Modeling and allometric scaling of s(+)-ketoprofen pharmacokinetics and pharmacodynamics: a retrospective analysis.

Interspecies scaling of pharmacokinetic (PK) parameters is commonplace in drug development. However, information about proportionality of pharmacodynamic (PD) parameters in different species is scarce. We investigated the feasibility of allometric scaling of PK and PD parameters of s(+)-ketoprofen (sKTP) using the literature data from several animal species. Two different indirect response models were proposed to characterize sKTP inhibitory effects on synthesis of thromboxane B(2) (TXB(2)) and prostaglandin E(2) (PGE(2)). Using the traditional allometric approach, the obtained PK and PD parameters were plotted against body weights (BW) on a log-log scale. For all species, values of systemic clearance (Cl), distribution clearance (Cl(D)), central volume of distribution (V(c)), and volume of distribution at steady-state (V(ss)) were highly correlated (r(2) = 0.89-0.99) with BW. The PD parameters for inhibition of TXB(2) synthesis were poorly correlated with BW (r(2) = 0.25-0.54) while most of the parameters for inhibition of PGE(2) synthesis lacked any correlation (r(2) approximately 0.05). In conclusion, indirect response models adequately described the time course of sKTP inhibitory effects on synthesis of TXB(2) and PGE(2). Allometrical scaling showed PK parameters to change proportionally to BW, whereas PD parameters had limited ranges and were essentially weight independent.

Stability and in vitro metabolism of dipeptide model prodrugs with affinity for the oligopeptide transporter.

One approach to increase drug stability and to facilitate oral absorption of low bioavailability drugs may be to design oligopeptide ester prodrugs which are stable in the gastrointestinal tract, are transported via the oligopeptide transporter, and finally release the parent drug molecule into the blood circulation and/or by its site of action. In these kinds of prodrugs the ester linkage may be broken by pH dependent and/or enzyme catalyzed hydrolysis. The objective of the present study was to investigate the degradation mechanism and rate of the model compounds Glu(OBzl)-Sar, D-Glu(OBzl)-Ala and Asp(OBzl)-Sar in aqueous solution and in relevant biological media and to compare these results with those of our previous study of D-Asp(OBzl)-Ala. Furthermore, the resulting aqueous stability and in vitro metabolism data are related to our previous affinity data to evaluate if Glu-Sar, D-Glu-Ala, and Asp-Sar have potential as pro-moieties in these kinds of prodrugs. The degradation rates follow first-order kinetics, show maximun stability at pH 4-5 with maximum half-lives for Asp(OBzl)-Sar, Glu(OBzl)-Sar, and D-Glu(OBzl)-Ala of 115 h, 30 days and 152 days, respectively. The stability was dependent on buffer concentration, temperature, pH, and ionic strength. In biological media such as 80% human plasma, human gastric juice and intestinal fluid, and 10% rat jejunal homogenate at 37 degrees C, the half-lives were greater than 1 h except for the hydrolysis of Glu(OBzl)-Sar in 10% rat jejunal homogenate, where the half-life was approximately 16 min. All the stabilized dipeptides may have potential as drug carriers targeting hPepT1.

Stability and perfusion studies of Desmopressin (dDAVP) and prodrugs in the rat jejunum.

Three aliphatic carboxylic acid esters of the tyrosine phenolic group in Desmopressin (dDAVP) were investigated in vitro for their stability and metabolism in rat gastrointestinal media. The degradation followed strictly first-order kinetics and the prodrugs were quantitatively converted to dDAVP. The n-hexanoyl (II) and n-octanoyl (III) esters were rapidly hydrolysed in 10% rat jejunal fluid showing half-lives of 1.1+/-0.2 min and 1.4+/-0.1 min, respectively. In 5 % rat jejunal homogenate the half-lives were 3.2+/-0.2 min and <30 sec, respectively. The sterically hindered pivalate ester (I) proved to be more stable. The half-lives were 10.3+/-0.3 min in 10% rat jejunal fluid and 1.5+/-0.1 min in 10% rat jejunal homogenate, respectively. The presence of paraoxon, an inhibitor of type B esterases significantly decreased the degradation rate of the pivalate ester (I) in rat jejunal fluid (t1/2 > 5 hrs) indicating that the prodrug is converted to dDAVP by rapid luminal breakdown of the ester bond. It was shown that approximately 13 % of prodrug I disappeared from the gut lumen during a single-pass perfusion experiment in rat jejunum. Our results indicate that the disappearance from the jejunal lumen was primarily caused by degradation of the prodrug to dDAVP by esterases rather than absorption. The better stability of the sterically hindered prodrug (I) indicate that even more sterically hindered prodrugs will be a better choice for a further optimization of stability and lipophilicity, and consequently a potentially improved intestinal absorption of dDAVP.

Stability, metabolism and transport of D-Asp(OBzl)-Ala--a model prodrug with affinity for the oligopeptide transporter.

The model prodrug D-Asp(OBzl)-Ala has previously been shown to have affinity and to be transported by the oligopeptide transporter PepT1 expressed in Caco-2 cells. The main objective of the present study was to investigate the aqueous stability of D-Asp(OBzl)-Ala and its in vitro metabolism in different gastrointestinal media arising from rats and humans, as well as in human plasma. The second major aim of the study was to evaluate our previous study in Caco-2 cell culture, by determining the effective intestinal permeability (Peff) of D-Asp(OBzl)-Ala in situ using the single-pass rat perfusion model. The aqueous stability studies show water, general buffer, as well as specific acid and base catalysis of D-Asp(OBzl)-Ala. The degradation of the model prodrug was independent of ionic strength. The half-lives in rat jejunal fluid and homogenate were >3 h. In human gastric and intestinal fluids, the half-lives were >3 h and 2.3+/-0. 03 h, respectively. Using the rat single-pass perfusion technique, the effective jejunal permeability (Peff) of D-Asp(OBzl)-Ala was determined to be high (1.29+/-0.5.10-4 cm/s). The 32 times higher Peff value found in the perfusion model compared to Caco-2 cells is most likely due to a higher functional expression of the oligopeptide transporter. Rat jejuna Peff was reduced by approximately 50% in the presence of well known oligopeptide transporter substrates, such as Gly-Sar and cephalexin. It may be that D-Asp(OBzl)-Ala is primarily absorbed intact by the rat jejunal oligopeptide transporter, since the stability in the intestinal homogenate and fluids was rather high (t1/2>2.3 h).