Development of absorption furosemide prodrugs: synthesis, in vitro and in vivo evaluation.

Six acyloxymethyl esters of Furosemide were synthesized and the structures were determined by chemical and spectroscopic methods. Lipophilicity parameters were analysed by high performance liquid chromatography (HPLC). Hydrolysis performances in human plasma and intestinal fluids anticipate their properties as absorption prodrugs of Furosemide. A bioavailability study carried out with 8 male Wistar rats with one of the synthesized prodrug (acetyloxymethyl 4-chloro-N-furfuryl-5-sulfamoylanthranilate) showed a greater absorption in relation to Furosemide. The percentages of mean urinary recovery of Furosemide for the prodrug and for the standard solution of the drug were 20.84 and 14.36 respectively. The doses were 10 mg/Kg in Furosemide. The analytical determinations of Furosemide in biological fluids were done by HPLC.     

Di- and triester prodrugs of the varicella-zoster antiviral agent 6-methoxypurine arabinoside.

6-Methoxypurine arabinoside (9-beta-D-arabinofuranosyl-6-methoxy-9H-purine, 1) has potent and selective activity against varicella-zoster virus in vitro. An unfavourable metabolic profile observed with oral dosing in the rat led to the preparation of a variety of 2',3',5'-triesters (2a-n) and several 2',3'-, 2',5'-, and 3',5'-diesters of this arabinoside (3a-n, 4a-f, and 5a-j, respectively). The compounds were evaluated as prodrugs by measuring the urinary levels of 1 in rat urine after oral dosing. With the exception of triacetate 2a, the triesters failed to significantly enhance bioavailability. Administration of compound 2a resulted in a 3-fold increase in systemic availability of 1, possibly because of its increased water solubility (1.6 times more soluble than 1) and only slightly increased relative log P value (1.93 vs 0.50 for 1). The longer chain aliphatic triesters and aromatic triesters had lower water solubilities and increased lipophilic partitioning. These factors might account for the lower systemic bioavailability of these compounds. In contrast, the diesters, especially the aliphatic diesters, showed significantly improved systemic availability. This might be a consequence of the higher aqueous solubilities and enhanced partition coefficients seen with these compounds. 2',3'-Diacetate 3a showed the best combination of high systemic availability and water solubility of all the prodrugs of 1.     

Physiological models are good tools to predict rat bioavailability of EF5154 prodrugs from in vitro intestinal parameters

There are only a few reports on the methods that predict in vivo bioavailability from in vitro intestinal parameters. In the present study, we constructed physiological models where we examined if in vivo rat bioavailability was predictable from in vitro intestinal parameters using prodrugs of EF5154, a potent glycoprotein IIb/IIIa receptor antagonist, and other prodrugs. Apparent fraction absorbed (F(a),pred) was calculated using the physiological models that consist of absorption number calculated from Caco-2 cell membrane permeability (P(app)), and Damkohler number calculated from apparent degradation rate constant (K(dapp)) in rat small intestinal fluid. The predicted rat bioavailability that was calculated from F(a),pred corresponded to the observed rat bioavailability, and root mean square error (RMSE) and squared correlation coefficient (r(2)) were 4.58 and 0.904, respectively, suggesting that the physiological models consisting of the membrane permeability and degradation rate constant are good tools for predicting rat bioavailability of EF5154 prodrugs. As for other prodrugs where the chemical structure of their active forms differs from EF5154, the predicted rat bioavailability was not different from fraction absorbed (or rat bioavailability), suggesting the physiological models are generalized to various prodrugs that are not the substrates for active transporters.     

Tyrosine-based 1-(S)-[3-hydroxy-2-(phosphonomethoxy)propyl]cytosine and -adenine ((S)-HPMPC and (S)-HPMPA) prodrugs: synthesis, stability, antiviral activity, and in vivo transport studies

Eight novel single amino acid (6-11) and dipeptide (12, 13) tyrosine P-O esters of cyclic cidofovir ((S)-cHPMPC, 4) and its cyclic adenine analogue ((S)-cHPMPA, 3) were synthesized and evaluated as prodrugs. In vitro IC(50) values for the prodrugs (<0.1-50 μM) vs vaccinia, cowpox, human cytomegalovirus, and herpes simplex type 1 virus were compared to those for the parent drugs ((S)-HPMPC, 2; (S)-HPMPA, 1; IC(50) 0.3-35 μM); there was no cytoxicity with KB or HFF cells at ≤100 μM. The prodrugs exhibited a wide range of half-lives in rat intestinal homogenate at pH 6.5 (<30-1732 min) with differences of 3-10× between phostonate diastereomers. The tyrosine alkylamide derivatives of 3 and 4 were the most stable. (l)-Tyr-NH-i-Bu cHPMPA (11) was converted in rat or mouse plasma solely to two active metabolites and had significantly enhanced oral bioavailability vs parent drug 1 in a mouse model (39% vs <5%).     

通过体外自乳化性能及体内药代动力学评价优化葛根素自乳化制剂

本文将水不溶性药物葛根素制备成自乳化制剂。测定了葛根素在不同油相及表面活性剂的溶解度，结果表明葛根素在油酸、Tween 80中的溶解度较好，1，2-丙二醇不但能增加药物的溶解度，而且能够提高自乳化能力。以油酸为油相，Tween 80为表面活性剂，1，2-丙二醇为助表面活性剂，配制一系列混合物，通过绘制三元相图得到自乳化区，考察不同自乳化处方的自乳化性质，采用激光粒度散射仪测定乳化后粒子大小，在体外评价基础上选择较好的3个处方进行比格犬体内药动学研究，比较不同处方自乳化制剂在比格犬体内的生物利用度包括药代动力学参数Cmax， Tmax， AUC0-t。结果表明处方2和处方3的AUC0-t值［(5.201±0.511) ng·mL^-1·h， (5.174±0.498) ng·mL^-1·h］和Cmax值［(1.524±0.125) ng·mL^-1， (1.513±0.157) ng·mL^-1］显著高于处方4［(3.013±0.623) ng·mL^-1·h， (0.939±0.089) ng·mL^-1］，通过体内研究结果获得较优处方为油酸(17.5%)、Tween 80(34.5%)、1，2-丙二醇(34.5%)。自乳化释药系统提供了水不溶性药物口服给药的新途径。     

Pharmacokinetics of oral moclobemide in healthy human subjects and effects on MAO-activity in platelets and excretion of urine monoamine metabolites

The plasma concentrations of the MAO-inhibitor moclobemide (Ro 11-1163) were determined in six healthy male subjects after oral (tablets) administration. Effects on MAO activity in platelets and excretion of monoamine metabolites in urine were investigated. The design of the study was a double-blind cross-over study with single oral doses of placebo, 50, 100 and 200 mg of moclobemide. The elimination profile of the drug showed that the half life of the unchanged drug ranged between 1 and 2 h except in one subject with a half-life of about 4 h. The mean bioavailability calculated using flow model concepts was F = 0.43 after 50 mg, F = 0.47 after 100 mg and F = 0.59 after 200 mg. The outlier with a t 1/2 of 4 h was found to have a bioavailability of more than 0.80 after all 3 doses. The slightly increasing bioavailability with higher doses was interpreted as evidence of saturable hepatic first-pass elimination of the drug. MAO activity in platelets was measured before and 2, 6 and 24 h after drug administration. No inhibition of platelet MAO was obtained at any point in time or dose level, as to be expected since moclobemide preferentially inhibits MAO A. Urine excretion of the monoamine metabolites homovanillic acid (HVA), dihydroxyphenylacetic acid (DOP-AC), 3-methoxy-4-hydroxy-phenylglycol (MOPEG) and 5-hydroxyindoleacetic acid (5-HIAA) was followed during 48 h after placebo, 50 and 200 mg of moclobemide. Time but not dose contributed significantly to the variability in excretion of the monoamine metabolites.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro studies on the hydrolysis of frusemide in gastrointestinal juices.

To elucidate a possible explanation for a relatively low bioavailability, the hydrolysis of frusemide in gastrointestinal juices was studied in vitro at concentrations likely to be present in vivo. Between 1.0 and 4.4% of the frusemide molecules were hydrolyzed to 4-chloro-N-furfuryl-5-sulphamoyl-antranilic acid (CSA) after 1 h at 37 degrees C in gastric juices. The rate of hydrolysis was inversely connected to pH. No fall in frusemide concentration was observed and no CSA was found in duodenal juices after 4 h at 37 degrees C. In three buffer solutions with the same pH as three gastric juices frusemide was hydrolyzed to CSA at a lower rate than in the gastric juices (pH 1.2, P less than 0.15;pH 1.4, P less than 0.001; pH 1.6, P less than 0.001). The solubility of frusemide was significantly higher in gastric juice from two fasting subjects (83-104 mg l-1) than in buffer solutions with the same pH (52-58 mg 1-1). The solubility of frusemide was significantly increased (by 40-50%) in gastric juice obtained after pentagastrin stimulation compared with its solubility in the mixed gastric secretion obtained after fasting. The binding of frusemide to macromolecules was 28.0 +/- 9.7% in ventricular secretion after fasting while it was 1.4 +/- 2.6% in the fluid obtained after pentagastrin stimulation. It is concluded that a hydrolysis of frusemide in the stomach prior to absorption cannot explain the relatively low bioavailability of the drug observed after oral intake.     

In vitro and in vivo evaluation of the metabolism and bioavailability of ester prodrugs of mgs0039 (3-(3,4-dichlorobenzyloxy)-2-amino-6-fluorobicyclo[3.1.0]hexane-2,6-dicarboxylic Acid), a potent metabotropic glutamate receptor antagonist.

MGS0039 (3-(3,4-dichlorobenzyloxy)-2-amino-6-fluorobicyclo-[3.1.0]hexane-2,6-dicarboxylic acid) has been identified as a potent and selective antagonist for metabotropic glutamate receptors. However, the oral bioavailability of MGS0039 is 10.9% in rats, due to low absorption. Several prodrugs, synthesized to improve absorption, exhibited 40 to 70% bioavailability in rats. This study investigated in vitro metabolism using liver S9 fractions from both cynomolgus monkeys and humans and oral bioavailability in cynomolgus monkeys to select the prodrug most likely to exhibit optimal pharmacokinetic profiles in humans. In monkeys, transformation to active substance was observed (5.9-72.8%) in liver S9 fractions, and n-butyl, n-pentyl, 3-methylbutyl, and 4-methylpentyl ester prodrugs exhibited high transformation ratios (>64%). Cmax levels and F values after oral dosing increased to 4.1- to 6.3-fold and 2.4- to 6.3-fold, respectively, and a close relationship between transformation ratios and Cmax and F values was observed, indicating that the hydrolysis rate in liver S9 fractions is the key factor in determining oral bioavailability in monkeys. In humans, n-hexyl, n-heptyl, n-octyl, 5-methylbutyl, and 6-methylpentyl ester prodrugs exhibited high transformation ratios (>65%) in liver S9 fractions. With these prodrugs, n-hexyl, n-heptyl, and 5-methylpentyl ester, almost complete recovery (96-99%) was obtained. Given the transformation ratio, we anticipated that the n-heptyl alkyl ester prodrug would exhibit the highest oral bioavailability of active substances in humans, if the hydrolysis rate in liver S9 fractions is indeed the key factor in determining oral bioavailability in humans. On this basis, MGS0210 (3-(3,4-dichlorobenzyloxy)-2-amino-6-fluorobicyclo[3.1.0]hexane-2,6-dicarboxylic acid n-heptyl ester) seems to be a promising candidate among MGS0039 prodrugs.     

Maleic- and fumaric-diamides of (O,O-diacetyl)-L-Dopa-methylester as anti-Parkinson prodrugs in liposomal formulation

The maleic and fumaric diamides preparation of (O,O-diacetyl)-L-Dopa-methylester [(+)-4, (+)-5] are reported; they were synthesized in order to attenuate marked fluctuations of L-DOPA (LD) plasma levels and to overcome the problem of low bioavailability of LD. The new compounds were characterized evaluating solubility, chemical stability, apparent partition coefficient (log P) and comparing neostriatum dopamine (DA) levels in freely moving rats after i.p. administration of prodrugs [(+)-4, (+)-5] with prodrugs in liposomal formulations [(+)-4Lip, (+)-5Lip]. All the new compounds showed chemical stability in aqueous buffer solutions (pH 1.3 and 7.4). A relatively slow release of LD in human plasma was observed. Among the studied products, prodrug was able to induce sustained delivery of DA in rat striatal dialysate with respect to equimolar i.p admistration of LD. Furthermore, neostriatum DA concentration after administration of the synthesized prodrugs vs. prodrugs in liposomal formulations was compared (+)-4Lip, (+)-5Lip). The results suggest that cis dimeric prodrug (+)-4 and (+)-4Lip can improve the release of DA in rat brain and demonstrate the potential of these formulations for controlled delivery of antiparkinson agents.     

Pharmacodynamic response of entacapone in rats after administration of entacapone formulations and prodrugs with varying bioavailabilities

The aim of this in vivo study was to assess the effect of improved oral bioavailability of entacapone on its actual pharmacodynamic response, COMT inhibition in erythrocytes. Rats were administered entacapone orally as a suspension, as a plain solution, an entacapone/HP-beta-CD solution, two N-alkyl-carbamate ester prodrugs and intravenously as a solution. Also the relationship between pharmacodynamic and pharmacokinetic responses of entacapone was investigated. The administration of entacapone as a solution (plain solution pH 7.4; F=34.8% or entacapone/HP-beta-CD solution pH 3.0; F = 18.5%) resulted in significantly higher degree of COMT inhibition in erythrocytes than could be achieved by administering entacapone as a suspension (pH 3.0; F=8.9%). The inhibitory Emax model did not reveal any significant differences in EC50 estimates of entacapone suspension, entacapone/HP-beta-CD solution or entacapone solution. The overall pharmacodynamic response of entacapone (AUE; area under effect-time curve) was dependent on the pharmacokinetic response (AUC; area under concentration-time curve) irrespective of the entacapone formulation and dosage form. However, this dependency did not extend to formulations producing very high peak concentrations of entacapone in plasma; high plasma concentrations reached transiently after administration of entacapone solution had only a minor effect on the overall pharmacodynamic response (AUE). The inhibitory Emax model revealed that a plateau of COMT inhibition near to Emax is attained by plasma concentrations under 2000 ng/ml, irrespective of the formulation. This supports the results concerning the dependence of AUE on AUC.     

Pharmacokinetic and ulcerogenic studies of naproxen prodrugs designed for specific brain delivery

Naproxen (Nap) is an NSAID used as a neuroprotective agent to treat several neurodegenerative diseases. The observed limited brain bioavailability of the drug prompted the design of several chemical delivery systems. We report the synthesis and preliminary in vitro and in vivo investigations of Nap prodrugs with dihydropyridine (I) and ascorbic acid (II) through an ester spacer to target specific brain delivery of Nap. The purpose of this study was to determine the brain bioavailability of Nap after oral administration of the prodrugs in rats. The results showed moderate oral bioavailability of prodrugs (AUC = 53–94 h · μg/mL) in rats compared with parent Nap (AUC = 155 h · μg/mL) at equimolar doses. Contrarily, there was a twofold increase in Nap levels in the brain with the prodrugs compared to parent Nap. The enhanced brain bioavailability may be attributed to the specific carrier system in addition to the reduced percentage of plasma protein binding of Nap. Plasma protein binding of the tested prodrugs was investigated in vitro using equilibrium dialysis. The percentage of plasma free fraction of prodrugs (9–15%) was significantly greater than that of Nap (about 5%) when tested at 20 μM, illustrating more available prodrug to cross the blood brain barrier. A significant decrease in gastric ulcerogenicity of the prodrugs compared with parent Nap was also noted. In conclusion, oral dihydropyridine and ascorbate prodrugs for brain site-specific delivery of Nap may be promising candidates for safe, chronic use of NSAIDs for the treatment of neurodegenerative diseases.     

The bioavailability and disposition of 1-(beta-D-arabinofuranosyl)-5-(1-propynyl)uracil (882C87), a potent, new anti-varicella zoster virus agent.

1. The bioavailability and disposition of 882C87, an anti-varicella zoster virus (VZV) agent, have been investigated in healthy young and elderly volunteers. 2. The mean bioavailability of a 200 mg tablet was 21.1% in the young (range 13.3-33.0%, n = 10) and 24.6% in the elderly (range 14.4-38.4%, n = 8), which is sufficient to achieve plasma concentrations well above the IC50 for anti-VZV activity. 3. Plasma concentrations of 882C87 after 50 mg i.v. were higher in the elderly than in the young, associated with a significantly longer half-life (13.7 vs 11.8 h) and decreased renal clearance (0.11 vs 0.14 ml min-1 kg-1) and total clearance (0.15 vs 0.17 ml min-1 kg-1). 4. After intravenous administration, the main route of elimination of 882C87 was renal with 81.6% recovered unchanged in urine in the young and 71.2% in the elderly. The pyrimidine base, 5-propynyluracil (5-PU) was unquantifiable in plasma and only present in trace amounts in urine. 5. After oral administration to four healthy volunteers, only 17% of a dose of [14C]-882C87 was recovered unchanged in urine and 58% as 5-PU, with total recovery in urine accounting for 86% of the dose. There was a lag of 4-12 h before the appearance of 5-PU in plasma, peak concentrations were one-third to a half those of 882C87. The data suggest that 5-PU is formed from unabsorbed 882C87 in the gut lumen and then absorbed and excreted in urine. 6. 882C87 is a potential once daily treatment for shingles.     

Serine peptide phosphoester prodrugs of cyclic cidofovir: synthesis, transport, and antiviral activity

Cidofovir (HPMPC, 1), a broad-spectrum antiviral agent, is currently used to treat AIDS-related human cytomegalovirus (HCMV) retinitis and has recognized therapeutic potential for orthopox virus infections, but is limited by its low oral bioavailability. Cyclic cidofovir (2) displays decreased nephrotoxicity compared to 1, while also exhibiting potent antiviral activity. Here we describe in detail the synthesis and evaluation as prodrugs of four cHPMPC dipeptide conjugates in which the free POH of 2 is esterified by the Ser side chain alcohol group of an X-L-Ser(OMe) dipeptide: 3 (X=L-Ala), 4 (X=L-Val), 5 (X=L-Leu), and 6 (X=L-Phe). Perfusion studies in the rat establish that the mesenteric permeability to 4 is more than 20-fold greater than to 1, and the bioavailability of 4 is increased 6-fold relative to 1 in an in vivo murine model. In gastrointestinal and liver homogenates, the cHPMPC prodrugs are rapidly hydrolyzed to 2. Prodrugs 3, 4, and 5 are nontoxic at 100 microM in HFF and KB cells and in cell-based plaque reduction assays had IC 50 values of 0.1-0.5 microM for HCMV and 10 microM for two orthopox viruses (vaccinia and cowpox). The enhanced transport properties of 3-6, conferred by incorporation of a biologically benign dipeptide moiety, and the facile cleavage of the Ser-O-P linkage suggest that these prodrugs represent a promising new approach to enhancing the bioavailability of 2.     

Metabolism and Pharmacokinetics of Novel Oral Prodrugs of 9-[(R)-2-(phosphonomethoxy)propyl]adenine (PMPA) in Dogs

Purpose. A series of prodrugs designed to enhance the oral bioavailability of the antiretroviral agent 9-[(R)-2-(phosphonomethoxy)propyl]adenine (PMPA; 1) have been synthesized, including a bis-(acyloxymethyl) ester 2 and a series of bis-(alkoxycarbonyloxymethyl) esters 3-9. The in vitro biological stability andin vivo pharmacokinetics of these prodrugs were evaluated to support selection of a prodrug candidate for clinical evaluation. Methods. The in vitrobiological stability of the prodrugs was examined in dog tissues (intestinal homogenate, plasma and liver homogenate). The apparent half-lives were determined based on the disappearance of prodrug using reverse-phase HPLC with UV detection. Oral bioavailability of PMPA from each prodrug was determined in fasted beagle dogs. Concentrations of PMPA in plasma were determined by HPLC following fluorescence derivatization. Data for prodrugs were compared to historical data for intravenous PMPA. Results. All prodrugs were rapidly hydrolyzed in dog plasma and tissues (t_1/2 < 60 min). In fasted beagle dogs, bis-[(pivaloyloxy)methyl] PMPA (bis-POM PMPA) 2 had the highest oral bioavailability as PMPA (37.8 ± 5.1%). The oral bioavailabilities of PMPA from bis-(alkoxycarbonyloxymethyl) esters ranged from 16.0% to 30.7% and PMPA was the major metabolite formed. Conclusions. There was a correlation between oral bioavailability and intestinal stability of bis-(alkoxycarbonyloxymethyl) ester prodrugs (r² = 0.96). Lipophilicity (log P) was not a good predictor of oral bioavailability. The most labile prodrugs in dog intestinal homogenates, bis-(n-butyloxycarbonyloxymethyl) PMPA 5 and bis-(neo-pentyloxycarbonyloxymethyl) PMPA 8 (t_1/2 < 5 min) had the lowest oral bioavailabilities. Based on good oral bioavailability (30.1%), chemical and intestinal stability bis-(isopropyloxycarbonyloxymethyl) PMPA (bis-POC PMPA) 4 was selected as a candidate for clinical evaluation.     

Antitumor benzothiazoles. 16. Synthesis and pharmaceutical properties of antitumor 2-(4-aminophenyl)benzothiazole amino acid prodrugs.

A series of water-soluble L-lysyl- and L-alanyl-amide prodrugs of the lipophilic antitumor 2-(4-aminophenyl)benzothiazoles has been synthesized to address formulation and bioavailability issues related to the desired parenteral administration of the chosen clinical candidate. The prodrugs exhibit the required pharmaceutical properties of good water solubility (in weak acid) and stability at ambient temperature and degradation to free base in vivo. The lysyl-amide of 2-(4-amino-3-methylphenyl)-5-fluorobenzothiazole (NSC 710305, 6d) has been selected for phase 1 clinical evaluation.     

An In-vitro and In-vivo Correlative Approach to the Evaluation of Ester Prodrugs to Improve Oral Delivery of Propranolol

Abstract— A series of ester prodrugs of propranolol was synthesized by incorporating substituents (straight alkyl, branched alkyl, acyloxyalkyl and cycloalkyl) into the β-hydroxy function of propranolol with the aim of protecting the drug against first-pass metabolism following oral administration. The in-vitro hydrolysis rates of the prodrugs were, in increasing order, liver homogenate ? plasma > buffers. The pH-rate profile of the prodrugs showed maximum stability around pH 4·0; the hydrolysis rates were drastically increased over pH 6·8. QSAR analysis revealed hydrophobic (π) and electronic (σ) effects of the substituents play the main roles for prodrug hydrolysis in buffers and plasma, while hydrolysis in liver homogenate could not be well explained by any of these parameters. Four prodrugs (O-acetyl-, O-butyryl-, O-isovaleryl- and O-cyclopropanoyl-propranolol) were selected for oral administration based on their hydrolysis in-vitro. Following oral administration of prodrugs to beagle dogs the absolute bioavailabilities (F) of propranolol were about 2–4-fold that after an equivalent dose of propranolol. The prodrugs were rapidly absorbed and regenerated propranolol to attain peak plasma levels at 0–0·5 h. Intact prodrug levels were also observed, which varied depending on their respective stabilities in in-vitro media. A linear relationship between F of propranolol and log P was obtained. F further appeared to be parabolically dependent on the observed hydrolysis rates of prodrugs in liver homogenate suggesting optimal design manipulation. The overall in-vitro and in-vivo results showed that lipophilic prodrugs having higher chemical and enzymatic stability in buffers and plasma, but susceptible to hydrolysis in the liver homogenate, to be the most promising prodrugs for improving oral bioavailability of propranolol.     

Improved oral bioavailability of cyclosporin A in male Wistar rats. Comparison of a Solutol HS 15 containing self-dispersing formulation and a microsuspension

Oral bioavailability of the highly lipophilic and poorly water-soluble immunosuppressive agent cyclosporin A (CyA) in two different formulations was investigated in male Wistar rats. An aqueous microsuspension and a self-dispersing formulation composed of the surface-active ingredients Solutol HS 15:Labrafil M2125CS:oleic acid=7:2:1 (v/v/v) were administered to the animals at a dose level of 20 mg/kg. In order to calculate the absolute oral bioavailability, CyA was additionally administered intravenously at 10 mg/kg as microsuspension. It was found that the oral bioavailability of CyA in the Solutol HS 15-based formulation was twofold higher as compared to the microsuspension (69.9+/-2.8 vs. 35.7+/-3.3%, P=0.001). By contrast, the time to reach maximum plasma concentration (t(max)) and the terminal half-life (t(1/2)) did not differ significantly with the different formulations (t(max): 7.0+/-1.0 vs. 6.3+/-1.7 h; t(1/2): 20.5+/-2.9 vs. 16.7+/-4.7 h). In vitro solubility experiments demonstrated a marked increase in the aqueous solubility of CyA in the presence of the self-dispersing formulation as compared to the micronized powder alone (solubility after 120 min at 37 degrees C: 136 vs. 23.2 microg/ml in human gastric juice; 133 vs. 10.8 microg/ml in simulated intestinal juice). Most likely, the enhanced systemic exposure of CyA in the self-dispersing formulation was caused by improved solubility of CyA in the gastrointestinal fluids in the presence of the surface-active ingredients. Additional factors that may have contributed to increased oral bioavailability are inhibition of metabolism and/or transport processes as well as permeability enhancement by the co-administered excipients.     

The bioavailability of cefpodoxime proxetil tablets relative to an oral solution

The bioavailability of cefpodoxime proxetil tablets relative to an oral solution of cefpodoxime proxetil in a sucrose/alcohol/citric acid vehicle was studied in 11 healthy volunteers in a randomized, crossover study. Fasted subjects took one cefpodoxime proxetil 100 mg tablet or 50 mL of a 2 mg mL^?1 cefpodoxime proxetil oral solution on two separate occasions. In a third study period, all subjects took a 100 mg dose of the oral solution with a high-fat meal to investigate the effect of food on cefpodoxime proxetil absorption from the oral solution. Serial blood samples were obtained over a 24h period, and urine was collected for 48h after dosing. Cefpodoxime concentrations in plasma and in urine were determined using HPLC methods. The bioavailability of cefpodoxime proxetil tablets relative to the oral solution was 82%, as determined from AUC ratios. There was no difference in the rate of cefpodoxime absorption between dosage forms. Food had no effect on the extent of drug absorption from the oral solution but did result in delayed absorption. These results suggest that complete dissolution of cefpodoxime proxetil is critical for optimal bioavailability.     

Effects of vehicles and prodrug properties and their interactions on the delivery of 6-mercaptopurine through skin: bisacyloxymethyl-6-mercaptopurine prodrugs

A series of S6,9-bisacyloxymethyl-6-mercaptopurine (6,9-bis-6-MP) prodrug derivatives was synthesized and characterized. The solubilities of the derivatives in solvents (vehicles), which exhibited a wide range of polarities from water to oleic acid, were measured. The abilities of the prodrugs to deliver 6-mercaptopurine (6-MP) from the vehicles have also been determined, and experimental fluxes and permeability coefficients (Kp) have been calculated for a large number of prodrug: vehicle combinations. Generally the best prodrugs of the series in terms of delivering 6-MP, regardless of the vehicle, were the first two members--the bisacetyl- and the bispropionyloxymethyl-6-mercaptopurine prodrugs. This result has been attributed mainly to the increased water solubility of these two prodrugs compared with that of 6-MP and the other prodrugs, since all of the prodrugs are much more lipid soluble than 6-MP. For three vehicles--isopropyl myristate, propylene glycol, and water--there was a good correlation between log experimental Kp for the delivery of 6-MP by the prodrugs from those vehicles and the theoretical solubility parameters of the prodrugs. The stabilities of the bisacetyl-(2), bisproprionyl-(3), and bisbutyryloxymethyl-6-mercaptopurine (4) derivatives were determined in buffer and in buffer containing enzymes leached from the dermis. Prodrug 2 was more stable than 3 or 4 in the buffer containing the enzymes, while 4 was more stable than 2 or 3 in the plain buffer.     

The selectivty and anti-metastatic activity of oral bioavailable butyric acid prodrugs

Summary Acyloxyalkyl ester prodrugs of histone deacetylase inhibitors, a family of anti-cancer agents, are metabolized intracellularly to acids and aldehyde(s). The purpose of this study was to assess the in vitro and in vivo anticancer activity, selectivity and oral bioavailability of these prodrugs. The prodrugs exhibited a hierarchal potency of AN-193 ≥ AN-7 > AN-1 and AN-9 ≫ AN-10 against murine lung carcinoma (3LLD122) and human breast carcinoma (MCF-7) cell lines. AN-9, and to even greater extent AN-7, displayed preferential cytotoxicity against leukemic and glioblastoma cells compared to their normal cellular counterparts-normal mononuclear and astrocytes cells, respectively. In vivo, anti-metastatic activity was evaluated in a metastatic model of lung cancer in which Lewis lung carcinoma (3LLD122) cells are injected intravenously into C57/BL mice and produce lung nodules. The prodrugs administered orally demonstrated a significant inhibition of lung-lesion formation and their hierarchal potency concurred with that observed in vitro, with the exception of AN-193 that was the least active compound. Escalating doses of AN-7 (5–100 mg/kg), administered by oral or intraperitoneal routes and displayed equivalent anti-metastatic activities, confirmed the good oral bioavailability of AN-7. Consistent with these findings, a time course study of histone acetylation in subcutaneously implanted 3LL122 tumors showed 2–4 fold increases in histone acetylation within 0.5 h of intravenous, intraperitoneal, or oral administration of AN-7 (100 mg/kg). Relative contributions of the prodrug metabolites to the anti-neoplastic activity and the best candidate for clinical studies are discussed.