Absolute bioavailability and pharmacokinetics of valsartan, an angiotensin II receptor antagonist, in man

Objective: The pharmacokinetics of orally and intravenously administered valsartan were determined in two studies. In a first pilot study, three i.v. doses of valsartan were given in an ascending manner (5, 10 and 20 mg) to evaluate tolerability and basic pharmacokinetics of the i.v. formulation. In a second study, the absolute bioavailability of 80 mg valsartan from a capsule and a buffered solution was compared with a 20 mg i.v. dose. Methods: The concentrations of valsartan in plasma and urine were measured using HPLC. The disposition of valsartan after an i.v. dose was characterized by biphasic decay kinetics, with a distribution phase (half-life 1.0 h), followed by a longer elimination phase (half-life 9.5 h). The volume of distribution at steady state was 16.9 l, and the total body clearance 2.2 l · h⁻¹. 29% of the i.v. dose was recovered unchanged in the urine. Results: Plasma levels peaked 2 h after oral administration of the 80 mg capsule. Thereafter, plasma levels declined biexponentially with a terminal t_1/2 of 7.0 h. C_max was reached 1 h after administration of the solution, and t_1/2 was 7.5 h. On average 7.3% (capsule) and 12.6% (solution) of the dose was excreted in the urine as the unchanged drug. The fraction of dose absorbed and systemically available after oral administration was 0.23 for the capsule and 0.39 for the solution, based on AUC. Absorption appeared to follow two first-order processes. The first phase was rapid, with a half-life of 0.5 h and 0.9 h for solution and capsule, respectively. The slower absorption phase was characterized by a half-life of 6.5 h for the solution and 3.5 h for the capsule. Most of the drug was absorbed during the period 0.4 h to 3 h post-dosing, and 90% of the fraction absorbed from the capsule was absorbed within 5 h. Received: 13 September 1996 / Accepted in revised form: 21 November 1996     

Nasal mucosal versus gastrointestinal absorption of nasally administered cocaine

Objective: Several xenobiotics, including cocaine, are dosed by the nasal route for systemic effects. The aim of this study was to estimate and compare cocaine input into the systemic circulation after oral and nasal dosing, and to determine the relevance of local absorption through the nasal mucosa. Methods: Cocaine was administered to healthy volunteers through the intravenous, oral, and nasal routes. Cocaine serum concentrations were measured at frequent intervals. From these data, the gastrointestinal, nasal, and nasal mucosa input rate functions were determined using nonparametric, subject-specific population deconvolution. Results: After oral dosing, cocaine input into systemic circulation increased slowly and peaked around 45 min after ingestion. The median systemic bioavailability after oral dosing was 33%. After nasal dosing, drug input was substantial even during the first minute and showed two peaks at 10 min and 45 min after ingestion. Since the second peak after nasal dosing closely resembled drug input after oral administration, we hypothesized that, after nasal administration, a part of the dose is swallowed and thereafter absorbed gastrointestinally. The data from the sessions with nasal cocaine administration were reanalyzed assuming the same shape for gastrointestinal drug input as after oral dosing. The fraction absorbed through the nasal mucosa was estimated to be 19% (95% CI: 11–26%). The fraction absorbed through the nasal mucosa contributed 31% (95% CI: 23–37%) of total systemic cocaine exposure. Conclusions: Our data suggest that the main reason addicts prefer nasal to oral cocaine dosing is faster absorption, enhancing the subjective effects rather than higher bioavailability. Received: 28 December 1999 / Accepted in revised form: 23 March 2000     

Evaluation of in vivo dissolution behavior and GI transit of griseofulvin, a BCS class II drug

Mean plasma concentration-time profile of griseofulvin, a BCS class II drug, orally administered as powders into rats, was predicted based on GITA model. However, it was very difficult to predict the individual plasma profile because of large inter-individual difference. As the absorption of griseofulvin would be rate-limited by the dissolution process, we tried to analyze the in vivo dissolution kinetics of griseofulvin by focusing on gastric emptying and intestinal transit as physiological factors influencing the in vivo dissolution kinetics. After oral administration of griseofulvin, theophylline and sulfasalazine into rats, gastric emptying and intestinal transit were simultaneously estimated by analyzing the absorption kinetics of theophylline and observing the appearance of sulfapyridine in plasma, respectively. Gastric emptying kinetics was not significantly correlated with absorption or dissolution behavior of griseofulvin. On the other hand, the cecum-arriving time reflecting the intestinal transit was significantly correlated with both AUC and total dissolved amount of griseofulvin. T(max) of griseofulvin also increased with the increase of cecum-arriving time. These results clearly indicate that the longer residence time could lead to the higher dissolution and absorption of griseofulvin and that the variance of intestinal transit could be responsible for the inter-individual difference of the in vivo absorption behavior.     

A ‘Rule of Unity’ for Human Intestinal Absorption

The ability to predict the passive intestinal absorption of organic compounds can be a valuable tool in drug design. Although Lipinski's ‘rule of 5’ is commonly used for this purpose, it does not routinely give reliable results. An alternative ‘rule of unity’ is proposed to predict the absorption efficiency of orally administered drugs that are passively transported. The rule of unity based upon the theoretical principals that govern passive transport. The ‘rule of 5’ and the ‘rule of unity’ are compared using experimentally determined passive human intestinal absorption data for 155 drugs. Absorption values which are >50% of the dose are classified as well absorbed and absorption values which are ≤50% of the dose are classified as classified as poorly absorbed. Comparison of the two models using a receiver operating characteristic (ROC) plot and McNemar's test reveal striking differences in absorption predictability. The ‘rule of 5’ gives twice as many false predictions than the ‘rule of unity.’     

An Integrated Model for Determining Causes of Poor Oral Drug Absorption

Purpose. To develop an integrated absorption model for estimating the fraction of dose absorbed and determining the causes of poor oral drug absorption. Methods. Both analytical and numerical methods were used to estimate the fraction of dose absorbed. Results. An integrated absorption model was developed by considering transit flow, dissolution, and permeation processes, simultaneously. A framework was proposed to determine permeability-, dissolution-, and solubility-limited absorption. Digoxin, griseofulvin, and panadiplon were employed to illustrate the applications of the integrated model in identifying the causes of poor absorption and guiding formulation development. Conclusions. The integrated absorption model was successfully applied to digoxin, griseofulvin, and panadiplon to estimate the fraction dose absorbed and to roughly determine the causes of poor oral drug absorption.     

Serum and urinary boron levels in rats after single administration of sodium tetraborate

The pharmacokinetics of boron was studied in rats by administering a 1 ml oral dose of sodium tetraborate solution to several groups of rats (n=20) at eleven different dose levels ranging from 0 to 0.4 mg/100 g body weight as boron. Twenty-four-hour urine samples were collected after boron administration. After 24 h the average urinary recovery rate for this element was 99.6 ± 7.9. The relationship between boron dose and excretion was linear (r=0.999) with a regression coefficient of 0.954. This result suggests that the oral bioavailability (F) of boron was complete. Another group of rats (n=10) was given a single oral injection of 2 ml of sodium tetraborate solution containing 0.4 mg of boron/100 g body wt. The serum decay of boron was followed and found to be monophasic. The data were interpreted according to a one-compartment open model. The appropriate pharmacokinetic parameters were estimated as follows: absorption half-life, t _1/2a=0.608±0.432 h; elimination half-life, t _1/2=4.64±1.19 h; volume of distribution, Vd=142.0±30.2 ml/100 g body wt.; total clearance, C _tot=0.359 ± 0.0285 ml/min per 100 g body wt. The maximum boron concentration in serum after administration (C _max) was 2.13 ± 0.270 mg/l, and the time needed to reach this maximum concentration (T _max) was 1.76 ± 0.887 h. Our results suggest that orally administered boric acid is rapidly and completely absorbed from the gastrointestinal tract into the blood stream. Boric acid in the intravascular space does not have a strong affinity to serum proteins, and rapidly diffuses to the extravascular space in proportion to blood flow without massive accumulation or binding in tissues. The main route of boron excretion from the body is via glomerular filtration. It may be inferred that there is partial tubular resorption at low plasma levels. The animal model is proposed as a useful tool to approach the problem of environmental or industrial exposure to boron or in cases of accidental acute boron intoxication. Received: 1 December 1997 / Accepted: 24 March 1998     

Effect of route of administration of fluconazole on the interaction between fluconazole and midazolam

Objective: Midazolam is a short-acting benzodiazepine hypnotic extensively metabolized by CYP3A4 enzyme. Orally ingested azole antimycotics, including fluconazole, interfere with the metabolism of oral midazolam during its absorption and elimination phases. We compared the effect of oral and intravenous fluconazole on the pharmacokinetics and pharmacodynamics of orally ingested midazolam. Methods: A double-dummy, randomized, cross-over study in three phases was performed in 9 healthy volunteers. The subjects were given orally fluconazole 400 mg and intravenously saline within 60 min; orally placebo and intravenously fluconazole 400 mg; and orally placebo and intravenously saline. An oral dose of 7.5 mg midazolam was ingested 60 min after oral intake of fluconazole/placebo, i.e. at the end of the corresponding infusion. Plasma concentrations of midazolam, α-hydroxymidazolam and fluconazole were determined and pharmacodynamic effects were measured up to 17 h. Results: Both oral and intravenous fluconazole significantly increased the area under the midazolam plasma concentration-time curve (AUC_0–3, AUC_0–17) 2- to 3-fold, the elimination half-life of midazolam 2.5-fold and its peak concentration (C_max) 2- to 2.5-fold compared with placebo. The AUC_0–3 and the C_max of midazolam were significantly higher after oral than after intravenous administration of fluconazole. Both oral and intravenous fluconazole increased the pharmacodynamic effects of midazolam but no differences were detected between the fluconazole phases. Conclusion: We conclude that the metabolism of orally␣administered midazolam was more strongly inhibited by oral than by intravenous administration of fluconazole. Received: 1 July 1996 / Accepted in revised form: 4 September 1996     

A compartmental absorption and transit model for estimating oral drug absorption.

This report describes a compartmental absorption and transit model to estimate the fraction of dose absorbed and the rate of drug absorption for passively transported drugs in immediate release products. The model considers simultaneous small intestinal transit flow and drug absorption. Both analytical and numerical methods were utilized to solve the model equations. It was found that the fraction of dose absorbed can be estimated by F(a) = 1-(1+0.54 P(eff))(-7), where P(eff) is the human effective permeability in cm/h. A good correlation was found between the fraction of dose absorbed and the effective permeability for ten drugs covering a wide range of absorption characteristics. The model was able to explain the oral plasma concentration profiles of atenolol.     

A physiological model for the estimation of the fraction dose absorbed in humans

A physiologically based model for gastrointestinal transit and absorption in humans is presented. The model can be used to study the dependency of the fraction dose absorbed (F(abs)) of both neutral and ionizable compounds on the two main physicochemical input parameters (the intestinal permeability coefficient (P(int)) and the solubility in the intestinal fluids (S(int))) as well as physiological parameters such as the gastric emptying time and the intestinal transit time. For permeability-limited compounds, the model produces the established sigmoidal dependence between F(abs) and P(int). In case of solubility-limited absorption, the model enables calculation of the critical mass-solubility ratio, which defines the onset of nonlinearity in the response of fraction absorbed to dose. In addition, an analytical equation to calculate the intestinal permeability coefficient based on the compound's membrane affinity and molecular weight was used successfully in combination with the physiologically based pharmacokinetic (PB-PK) model to predict the human fraction dose absorbed of compounds with permeability-limited absorption. Cross-validation demonstrated a root-mean-square prediction error of 7% for passively absorbed compounds.     

Estimating Human Oral Fraction Dose Absorbed: A Correlation Using Rat Intestinal Membrane Permeability for Passive and Carrier-Mediated Compounds

Based on a simple tube model for drug absorption, the key parameters controlling drug absorption are shown to be the dimensionless effective permeability, P _eff ^*, and the Graetz number, Gz, when metabolism or solubility/dissolution is not rate controlling. Estimating the Graetz number in humans and assuming that P _aq ^* is not rate controlling gives the following equation for fraction dose absorbed: F = 1– e ^{–2 P*w}. The correlation between fraction dose absorbed in humans and P _w ^* determined from steady-state perfused rat intestinal segments gives an excellent correlation. It is of particular significance that the correlation includes drugs that are absorbed by passive and carrier-mediated processes. This indicates that P _w ^* is one of the key variables controlling oral drug absorption and that the correlation may be useful for estimating oral drug absorption in humans regardless of the mechanism of absorption.     

The Use of BDDCS in Classifying the Permeability of Marketed Drugs

We recommend that regulatory agencies add the extent of drug metabolism (i.e., ≥ 90% metabolized) as an alternate method in defining Class 1 marketed drugs suitable for a waiver of in vivo studies of bioequivalence. That is, ≥ 90% metabolized is an additional methodology that may be substituted for ≥ 90% absorbed. We propose that the following criteria be used to define ≥ 90% metabolized for marketed drugs: Following a single oral dose to humans, administered at the highest dose strength, mass balance of the Phase 1 oxidative and Phase 2 conjugative drug metabolites in the urine and feces, measured either as unlabeled, radioactive labeled or nonradioactive labeled substances, account for ≥ 90% of the drug dosed. This is the strictest definition for a waiver based on metabolism. For an orally administered drug to be ≥ 90% metabolized by Phase 1 oxidative and Phase 2 conjugative processes, it is obvious that the drug must be absorbed. This proposal, which strictly conforms to the present ≥ 90% criteria, is a suggested modification to facilitate a number of marketed drugs being appropriately assigned to Class 1. Opinions expressed in this report are those of the authors. For those authors affiliated with regulatory agencies (DMB & LXY) the opinions do not necessarily reflect the views or policies of the regulatory agencies.     

A Physiologic Model for Simulating Gastrointestinal Flow and Drug Absorption in Rats

PURPOSE: The development of a physiologically based absorption model for orally administered drugs in rats is described. METHODS: Unlike other models that use a multicompartmental approach, the GI tract is modeled as a continuous tube with spatially varying properties. The mass transport through the intestinal lumen is described via an intestinal transit function. The only substance-specific input parameters of the model are the intestinal permeability coefficient and the solubility in the intestinal fluid. With this physiologic and physicochemical information, the complete temporal and spatial absorption profile can be calculated. RESULTS: A first performance test using portal concentration data published in the literature yielded an excellent agreement between measured and simulated temporal absorption profiles in the portal vein. Furthermore, the dose dependence of a compound with solubility-limited fraction dose absorbed in rats (chlorothiazide) could be adequately described by the model. CONCLUSIONS: The continuous absorption model is well suited to simulate drug flow and absorption in the GI tract of rats.     

Toxicokinetics of p-tert-octylphenol in female DA/Han rats after single i.v. and oral application

Female DA/Han rats were administered p-tert-octylphenol [OP; p-(1,1,3,3-tetramethylbutyl)-phenol], either intravenously (5 mg/kg body wt.) or orally by gavage (50 or 200 mg/kg body wt.). After i.v. administration the blood concentration-time curve of OP was fitted to a tri-exponential model, resulting in a final half-life (γ-phase) of 36.1 h. This contrasts to much more rapid eliminations previously reported in male Wistar rats. The oral bioavailability of 50 mg/kg OP was 12.3% and of 200 mg/kg 8.4%. The higher dose (200 mg/kg) was absorbed slower than the smaller dose, probably due to low solubility of OP in aqueous media. Maximal OP blood levels in female DA/Han rats receiving 50 and 200 mg OP/kg body wt. were 4.5 and 3 times higher than previously reported in male Wistar rats. The blood concentration-time curves after oral administration of OP to female DA/Han rats revealed pronounced interindividual differences, indicating extensive enterohepatic circulation of OP in this rat strain. In contrast to male Wistar rats, after application of high doses of OP to female DA/Han rats the compound was not completely eliminated within 48 h; under these conditions some bioaccumulation might therefore occur. The experimental toxicokinetics of OP appears as a relevant subject to be integrated into extrapolation of toxicological data, from in vitro to in vivo, and into systems of risk assessment of endocrine modulating activity which are currently being developed. Received: 8 March 1999 / Accepted: 27 April 1999     

Oral absorption of propiverine solution and of the immediate and extended release dosage forms: influence of regioselective intestinal elimination

Purpose  The muscarine receptor antagonist propiverine in immediate release tablet form (IR) undergoes presystemic elimination mediated by CYP450 enzymes and intestinal efflux transporters. The aim of our study with propiverine IR and extended release (ER) was to determine whether propiverine disposition is dose linear, to compare the pharmacokinetics of propiverine in oral solution with IR and ER and to show how absorption rate is associated with bioavailability. Methods  The pharmacokinetics of propiverine administered as intravenous propiverine (15 mg), 10, 15, and 30 mg propiverine IR, an oral propiverine solution (15 mg) and 10, 15, 30, and 45 mg propiverine ER were measured in two randomized, controlled, single-dose, five-period, cross-over studies, with each case involving a study cohort of ten healthy Caucasian subjects. Results  Disposition of propiverine IR and ER was not dose-related. The bioavailability of ER was 64.5 ± 16.1% compared to 50.3 ± 13.4% (non-significant) after administration of the IR and propiverine solution (42.6 ± 14.8%, p < 0.05). The mean absorption time (MAT) of ER (14.2 ± 4.79 h) was significantly longer than that of the solution and IR (3.94 ± 4.14 and 0.38 ± 3.79 h, respectively; both p < 0.05). The bioavailability of propiverine was significantly correlated to the MAT (r = 0.521, p < 0.001). Renal excretion of the metabolite M-23 after propiverine ER administration (6.7 ± 2.7%) was significantly lower than that after administration of the oral solution (10 ± 2.2%) and of IR (9.8 ± 2.7%; both p < 0.05). Conclusions  The bioavailability of propiverine appears to be dependent on the intestinal site of dissolution and, consequently, on the extent of presystemic intestinal elimination.     

Absorption sites of orally administered drugs in the small intestine

Introduction: In pharmacotherapy, drugs are mostly taken orally to be absorbed systemically from the small intestine, and some drugs are known to have preferential absorption sites in the small intestine. It would therefore be valuable to know the absorption sites of orally administered drugs and the influencing factors.

Areas covered:In this review, the author summarizes the reported absorption sites of orally administered drugs, as well as, influencing factors and experimental techniques. Information on the main absorption sites and influencing factors can help to develop ideal drug delivery systems and more effective pharmacotherapies.

Expert opinion: Various factors including: the solubility, lipophilicity, luminal concentration, pKa value, transporter substrate specificity, transporter expression, luminal fluid pH, gastrointestinal transit time, and intestinal metabolism determine the site-dependent intestinal absorption. However, most of the dissolved fraction of orally administered drugs including substrates for ABC and SLC transporters, except for some weakly basic drugs with higher pKa values, are considered to be absorbed sequentially from the proximal small intestine. Securing the solubility and stability of drugs prior to reaching to the main absorption sites and appropriate delivery rates of drugs at absorption sites are important goals for achieving effective pharmacotherapy.     

Evaluation of the Clearance of a Sublingual Buprenorphine Spray in the Beagle Dog Using Gamma Scintigraphy

Purpose The aim of this study was to evaluate clearance from the buccal cavity and pharmacokinetic profiles of a sublingual spray formulation in the dog, to assist in interpretation of future pharmacokinetic studies. Methods Radiolabelled buprenorphine in a spray formulation (400 μg/100 μl in 30% ethanol) was administered sublingually to four beagle dogs, and the residence in the oral cavity was determined using gamma scintigraphy. Pharmacokinetic sampling was performed to facilitate correlation of location of dose with significant pharmacokinetic events. Results Scintigraphic imaging revealed that clearance of the formulation from the oral cavity was rapid, with a mean T _50% clearance of 0.86 ± 0.46 min, and T _80% clearance of 2.75 ± 1.52 min. In comparison, absorption of buprenorphine was relatively slow, with a T _max of 0.56 ± 0.13 h. Good buccal absorption despite short residence time can be explained by lipophilicity of buprenorphine enabling rapid sequestration into the oral mucosa, prior to diffusion and absorption directly into systemic circulation. Conclusion This study demonstrated rapid clearance of a sublingual solution from the canine oral cavity, with T _50% similar to results previously reported in man, providing initial confidence in using a conscious dog model to achieve representative residence times for a sublingual solution.     

Evolution of a detailed physiological model to simulate the gastrointestinal transit and absorption process in humans, part 1: oral solutions

To enable more precise prediction of oral drug absorption, an existing physiologically based absorption model was revised. The revised model reflects detailed knowledge of human gastrointestinal (GI) physiology including fluid secretion and absorption, and comprises an elaborate representation of the intestinal mucosa. The alimentary canal from the stomach to the rectum was divided into 12 compartments. A mucosal compartment was added to each luminal segment of the intestine. A training set of 111 passively absorbed drugs with reported fractions of dose absorbed was used to optimize the semiempirical equation, which calculates intestinal permeability coefficients. The model was subsequently integrated into an established physiologically based pharmacokinetic software and validated by prediction of plasma concentration-time profiles of eight test compounds with diverse physicochemical properties. A good correlation between the simulated and experimental fractions of dose absorbed was established for the 111 compounds in the training set. Subsequently, the concentration-time profiles of six out of eight test compounds were predicted with high accuracy. The detailed model for GI transit and absorption presented in this study can help to understand the complex processes of oral absorption better and will be useful during the drug development process.     

In Vitro Studies of Intestinal Permeability and Hepatic and Intestinal Metabolism of 8-Prenylnaringenin, a Potent Phytoestrogen from Hops (Humulus lupulus L.)

Purpose The absorption potential and metabolism of 8-prenylnaringenin (8-PN) from hops (Humulus lupulus L.) were investigated. 8-PN is a potent estrogen with the potential to be used for the relief of menopausal symptoms in women. Methods Monolayers of the human intestinal epithelial cancer cell line Caco-2 and human hepatocytes were incubated with 8-PN to model its intestinal absorption and hepatic metabolism, respectively. Results The apparent permeability coefficients for 8-PN in the apical-to-basolateral and basolateral-to-apical directions of a Caco-2 monolayer were 5.2 ± 0.7 × 10⁻⁵ and 4.9 ± 0.5 × 10⁻⁵ cm/s, respectively, indicating good intestinal absorption via passive diffusion. Both glucuronide and sulfate conjugates of 8-PN were detected in the Caco-2 cell incubations. The 4′-O-glucuronide was the predominant Caco-2 cell metabolite, followed by 7-O-sulfate and 4′-O-sulfate. Both phase I and phase II metabolites of 8-PN were formed by human hepatocytes. The 7-O-glucuronide was the most abundant hepatocyte metabolite, and no sulfate conjugates were detected. Incubations with various cDNA-expressed UDP-glucuronosyltransferases indicated that the isozymes UGT1A1, UGT1A6, UGT1A8, and UGT1A9 were responsible for glucuronidation of 8-PN. Conclusions Although orally administered 8-PN should be readily absorbed from the intestine, its bioavailability should be reduced significantly by intestinal and hepatic metabolism.     

Intestinal permeability and its relevance for absorption and elimination

Human jejunal permeability (P_eff) is determined in the intestinal region with the highest expression of carrier proteins and largest surface area. Intestinal P_eff are often based on multiple parallel transport processes. Site-specific jejunal P_eff cannot reflect the permeability along the intestinal tract, but they are useful for approximating the fraction oral dose absorbed. It seems like drugs with a jejunal P_eff > 1.5 x 10^–4 cm s^–1 will be completely absorbed no matter which transport mechanism(s) are utilized. Many drugs that are significantly effluxed in vitro have a rapid and complete intestinal absorption (i.e. >85%) mediated by passive transcellular diffusion. The determined jejunal P_eff for drugs transported mainly by absorptive carriers (such as peptide and amino acid transporters) will accurately predict the fraction of the dose absorbed as a consequence of the regional expression. The data also show that: (1) the human intestinal epithelium has a large resistance towards large and hydrophilic compounds; and (2) the paracellular route has a low contribution for compounds larger than approximately molecular weight 200. There is a need for more exploratory in vivo studies to clarify drug absorption and first-pass extraction along the intestine. One is encouraged to develop in vivo perfusion techniques for more distal parts of the gastrointestinal tract in humans. This would stimulate the development of more relevant and complex in vitro absorption models and form the basis for an accurate physiologically based pharmacokinetic modelling of oral drug absorption.     

Regional Gastrointestinal Absorption of the Beta-Blocker Pafenolol in the Rat and Intestinal Transit Rate Determined by Movement of 14C-Polyethylene Glycol (PEG) 4000

The gastrointestinal absorption characteristics of pafenolol following oral administration as a solution in man and rat has previously been found to be a double-peak phenomenon and exhibited dose-dependent bioavailability, despite negligible presystemic metabolism. In both man and rat the first peak appeared approximately 0.5–1 hr postdose and the second, more pronounced peak 3–4 hr postdose. In rat more than 90% of the available dose was absorbed during the second peak. In the present study we investigated the absorption of a solution of pafenolol in rats after intrajejunal and intraileal administration. The resulting blood concentration–time profile of pafenolol exhibited one peak only; the extent of absorption was similar to that observed when the same dose was given orally. The small intestinal transit time of the ¹⁴C-PEG 4000 solution was found to be more than 3 hr. The transit rate was higher in the proximal part of the small intestine compared to the more distal part, where the transit of the solution was staggered. In conclusion, the results of the intestinal transit time investigation and the administrations of pafenolol at different levels of the alimentary tract indicate that pafenolol is a drug with a specific absorption site located in the ileocolonic region.