Ritesh Jain

Pharmacokinetics of amino acid ester prodrugs of acyclovir after oral administration: interaction with the transporters on Caco-2 cells.

In vivo systemic absorption of the amino acid prodrugs of acyclovir (ACV) after oral administration was evaluated in rats. Stability of the prodrugs, L-alanine-ACV (AACV), L-serine-ACV (SACV), L-isoleucine-ACV (IACV), gamma-glutamate-ACV (EACV) and L-valine-ACV (VACV) was evaluated in various tissues. Interaction of these prodrugs with the transporters on Caco-2 cells was studied. In vivo systemic bioavailability of these prodrugs upon oral administration was evaluated in jugular vein cannulated rats. The amino acid ester prodrugs showed affinity towards various amino acid transporters as well as the peptide transporter on the Caco-2 cells. In terms of stability, EACV was most enzymatically stable compared to other prodrugs especially in liver homogenate. In oral absorption studies, ACV and AACV showed high terminal elimination rate constants (lambda(z)). SACV and VACV exhibited approximately five-fold increase in area under the curve (AUC) values relative to ACV (p<0.05). C(max(T)) (maximum concentration) of SACV was observed to be 39+/-22 microM in plasma which is 2 times better than VACV and 15 times better than ACV. C(last(T)) (concentration at the last time point) of SACV was observed to be 0.18+/-0.06 microM in plasma which is two times better than VACV and three times better than ACV. Amino acid ester prodrugs of ACV were absorbed at varying amounts (C(max)) and eliminated at varying rates (lambda(z)) thereby leading to varying extents (AUC). The amino acid ester prodrug SACV owing to its enhanced stability, higher AUC and better concentration at last time point seems to be a promising candidate for the oral treatment of herpes infections.

Cotransport of macrolide and fluoroquinolones, a beneficial interaction reversing P-glycoprotein efflux

The purpose of this study was to determine the interactions of erythromycin and various fluoroquinolones with P-glycoprotein (P-gp) and in turn assess their effects on transport kinetics across a model cell monolayer. MDCKII-MDRI cells were selected as a model monolayer to evaluate the effects of various fluoroquinolones, ie, norfloxacin, lomefloxacin, ofloxacin, enoxacin, grepafloxacin, levofloxacin, and sparfloxacin on the P-gp–mediated efflux of 3H-cyclosporine (CsA) and 14C-erythromycin. IC50 values associated with grepafloxacin-, levofloxacin-, and sparfloxacin-mediated inhibition of P-gp were calculated across Caco-2 cells with erythromycin as the model P-gp substrate. Transport of erythromycin was then studied with P-gp saturable concentrations of fluoroquinolones. Western blot analysis was performed on Caco-2 cells to confirm P-gp expression. Only grepafloxacin elevated the uptake of 3H-CsA across the MDCKII-MDRI cell monolayer, whereas norfloxacin, lomefloxacin, ofloxacin, and enoxacin did not exert any effect on 3H-CsA uptake. Inhibition studies indicate that grepafloxacin, levofloxacin, and sparfloxacin are potent inhibitors of P-gp–mediated efflux of 14C-erythromycin in the MDCKII-MDRI cell monolayer. Similar studies were conducted across Caco-2 cells and IC50 values were calculated. Inhibitory potency of sparfloxacin (IC50 = 607.6 μM) exceeded that of levofloxacin (IC50 = 1644 μM) and grepafloxacin (IC50 = 2266 μM). Permeability ratio (BL-AP/AP-BL) of 14C-erythromycin was found to be 8.67, which was reduced to 1.18, 1.83, and 1.39 in the presence of grepafloxacin (1 mmol/L), levofloxacin (5 mmol/L), and sparfloxacin (1 mmol/L), respectively. Log partition coefficient of grepafloxacin (1.58), levofloxacin (0.553), and sparfloxacin (0.45) were correlated with the inhibition of P-gp. Western blot analysis indicated the expression of P-gp in Caco-2 cells. Fluoroquinolones like grepafloxacin, levofloxacin, and especially sparfloxacin significantly inhibit the efflux of erythromycin, which can modulate oral absorption and disposition of macrolide drugs when administered concomitantly.

Interaction of dipeptide prodrugs of saquinavir with multidrug resistance protein-2 (MRP-2): Evasion of MRP-2 mediated efflux

Saquinavir (SQV), the first protease inhibitor approved by FDA to treat HIV-1 infection. This drug is a well-known substrate for multidrug resistance protein-2 (MRP-2). The objective of this study was to investigate whether derivatization of SQV to dipeptide prodrugs, valine-valine-saquinavir (Val-Val-SQV) and glycine-valine-saquinavir (Gly-Val-SQV), targeting peptide transporter can circumvent MRP-2 mediated efflux. Uptake and transport studies were carried out across MDCKII-MRP2 cell monolayers to investigate the interaction of SQV and its prodrugs with MRP-2. In situ single pass intestinal perfusion experiments in rat jejunum were performed to calculate intestinal absorption rate constants and permeabilities of SQV, Val-Val-SQV and Gly-Val-SQV. Uptake studies demonstrated that the prodrugs have significantly lower interaction with MRP-2 relative to SQV. Transepithelial transport of Val-Val-SQV and Gly-Val-SQV across MDCKII-MRP2 cells exhibited an enhanced absorptive flux and reduced secretory flux as compared to SQV. Intestinal perfusion studies revealed that synthesized prodrugs have higher intestinal permeabilities relative to SQV. Enhanced absorption of Val-Val-SQV and Gly-Val-SQV relative to SQV can be attributed to their translocation by the peptide transporter in the jejunum. In the presence of MK-571, a MRP family inhibitor, there was a significant increase in the permeabilities of SQV and Gly-Val-SQV indicating that these compounds are probably substrates for MRP-2. However, there was no change in the permeability of Val-Val-SQV with MK-571 indicating lack of any interaction of Val-Val-SQV with MRP-2. In conclusion, peptide transporter targeted prodrug modification of MRP-2 substrates may lead to shielding of these drug molecules from MRP-2 efflux pumps.

Disposition kinetics of a dipeptide ester prodrug of acyclovir and its metabolites following intravenous and oral administrations in rat.

The objective of this work was to study the disposition kinetics of valine-valine–acyclovir (VVACV), a dipeptide ester prodrug of acyclovir following intravenous and oral administrations in rat. A validated LC-MS/MS analytical method was developed for the analysis VVACV, Valine-Acyclovir (VACV), and Acyclovir (ACV) using a linear Ion Trap Quadrupole. ACV was administered orally for comparison purpose. In the VVACV group, both blood and urine samples and in the ACV group only blood samples were collected. All the samples were analyzed using LC-MS/MS. The LLOQ for ACV, VACV, and VVACV were 10, 10, and 50 ng/ml, respectively. Relevant pharmacokinetic parameters were obtained by non-compartmental analyses of data with WinNonlin. Following i.v. administration of VVACV, AUC0-inf (min*μM) values for VVACV, VACV, and ACV were 55.06, 106, and 466.96, respectively. The AUC obtained after oral administration of ACV was 178.8. However, following oral administration of VVACV, AUC0-inf values for VACV and ACV were 89.28 and 810.77, respectively. Thus the exposure of ACV obtained following oral administration of VVACV was almost 6-fold higher than ACV. This preclinical pharmacokinetic data revealed that VVACV has certainly improved the oral bioavailability of ACV and is an effective prodrug for oral delivery of ACV.