Presentation of a modified dispersion model (MDM) for hepatic drug extraction and a new methodology for the prediction of the rate-limiting step in hepatic metabolic clearance.

The main objectives were to investigate the roles of and interplay between determinants of hepatic clearance (CL(H)) in humans, to develop a methodology and reference system for the evaluation and prediction of the rate-limiting step in CL(H), and to update the dispersion model and compare it with traditionally used liver extraction models. The new methodology enables predictions of the hepatic uptake and CL(H), dissociation, and rate-limiting step. In general, absorption, dissociation and diffusion are comparably rapid processes, and metabolism is rate-limiting. The liver appears to have a high passive uptake capacity. The Modified Dispersion Model (MDM) has a dispersion number of 0.5 and a distribution factor (df = 0.87) for the correction of a longer hepatic transit time of unbound molecules and the exclusion of the hidden unbound fraction within erythrocytes. Liver models are functionally equivalent at low CL(H), but differ for highly extracted compounds. Well-stirred and parallel-tube models demonstrate the greatest difference in performance, for example, 6- and 800,000-fold differences in the estimated in vivo intrinsic CL(H) and predicted oral bioavailability of the high CL(H) drug naloxone, respectively. The roles of and interplay between determinants of CL(H) have been further clarified and can now be better predicted. Apparent advantages with the MDM include its scientific rationale and intermediate/ balanced performance.

Pre-clinical pharmacokinetics of the cyclooxygenase-inhibiting nitric oxide donor (CINOD) AZD3582.

The pre-clinical pharmacokinetics of AZD3582 (4-(nitrooxy)butyl-(2S)-2-(6-methoxy-2-naphthyl) propanoate) and its primary metabolites (naproxen and nitrate) were evaluated. AZD3582 had intermediate and passive intestinal permeability (40 times lower than for naproxen), high systemic plasma clearance (CL), substantial gastrointestinal hydrolysis, intermediate volume of distribution (Vss; >or=3.4 L kg-1) and half-life (t1/2; 7 h), negligible plasma protein binding (approximately 0.1%), low/intermediate oral uptake (>or=13% as intact substance) and low and varying oral bioavailability (mean 1.4% in minipigs and 3.9% in dogs). Following administration of therapeutically relevant oral doses, plasma concentrations of AZD3582 were very low (40 h in rats, minipigs and dogs, respectively. The Vss and CL for naproxen were small. Plasma protein binding was extensive, and saturation was observed within the therapeutic dose and concentration range. Intake of food prolonged the systemic absorption of naproxen in the minipig. The pharmacokinetics of naproxen did not show apparent time- or gender-related dependency. Following oral dosing of [3H]-, [14C]- and [15N]-AZD3582, most [14C]- and [3H]-activity was excreted in urine and expired air, respectively. Seventeen per cent of [15N] was recovered in minipig urine as [15N]-nitrate. About 30% of [3H]-activity (naproxen and/or naproxen-related metabolites) was excreted in bile and re-absorbed. Concentrations of [14C]-activity (nitrooxy-butyl group and/or its metabolites) in milk were higher than in plasma and [3H]-activity in milk. [3H]- and [14C]-excretion data indicated that intact AZD3582 was not excreted in urine, bile or milk to a significant extent. There was no apparent consistency between tissue distribution of [14C]- and [3H]-activity in the rat, which suggests rapid and extensive metabolism of extravascularly distributed AZD3582. A substantial increase of plasma nitrate levels was found after single and repeated oral doses of AZD3582 in the minipig. No inhibition or induction of CYP450 was found.

Gastrointestinal safety of AZD3582, a cyclooxygenase inhibiting nitric oxide donator: proof of concept study in humans.

BACKGROUND: Cyclooxygenase inhibiting nitric oxide donators (CINODs) are a new class of anti-inflammatory and analgesic drugs that may minimise gastrointestinal toxicity compared with standard non-steroidal anti-inflammatory drugs (NSAIDs) by virtue of nitric oxide donation. METHODS: A proof of concept study of the gastrointestinal safety of AZD3582, the first CINOD available for human testing, was conducted. Thirty one subjects were randomised to receive placebo, naproxen 500 mg twice daily, or its nitroxybutyl derivative AZD3582 in an equimolar dose (750 mg twice daily) for 12 days in a double blind three period crossover volunteer study. At the start and end of each dosing period, gastroduodenal injury was assessed by endoscopy and small bowel permeability by differential urinary excretion of lactulose and L-rhamnose. Pharmacokinetic profiles were assessed at steady state. RESULTS: On naproxen, the mean total number of gastroduodenal erosions was 11.5 (and one subject developed an acute ulcer) versus 4.1 on AZD3582 (p<0.0001). More than half of the subjects had no erosions on AZD3582. Differences were seen for both the stomach and duodenum. Naproxen increased intestinal permeability (lactulose:L-rhamnose ratio 0.030 before v 0.040 after treatment) whereas AZD3582 (0.029 before, 0.029 after; p=0.006 v naproxen) and placebo (0.030 before, 0.028 after; p<0.001 v naproxen) did not. The steady state bioavailability of naproxen metabolised from AZD3582 was 95% (95% confidence interval 87-101%) of that after naproxen administration. CONCLUSIONS: This human study supports animal data showing reduced gastrointestinal toxicity with the CINOD AZD3582. The potential combination of effective pain relief and gastrointestinal protection offered by AZD3582 warrants further evaluation in human clinical studies.

Jejunal permeability in humans in vivo and rats in situ: investigation of molecular size selectivity and solvent drag.

The mechanisms controlling rates and routes for intestinal absorption of nutrients and small compounds are still not fully clarified. In the present study we aimed to investigate the effect of solvent drag on intestinal permeability of compounds with different molecular sizes in humans and rats. The effective intestinal permeabilities (Peff) of hydrophilic compounds (MW 60-4000) were determined in the single-pass perfused jejunum in humans in vivo and rats in situ under iso- and hypotonic conditions. The transport mechanism(s) of water and the importance of the solvent drag effect were investigated by the use of D2O. This is the first report in humans establishing the relation between in vivo measured jejunal Peff and molecular size for hydrophilic compounds. In addition, in rats we also found a molecular-size selectivity for hydrophilic compounds similar to man. The jejunal Peff of water and urea (MW 60) in both species were several times higher than predicted from their physicochemical properties. In humans, the jejunal absorption of urea and creatinine (MW 113) was increased by solvent drag, while no effect was found for the other investigated compounds. In rats, Peff for urea and creatinine were unaffected. In conclusion, it is still unclear if solvent drag occurs mainly through the para- or transcellular route, although, results from this study further add to our earlier reports suggesting that the transcellular route is most important from a quantitative point of view regardless of physicochemical properties of the transported compounds.

The effect of a drug-delivery system consisting of soybean phosphatidyl choline and medium-chain monoacylglycerol on the intestinal permeability of hexarelin in the rat.

The aim of this study was to investigate if the effective in-situ permeability (Peff) of a new growth hormone-releasing peptide, hexarelin, along rat intestine was enhanced by a lipid matrix drug-delivery system comprising a mixture of soybean phosphatidyl choline and medium-chain monoacylglycerol (PC-MG). The study was performed with and without a protease inhibitor, Pefabloc SC. To enable better understanding of the mechanism of action of this delivery system we also studied the uptake of a small hydrophilic molecule, atenolol. PC-MG at a concentration of 15 mmol L(-1) increased the jejunal Peff of hexarelin approximately 20-fold, both in the presence and absence of Pefabloc SC, whereas Peff was not increased in the ileum and colon. PC-MG had no effect on the jejunal, ileal and colonic Peff of atenolol. Complete recovery of the non-absorbable molecule PEG 4000 showed that functional intestinal viability was maintained in all experiments. Although the results obtained in this study are promising, pharmacokinetic and toxicological studies are required to investigate if this delivery system is a suitable and safe candidate for improving the oral bioavailability of hexarelin.

A residence-time distribution analysis of the hydrodynamics within the intestine in man during a regional single-pass perfusion with Loc-I-Gut: in-vivo permeability estimation.

The goal of this study was to determine the most appropriate hydrodynamic model for the Loc-I-Gut in-vivo perfusion system. The general mixing-tank-in-series model, which can approximate single mixing tank and laminar and plug-flow hydrodynamics, was fitted to the observed experimental residence-time distribution curves for the non-absorbable marker [14C]PEG 4000. The residence-time distribution analysis shows that the hydrodynamics of the perfusion solution within the jejunal segment in man is well approximately by a model containing on average between 1-2 mixing tanks in series. The solution is well mixed when using perfusion rates of 2.0, 3.0 and 6.0 mL min-1. The average mean residence time estimates from the fitted residence-time distribution were 12 +/- 7.6, 15 +/- 4.2 and 7.7 +/- 4.6 min, respectively, at these three perfusion rates. The mean volumes of the segment (Vs) were 25 +/- 15, 45 +/- 12 and 46 +/- 27 mL, respectively. There were no statistical differences between 2.0, 3.0 and 6.0 mL min-1 in respect of the number of mixing tanks (n) and mean residence times. This residence-time distribution analysis indicates that the luminal fluid in the Loc-I-Gut perfusion system is well-mixed, and that permeability calculations based on the well-mixed assumption most closely approximate the actual local (average) membrane permeability within the perfused segment.

Regional intestinal permeability in rats of compounds with different physicochemical properties and transport mechanisms.

Because the absorption of orally administered drugs depends on intestinal permeability, we have investigated how absorptive capacity varies from the proximal to distal intestine in rats. The effective permeabilities of compounds with a range of physicochemical properties and different absorption mechanisms were estimated by use of a previously validated in-situ, single-pass perfusion model. The low colonic permeabilities of D-glucose and L-dopa indicate the absence or low capacity of the glucose- and amino-acid-transporters in this region. With the exception of the small and moderately lipophilic non-steroidal anti-inflammatory drug, naproxen, for which permeability was maintained throughout the intestine, the passive intestinal permeabilities for hydrophilic and lipophilic drugs were approximately twice as high in the jejunum and ileum as in the colon. These observations are in accord with those made in recent studies. However, the reasons for the high colonic permeability of non-steroidal anti-inflammatory drugs, and results obtained in previous animal experiments demonstrating that the colon is the region of the intestine with the highest absorptive capacity were not fully clarified. These data show that the permeability to hydrophilic and lipophilic drugs decreases along the intestine, whereas it is maintained throughout the intestine for the small and moderately lipophilic naproxen. Further investigations are required to clarify the interplay between membrane composition, fluidity and permeability under various conditions in different absorption models.

Comparison between permeability coefficients in rat and human jejunum.

PURPOSE: Our main aim is to determine the effective intestinal permeability (Peff) in the rat jejunum in situ for 10 compounds with different absorption mechanisms and a broad range of physico chemical properties, and then compare them with corresponding historical human in vivo Peff values. METHODS: The rat Peff coefficients are determined using an in situ perfusion model in anaesthetized animals. The perfusion flow rate used is 0.2 ml/min, which is 10 times lower than that used in humans. The viability of the method is assessed by testing the physiological function of the rat intestine during perfusions. RESULTS: The Peff for passively absorbed compounds is on average 3.6 times higher in humans compared to rats (Peff, man = 3.6 x Peff.rat+ 0.03.10(-4); R]2 = 1.00). Solutes with carrier-mediated absorption deviate from this relationship, which indicates that an absolute scaling of active processes from animal to man is difficult, and therefore needs further investigation. The fraction absorbed of drugs after oral administration in humans (fa) can be estimated from 1-e-(-2.Peff,man t rex/r.2.8). CONCLUSIONS: Rat and human jejunum Peff-estimates of passively absorbed solutes correlate highly, and both can be used with precision to predict in vivo oral absorption in man. The carrier-mediated transport requires scaling between the models, since the transport maximum and/or substrate specificity might differ. Finally, we emphasize the absolute necessity of including marker compounds for continuous monitoring of intestinal viability.

Regional rectal perfusion: a new in vivo approach to study rectal drug absorption in man.

BACKGROUND: In vivo permeability measurements of drugs in the colonic/rectal region in humans are difficult. A new instrument for the perfusion of a defined and closed segment in the colon/rectum was developed. The objective of this study was to evaluate its use for studying drug absorption mechanisms in the human rectum and to investigate the effect of transmucosal water absorption on drug permeability. Six healthy subjects participated at 2 separate occasions by using a modified system for segmental rectal perfusion. The system consisted of a multichannel tube with inflatable balloons and was endoscopically introduced into the rectum. The technique was considered acceptable by the following criteria; (a) high and reproducible recovery of PEG 4000, (b) stable residence time of the solution within the test segment, (c) flux of electrolytes that agrees with previous reports, (d) mass-balance absorption of antipyrine across the rectal barrier, (e) and good acceptability to the subjects. The permeability of antipyrine in the rectal region was increased by inducing net water absorption. D-glucose was not absorbed during any study periods. The present technique is valuable for studying drug absorption from the human rectum.

The lack of effect of induced net fluid absorption on the in vivo permeability of terbutaline in the human jejunum.

The absorption mechanism(s) of terbutaline in the human jejunum was studied by using the intestinal perfusion instrument, Loc-I-Gut. The present study was divided into three parts. In Part I the absorption of 10 and 20 microM of both (+) and (-)-terbutaline enantiomers was studied. The influence of D-glucose (80 mM) on the net fluid transport across the intestinal wall and the effective intestinal permeability (Peff) of both (+/-)-terbutaline (10 microM) and antipyrine (0.5 mM) was investigated in Part II. The experimental design of Part III was similar to that in Part II, with the exception that the perfusion solution was hypotonic and had a D-glucose concentration of 80 mM. No statistical differences were found in the Peff between terbutaline enantiomers or their concentrations. D-glucose (80 mM) did neither affect net fluid transport nor the Peff of (+/-)-terbutaline and antipyrine in the human jejunum. In contrast, hypotonic D-glucose (80 mM) solution induced a net fluid absorption (p < 0.01). In parallel with this observation, the Peff -value of (+/-)-terbutaline was unchanged, whereas the absorption of antipyrine was found to be significantly increased (p < 0.05). The increased permeability of antipyrine during the net fluid absorption phase might be due to convective paracellular flow, but more likely is it a consequence of a higher concentration gradient of the drug close to the intestinal wall, and thereby increased transcellular absorption. Based on these findings we propose that the major route for the oral absorption of terbutaline and antipyrine might be passive transcellular diffusion.

The influence of net water absorption on the permeability of antipyrine and levodopa in the human jejunum.

Food ingestion can influence the absorption of levodopa in the intestine and thereby contribute to fluctuations of motor functions in Parkinson patients. Obstruction of the active transport of levodopa by amino acids can be one factor. Paracellular drug absorption, a route proposed to be influenced by net transport of water across the intestinal epithelium, might occur for a small and hydrophilic drug such as levodopa. In the present study we studied how luminal L-leucine (60 mmol/L), alone or combined with hypotonicity, might stimulate net water absorption, and levodopa uptake in the human small intestine, since this possibly can contribute to the variable intestinal absorption of levodopa. The Loc-I-Gut perfusion technique was used in 10 healthy volunteers to study the effects of induced net fluid absorption on the small intestinal absorption of levodopa (2.5 mmol/L). An induced net fluid absorption was observed only when L-leucine was combined with a hypoosmolar perfusion solution. However, this did not enhance the intestinal permeability of levodopa. In conclusion, we suggest that the variability in the absorption of levodopa in Parkinson's disease cannot be explained by differences in transmucosal water flux in the human small intestine.