rate, heart rate, blood pressure, systolic pressure, diastolic pressure, and decreased the blood flow in dogs at all doses of 0.5, 1 and 2 g/kg via duodenal administration. Further, TJ-19 extracts decreased the interval of PR and QT of EKG parameters in dogs at doses of 1 and 2 g/kg. TJ-19 extracts increased the intestinal transport of charcoal meal in rats at doses of 1 and 2 g/kg. TJ-19 increased the urinary Na+ excretion at all doses of 0.5, 1, and 2 g/kg, and increased the urinary K+ and Cl- excretion at 1 and 2 g/kg, although it showed no effect on urine volume output in rats. These data suggest that TJ-19 stimulates the sympathetic nervous system function at a pharmacological dose of under 0.5 g/kg, and has possibility to increase the intestinal peristalsis and urinary electrolyte excretion at higher doses.

Simultaneous analysis of inulin and 15N2-urea kinetics in humans.

To elucidate the physiologic basis of multicompartmental systems used to model drug distribution, we studied inulin and 15N2-urea kinetics after simultaneous intravenous injection in five normal subjects. Distribution of both compounds was characterized by three-compartment models in which the central compartment corresponded to intravascular space. The mean distribution volumes of 0.164 +/- 0.009 L/kg (+/- SD) for inulin and of 0.670 +/- 0.143 L/kg for urea were similar to expected values for extracellular space and total body water, respectively. Distribution from intravascular space was kinetically heterogeneous, presumably reflecting differences in vascular beds supplied by either fenestrated and discontinuous capillaries or capillaries with a continuous basement membrane. Intercompartmental clearances of inulin and urea and the ratio of their free water diffusion coefficients were used to estimate blood flows and permeability coefficient-surface area products for the peripheral compartments. The sum of compartmental blood flows averaged 5.39 +/- 0.49 L/min and was similar to dual-beam Doppler measurements of cardiac output (5.47 +/- 0.40 L/min).

Physiological basis of multicompartmental models of drug distribution.

Although most pharmacokinetic studies are conducted in normal subjects, their clinical utility depends on the reliability with which the results can be extrapolated to patients. This reliability can be improved by increased understanding of how drug absorption and disposition mechanisms are affected by physiological changes or by disease. In recent years, important insight has been gained regarding the effects of altered renal function on drug elimination by the kidneys. There has also been considerable progress in defining the interaction of hemodynamic and metabolic factors that affect the hepatic elimination of drugs. Although comparatively little progress has been made in elucidating the underlying basis of changes in the rate and extent of drug distribution, Arthur Atkinson and colleagues analyse methods of compartmental pharmacokinetic analysis that may provide physiological insight into the factors affecting drug distribution.

A kinetic model of benzoylecgonine disposition after cocaine administration in humans.

Cocaine (C) and benzoylecgonine (BZ) plasma levels and urinary excretion rate data from a series of intravenous cocaine studies were used to develop a kinetic model for C and BZ, with the main objective of characterizing BZ disposition. Kinetic analyses were made with the CONSAM 30 computer program. Under assumptions of the model, calculated parameters indicated a BZ distribution volume of 50 L, a half-time for BZ formation of 1.9 h and a BZ excretion half-time of 4.7 h. The model may eventually provide a basis for interpretation of analytical data on isolated samples of plasma or urine.

Characterization of theophylline binding to serum proteins in pregnant and nonpregnant women.

Sera from 10 subjects in the third trimester of pregnancy and from 10 nonpregnant women were studied to elucidate the mechanism underlying decreased theophylline protein binding during pregnancy. Consistent with the physiologic hypoalbuminemia of pregnancy, serum albumin concentrations averaged only 3.2 +/- 0.3 gm/dl (+/- SD) in pregnant subjects, compared with 4.4 +/- 0.3 gm/dl in control subjects (p less than 1 x 10(-6], and this was the main cause of decreased theophylline binding. Saturation binding studies indicated a single class of theophylline binding sites. Theophylline binding capacity (N) was greater in pregnant (N = 4.3 +/- 1.0) than in nonpregnant (N = 3.3 +/- 0.4) subjects, but binding affinity (ka) averaged only 227 +/- 69 (mol/L)-1 in pregnant subjects, compared with 303 +/- 44 (mol/L)-1 in control subjects (F2,17 = 4.26; p = 0.032). At a theophylline plasma concentration of 10 micrograms/ml, the combined effects of hypoalbuminemia and lowered ka would reduce theophylline binding to 31% +/- 3% in pregnant women, compared to 39% +/- 3% in nonpregnant control subjects (p less than 1 x 10(-5]. Nonesterified fatty acid concentrations were similar in both subject groups and did not contribute to the pregnancy-associated decrease in theophylline binding.

Splanchnic tissues are a major part of the rapid distribution spaces of inulin, urea and theophylline.

Distribution of kinetics of inulin, [14C]urea and theophylline were studied in five anesthetized dogs after splenectomy and gastrointestinal resection. Distribution was modeled with three-compartment mammillary systems in which the central compartment corresponds to intravascular space and the two peripheral compartments have different rates of transcapillary exchange. Compared with results in intact dogs, the surgical procedure removed between 41 and 55% of the rapidly equilibrating tissues and reduced the permeability coefficient-surface area products for the rapidly equilibrating inulin and urea compartments proportionately. This is consistent with the concept that splanchnic organs equilibrate rapidly with inulin and urea because they are supplied by fenestrated and discontinuous capillaries that are prominent in the splanchnic vascular bed. However, splanchnic organs probably do not contain all rapidly equilibrating tissues, and somatic tissues may contribute as much as 36 and 22%, respectively, of the rapidly equilibrating inulin and urea compartments. Cardiac output averaged 2.87 +/- 0.86 liters/min and was similar to the sum of compartmental blood flows estimated from the intercompartmental clearances of urea and inulin (2.74 +/- 0.96 liters/min) and to the sum of theophylline intercompartmental clearances (2.62 +/- 0.74 liters/min). Theophylline intercompartmental clearance to each peripheral compartment was similar to estimated compartmental blood flow.

Pharmacokinetics of N-acetylprocainamide in patients profiled with a stable isotope method.

N-Acetylprocainamide (NAPA) absorption and disposition were profiled in five patients with ventricular arrhythmias by the simultaneous intravenous administration of NAPA-13C and oral administration of a 500 mg NAPA hydrochloride tablet. NAPA distribution was modeled with a three compartment mammillary system. The central compartment volume of 14.1 +/- 2.6 L (mean +/- SD) was similar to expected intravascular space, corrected for NAPA partitioning between erythrocytes and plasma. Other compartment volumes, intercompartmental and nonrenal clearances, and the steady-state distribution volume of 1.45 +/- 0.09 L/kg were similar to normal subject values. The least-squares estimate of 1.67 for the NAPA renal clearance/creatinine clearance ratio was similar to the value of 1.68 previously reported for functionally anephric patients and showed the expected age-associated decrease. The oral NAPA dose was 78.0% +/- 11.7% absorbed and interindividual variation in NAPA absorption was correlated with fast intercompartmental clearance (r = 0.89, p = 0.045). Because fast intercompartmental clearance partly reflects splanchnic blood flow, hemodynamic changes may affect NAPA bioavailability, as has been found for procainamide.

Urinary excretion of cocaine, benzoylecgonine, and ecgonine methyl ester in humans.

The excretion kinetics of cocaine (C) and its two major metabolites, benzoylecgonine (BZ) and ecgonine methyl ester (EME), were determined by collecting all urine for 30 h from 5 cocaine users (subjects C, D, E, F, and G) given bolus doses followed by exponential cocaine infusions that delivered doses of 253 (subject C), 444 (subjects D, E, and F), and 700 mg (subject G). Plasma cocaine, urine cocaine, BZ, and EME were measured by gas chromatography, with a nitrogen detector. Elimination half-times for EME and BZ, estimated from semilog plots of excretion rates vs. time, averaged 3.1 and 4.5 h respectively, in agreement with our previous report. Urinary recovery in D, E, and F was 27-41% of the dose, with 14-17% as BZ, 12-21% as EME, and 2% as cocaine. Subject C excreted very little EME--5-6-fold less than the mean for the other subjects and amounting to only 3% of the dose. Cocaine disposition in subject G, who received the largest dose and attained plasma levels of 3000 ng/mL, showed some characteristics of a nonlinear process.

Acute tolerance to cocaine in humans.

There is controversy as to whether acute tolerance develops to the principal effects of cocaine in humans. The studies described here demonstrate the phenomenon of acute tolerance to cocaine chronotropic and subjective effects and the rate and extent of tolerance development. Stable plasma cocaine concentrations were produced and then maintained in volunteer cocaine users by administering an intravenous cocaine injection followed by a cocaine infusion designed to compensate for the plasma clearance of cocaine. The euphoric effect (high) intensified to a peak at about 1 hour and then declined toward baseline at 4 hours despite the presence of constant plasma cocaine levels. The chronotropic effect reached a peak within 10 minutes and then declined, with a half-life of 31 +/- 13 (mean +/- SD) minutes toward a plateau at 33% +/- 21% of its peak intensity. Tolerance development was quantified as an exponential process, with a rate constant (tolerance factor) accounting for the progressive alteration of the cocaine concentration-effect relationship.

Comparison of the pharmacokinetic and pharmacodynamic properties of procainamide and N-acetylprocainamide.

Although procainamide (PA) has been widely used to treat patients with both ventricular and supraventricular arrhythmias since 1951, more than twenty years elapsed before N-acetylprocainamide (NAPA) was identified as a major PA metabolite and shown in PA-treated patients to have plasma concentrations generally equaling or being 2 to 3 times greater than those of the parent drug. Numerous investigations have been conducted since then to characterize the pharmacokinetics and pharmacodynamics of NAPA and to compare these properties with those of PA. Salient differences have been that the elimination half-life of NAPA is 2.5 times that of PA, even when renal function is normal; that NAPA has a spectrum of electrophysiologic action that differs from PA in that NAPA only prolongs action potential duration; and that NAPA is less likely than PA to cause a syndrome resembling systemic lupus erythematosus. Although these properties have provided an impetus for the development of NAPA as an antiarrhythmic drug in its own right, emphasis is placed in this review on the implications of these findings for individualizing PA therapy.

Assay of stable isotope labelled urea in biological fluids by selected ion monitoring.

A selected ion-monitoring method, incorporating an internal standard, was developed to allow the direct and simultaneous measurement of stable isotope-labelled urea and unlabelled urea concentrations in biological specimens. After cyclization of urea with malonaldehyde bis(dimethylacetal) to form 2-hydroxypyrimidine, the volatile heptafluorobutyryl derivative was made in a two-step process utilizing a trimethylsilyl intermediate. The internal standard, 4-methyl-2-hydroxypyrimidine, was found to be stable under the cyclization conditions. The structures of the internal standard and urea derivatives were confirmed by electron impact and chemical ionization mass spectrometry. This method was applied to the measurement of [15N2]urea concentrations in dog plasma.

Theophylline distribution kinetics analyzed by reference to simultaneously injected urea and inulin.

Theophylline distribution kinetics were studied after i.v. injection in five anesthetized dogs. [14C]Urea and inulin were injected simultaneously as reference compounds to measure body fluid spaces and to calculate compartmental blood flows and permeability coefficient-surface area products for transcapillary exchange. The distribution of all three compounds was modeled with three-compartment systems in which the central compartment corresponds to intravascular space. The total volume of theophylline distribution averaged 0.72 +/- 0.09 liters/kg (+/- S.D.), indicating net tissue binding as reflected in a tissue/intracellular water partition coefficient of 1.17 +/- 0.10. Cardiac output measurements averaged 4.78 +/- 0.95 liters/min and were similar to the sum of compartmental blood flows estimated from the intercompartmental clearances of urea and inulin (4.62 +/- 1.10 liters/min) and to the sum of theophylline intercompartmental clearances (5.10 +/- 1.29 liters/min). Theophylline intercompartmental clearance to each peripheral compartment was faster than expected from its free-water diffusion coefficient and was similar to estimated compartmental blood flow. It is possible that theophylline transcapillary exchange is carrier mediated and that its rapidity contributes to the frequency of adverse reactions after i.v. administration of this drug.

Effect kinetics of N-acetylprocainamide-induced QT interval prolongation.

We attempted to correlate clinical response with the effects of N-acetylprocainamide (NAPA) on the QT interval in five patients with stable chronic ventricular arrhythmias. A 15 mg/kg dose of NAPA was administered and a pharmacokinetic-pharmacodynamic model was used to relate plasma NAPA concentrations to changes in corrected QT interval (QTc). NAPA volume of distribution, elimination clearance, and elimination half-life averaged 1.37 +/- 0.19 L/kg, 174 +/- 63 ml/min, and 8.2 +/- 1.4 hours, respectively (mean +/- SD), and NAPA renal clearance averaged 1.9 +/- 0.6 times creatinine clearance. QTc prolongation was characterized by a linear-effect model in the first four patients and averaged 2.4 msec for every microgram per milliliter NAPA in a hypothetic biophase. QTc prolongation in patient 5 was exaggerated and was analyzed with an Emax model. Nonetheless, NAPA did not control this patient's arrhythmia. Conversely, patient 1 subsequently developed torsade de pointes even though QTc prolongation in this patient was comparable to that in patients 2 through 4, who responded satisfactorily to NAPA. We conclude that QT interval changes during initial NAPA administration do not reliably predict subsequent clinical response.

Pharmacokinetics of N-acetylprocainamide.

Shortly after Dreyfus and his colleagues demonstrated that procainamide was metabolized by acetylation to N-acetylprocainamide (NAPA), Drayer, Reidenberg and Sevy reported that NAPA had antiarrhythmic activity in an animal model. We confirmed these findings and found that plasma levels of NAPA were high enough to warrant consideration in managing patients requiring procainamide therapy. However, the actual impetus for developing NAPA as an antiarrhythmic drug in its own right was provided by the initial studies of NAPA pharmacokinetics in normal subjects. In these studies, we showed that NAPA has an elimination-phase half-life that is more than twice as long as procainamide and suggested that patient compliance and arrhythmia suppression might be improved if NAPA were used to circumvent the inconvenience of the frequent dosing schedule that has been recommended for procainamide. From the standpoint of managing individual patients with NAPA, the pharmacokinetics of this drug continue to provide the scientific basis for designing dose regimens that will have maximal antiarrhythmic efficacy and minimal toxicity. This review summarizes the salient features of NAPA pharmacokinetics and outlines an approach for individualizing therapy with this drug.

Theophylline pharmacokinetics in pregnancy.

Theophylline pharmacokinetics were studied serially in five women during and after pregnancy. Theophylline protein binding was reduced to 11.1% +/- 4.7% (P less than 0.01) and 13.0% +/- 5.9% (P less than 0.01) during the second and third trimesters of pregnancy, respectively, compared with 28.1% +/- 2.8% when the patients were more than 6 months postpartum. Similar comparisons indicate that theophylline distribution volume and elimination t1/2 were increased from 30.7 +/- 4.4 L and 262 +/- 57 minutes to 36.8 +/- 4.2 L (P less than 0.05) and 389 +/- 73 minutes (P less than 0.01) in the third trimester of pregnancy. In the second and third trimesters, intrinsic nonrenal clearance was reduced to 0.82 +/- 0.25 ml/min X kg (P less than 0.05) and 0.67 +/- 0.18 ml/min X kg (P less than 0.01) compared with a remote postpartum value of 1.25 +/- 0.37 ml/min X kg. However, these reductions were offset by increases in theophylline intrinsic renal clearance so that apparent reductions in the overall unbound clearance of this drug did not reach statistical significance either during pregnancy or in the early postpartum period.

Mothball composition: three simple tests for distinguishing paradichlorobenzene from naphthalene.

We describe three analytical procedures that can be used to distinguish naphthalene from the less toxic mothball component paradichlorobenzene. An initial presumptive identification can be made by noting the characteristic aroma of the two substances. This can be followed by one of the three analytical tests, each of which is simple to perform, gives an answer in seconds to minutes, and is definitive enough to eliminate the need for costly additional testing at an analytical reference laboratory. These tests have as additional advantages that the endpoints are dramatic and the reagents are commonly available.

Kinetics of cocaine distribution, elimination, and chronotropic effects.

The pharmacokinetics of cocaine were studied in five subjects with histories of drug abuse who were otherwise healthy. A two-compartment system was used to model the distribution kinetics of the drug. The steady-state volume of distribution averaged 131.8 L or 1.96 L/kg, elimination clearance was 2.10 L/min, and the t 1/2 was 48 minutes. Cocaine concentrations in a hypothetic biophase were estimated to correlate the chronotropic effects of this drug with its pharmacokinetics. The experimentally determined kinetic parameters indicate that the peak chronotropic effect would occur 7.3 minutes after intravenous bolus injection of cocaine, and that biophase cocaine concentrations would initially accelerate the heart rate by 0.3 bpm for each 1 ng/ml. The kinetic analysis also demonstrated that the chronotropic effects of cocaine decline more rapidly than either plasma levels or biophase concentrations. This progressive attenuation in intensity of the chronotropic effect of a given biophase cocaine concentration could be modeled as a first-order process and is compatible with either the intervention of homeostatic reflex mechanisms or the phenomenon of acute tolerance.