Active Free Drug Research Articles

Bidentate bromhexine drug coordination modes with various transition metal ions: Synthesis, characterization, and in vitro antibacterial and anti-breast cancer activity tests

BackgroundBromhexine (BHX) is a mucolytic drug used in treatment the respiratory disorders which are associated with excessive or viscid mucus. Transition metal complexes have made tremendous progress in the treatment of a variety of human ailments, according to reported articles. Transition metal complexes are being developed as medications with a lot of effort. Metal complexes can form a variety of coordination geometries, giving them distinct forms. So, binary metal complexes of bromhexine drug have been prepared to enhance the biological activity and stability of the free drug. MethodsA new series of binary complexes with bromhexine drug (BHX) has been prepared with some transition metal ions namely Cr(III), Mn(II), Fe(III), Co(II), Ni(II), Cu(II), Zn(II), and Cd(II). Elemental analyses, FT-IR, mass spectrometry, thermal studies and UV-Vis spectra have been used to characterize and structurally elucidate the produced metal complexes. Antibacterial activity has been tested for the ligand and metal complexes against a variety of pathogenic bacterial species (Bacillus subtilis, Escherichia coli, Pseudomonas aeruginosa and Staphylococcus aureus). In addition, the ligand has been tested for anticancer efficacy against the MCF-7 breast cancer cell line, as opposed to binary metal complexes. The binding orientation or conformation of the free BHX ligand and Co(II) complex in the active region of the protein of crystal structure of Escherichia coli (PDB ID: 3T88) and Pseudomonas aeruginosa (PDB ID: 6NE0) has been performed using molecular docking studies. ResultsThe BHX ligand coupled in neutral bidentate mode to the metal ions, according to FT-IR and 1H-NMR spectral results. The molar conductivity measurements of the complexes in DMF proved the electrolytic nature of all binary complexes. Co(II) complex showed the highest inhibition zone diameter against S. aureus, E. coli and P. aeruginosa. Zn(II) complex had the greatest inhibitory effect against P. aeruginosa and B. subtilis. Also, Cd(II) chelate appeared high efficacy as antibacterial agent against Pseudomonas aeruginosa and Staphylococcus aureus. ConclusionAll the output data conjugated to confirm the octahedral geometry of the metal complexes. The biological findings revealed that metal complexes can be more active than the free BHX ligand. Against MCF-7 cell line, Cd(II)-L complex is highly active complex (4.95 µg/mL) but BHX free drug is the most active compound (3.96 µg/mL).

Ex-vivo activation of a liposomal prodrug of mitomycin C by human tumors.

To examine the ex- vivo ability of explanted human tumors and normal tissue to activate liposomal mitomycin C lipidic prodrug (MLP) by releasing the active free drug form, mitomycin C (MMC). We tested conversion of MLP to MMC in an ex vivo assay using explanted tissues obtained during routine surgery to remove primary tumors or metastases. Tumor and adjacent normal tissue were obtained from freshly explanted tumors and were immediately deep frozen at -70°C. On test day, the fragments were thawed, homogenized and incubated in the presence of a fixed amount of liposomal MLP at 37°C for 1h. We measured MLP and its rate of conversion to MMC by HPLC. Controls included plasma, malignant effusions, red blood cells, tumor cell lines, mouse liver, and buffer with dithiothreitol, a potent reducing agent. Most patients tested (16/20) were diagnosed with colo-rectal carcinoma. The average fraction of MLP cleaved per 100-mg tumor tissue (21.1%, SEM = 1.8) was greater than per 100-mg normal tissue (16.6%, SEM = 1.3). When the tumor and normal tissue samples were paired by patient, the difference was statistically significant (p = 0.022, paired t test). Biological fluids did not activate liposomal MLP, while normal liver tissue strongly does. Interestingly, the omental fatty tissue also greatly activated MLP. Tumor tissue homogenates activate MLP with greater efficiency than the surrounding normal tissues, but far less than liver and adipose tissue. These observations demonstrate the bioavailability of liposomal MLP in human tumors, and its pharmacologic potential in cancer therapy.

Tumor stroma-targeted antibody-drug conjugate triggers localized anticancer drug release.

Although nonmalignant stromal cells facilitate tumor growth and can occupy up to 90% of a solid tumor mass, better strategies to exploit these cells for improved cancer therapy are needed. Here, we describe a potent MMAE-linked antibody-drug conjugate (ADC) targeting tumor endothelial marker 8 (TEM8, also known as ANTXR1), a highly conserved transmembrane receptor broadly overexpressed on cancer-associated fibroblasts, endothelium, and pericytes. Anti-TEM8 ADC elicited potent anticancer activity through an unexpected killing mechanism we term DAaRTS (drug activation and release through stroma), whereby the tumor microenvironment localizes active drug at the tumor site. Following capture of ADC prodrug from the circulation, tumor-associated stromal cells release active MMAE free drug, killing nearby proliferating tumor cells in a target-independent manner. In preclinical studies, ADC treatment was well tolerated and induced regression and often eradication of multiple solid tumor types, blocked metastatic growth, and prolonged overall survival. By exploiting TEM8+ tumor stroma for targeted drug activation, these studies reveal a drug delivery strategy with potential to augment therapies against multiple cancer types.

Binding of Small Molecule Drugs to Porcine Vitreous Humor.

Pharmacokinetics in the posterior eye segment has therapeutic implications due to the importance of retinal diseases in ophthalmology. In principle, drug binding to the components of the vitreous, such as proteins, collagen, or glycosaminoglycans, could prolong ocular drug retention and modify levels of pharmacologically active free drug in the posterior eye segment. Since drug binding in the vitreous has been investigated only sparsely, we studied vitreal drug binding of 35 clinical small molecule drugs. Isolated homogenized porcine vitreous and the drugs were placed in a two-compartment dialysis system that was used to separate the bound and unbound drug. Free drug concentrations and binding percentages were quantitated using LC-MS/MS. Drug binding levels varied between 21 and 74% in the fresh vitreous and 0 and 64% in the frozen vitreous. The vitreal binding percentages did not correlate with those in plasma. Our data-based pharmacokinetic simulations suggest that vitreal binding of small molecule drugs has only a modest influence on the AUC of free drug or drug half-life in the vitreous. Therefore, it is likely that vitreal binding is not a major reason for interindividual variability in ocular drug responses or drug-drug interactions.

Plasma Protein Binding Structure-Activity Relationships Related to the N-Terminus of Daptomycin.

Daptomycin is a lipopeptide antibiotic that is highly bound to plasma proteins. To date, the plasma components and structure-activity relationships responsible for the plasma protein binding profile of daptomycin remain uncharacterized. In the present study we have employed a surface plasmon resonance assay together with molecular docking techniques to investigate the plasma protein binding structure-activity relationships related to the N-terminal fatty acyl of daptomycin. Three compounds were investigated: (1) native daptomycin, which displays an N-terminal n-decanoyl fatty acid side chain, and two analogues with modifications to the N-terminal fatty acyl chain; (2) des-acyl daptomycin; and (3) acetyl-daptomycin. The surface plasmon resonance (SPR) data showed that the binding profile of native daptomycin was in the rank order human serum albumin (HSA) ≫ α-1-antitrypsin > low-density lipoprotein ≥ hemoglobin > sex hormone binding globulin > α-1-acid-glycoprotein (AGP) > hemopexin > fibrinogen > α-2-macroglobulin > β2-microglobulin > high-density lipoprotein > fibronectin > haptoglobulin > transferrin > immunoglobulin G. Notably, binding to fatty acid free HSA was greater than binding to nondelipidated HSA. SPR and ultrafiltration studies also indicated that physiological concentrations of calcium increase binding of daptomycin and acetyl-daptomycin to HSA and AGP. A molecular model of the daptomycin-human serum albumin A complex is presented that illustrates the pivotal role of the N-terminal fatty acyl chain of daptomycin for binding to drug site 1 of HSA. In proof-of-concept, the capacity of physiological cocktails of the identified plasma proteins to inhibit the antibacterial activity of daptomycin was assessed with in vitro microbiological assays. We show that HSA, α-1-antitrypsin, low-density lipoprotein, sex hormone binding globulin, α-1-acid-glycoprotein, and hemopexin are responsible for the majority of the sequestering activity in human plasma. The findings are relevant to medicinal chemistry programs focused on the development of next-generation daptomycin lipopeptides. Tailored modifications to the N-terminal fatty acyl domain of the daptomycin molecule should yield novel daptomycin lipopeptides with more ideal plasma protein binding profiles to increase the levels of active (free) drug in plasma and improved in vivo activity.

Total and Free Plasma Concentrations of the Active Metabolite of Leflunomide in Relation to Therapeutic Outcome in Kidney Transplant Recipients With BK-Virus Nephropathy

Plasma concentrations of A771726, the active moiety of leflunomide, have been suggested to be associated with antiviral efficacy and/or an increased risk of toxicity. A771726 is >99% bound to serum albumin, which can be relevant in kidney transplant recipients (KTRs) displaying impaired function, which leads to increased pharmacologically active free drug concentrations. This study investigated the relationship of total (t-) and free (f-) A771726 concentrations with clinical outcomes. The 20 KTRs displayed a median daily dose and time on leflunomide of 20 mg (range, 10–50) and 16.5 months (range, 2–28), respectively. A median of 6 (range, 1–15) trough concentrations were measured in each patient. All patients received steroids and a calcineurin inhibitor (CNI) as well as 4 of them, cidofovir. To evaluate therapeutic efficacy, we monitored viral loads in the urine and blood, serum creatinine, and kidney histology. To detect toxicity, we recorded blood and platelet counts, hematocrit, hemoglobin concentrations, liver enzymes (alanine aminotransferase [ALT], and aspartate aminotransferase [AST]), and skin diseases. The median t-A771726 concentration was 31.5 mg/L (interindividual range, 11.0–56.4); the median f-A771726 concentration and fraction were 55.8 μg/L and 0.19% (interindividual ranges, 27.9–148.4 μg/L and 0.12%–0.50%), respectively. A weak but significant inverse correlation was observed between the free drug fraction and both the glomerular filtration rate estimated by the Modification of Diet in Renal Disease formula (MDRD-GFR) (r = −0.202) and serum albumin (r = −0.358). Higher MDRD-GFRs were associated with greater t-A771726 concentrations. There were no significant associations between efficacy parameters and either the t- or f-A771726 concentration or between the t-A771726 concentration and toxicity parameters. In contrast, the f-A771726 concentration was significantly associated with leukopenia. These results indicated that f-A771726 concentrations may be more reliable than t-A771726 content to estimate the risk of leukopenia. Intensified elimination due to a higher free drug fraction and compromised absorption associated with a low GFR may have been responsible for the positive correlation between MDRD-GFR and t-A771726.

Total Phenytoin concentration is not well correlated with active free drug in critically-ill head trauma patients.

Objective:Phenytoin is an antiepileptic drug used widely for prophylaxis and treatment of seizure after neurotrauma. Phenytoin has a complex pharmacokinetics and monitoring of its serum concentrations is recommended during treatment. Total phenytoin concentration is routinely measured for monitoring of therapy. In this study, we evaluated the correlation between phenytoin total and free concentrations in neurotrauma critically-ill patients to determine whether the phenytoin total concentration is a reliable predictor of free drug, which is responsible for the therapeutic effects.Methods:A total of 40 adult head trauma patients evaluated for free (unbound) and total serum phenytoin concentrations. Patients were divided into two groups. Group A consists of 20 unconscious patients with severe head injury under mechanical ventilation and Group B consists of 20 conscious self-ventilated patients. Correlation and agreement between total and free phenytoin plasma concentrations were analyzed.Findings:Pearson correlation analysis and Bland-Altman test showed weak to moderate correlation (r = 0.528) and poor agreement between free and total phenytoin concentrations in patients with severe trauma and higher Acute Physiology And Chronic Health Evaluation II (APACHE II) scores (Group A) and good correlation (r = 0.817) and moderate agreement in patients with mild to moderate trauma and lower APACHE II scores (Group B).Conclusion:Our results indicated that total phenytoin serum concentration is not a reliable therapeutic goal for drug monitoring in severely-ill head trauma patients even in the absence of hypoalbuminemia, renal and hepatic failure. It seems justifiable to measure free phenytoin concentration in all severely ill neurotrauma patients.

Gestational influences on the pharmacokinetics of gestagenic drugs: A combined in silico, in vitro and in vivo analysis

Abstract During preclinical development of a gestagenic drug, a significant increase of the total plasma concentration was observed after multiple dosing in pregnant rabbits, but not in (non-pregnant) rats or monkeys. We used a PBPK modeling approach in combination with in vitro and in vivo data to address the question to what extent the pharmacologically active free drug concentration is affected by pregnancy induced processes. In human, a significant increase in sex hormone binding globulin (SHBG), and an induction of hepatic CYP3A4 as well as plasma esterases is observed during pregnancy. We find that the observed increase in total plasma trough levels in rabbits can be explained as a combined result of (i) drug accumulation due to multiple dosing, (ii) increase of the binding protein SHBG, and (iii) clearance induction. For human, we predict that free drug concentrations in plasma would not increase during pregnancy above the steady state trough level for non-pregnant women.

Re-evaluation of the Role of Broad-Spectrum Cephalosporins Against Staphylococci by Applying Contemporary In-Vitro Results and Pharmacokinetic- Pharmacodynamic Principles

The potency of cefepime, ceftriaxone, and ceftazidime was assessed by CLSI broth microdilution methods against 41,644 S. aureus (63.2% oxacillin-susceptible) and 14,266 coagulase-negative staphylococci (CoNS; 22.2% oxacillin-susceptible) through the SENTRY Antimicrobial Surveillance Program database (1998-2004). Using normal volunteer pharmacokinetic data and a linear intermittent intravenous infusion model, and an animal-derived pharmacokinetic/pharmacodynamic (PK-PD) target of ≥40% time above MIC, expected probabilities of target attainment (PTA) for cephems were evaluated using Monte Carlo simulation. Current CLSI breakpoints would rank the tested agents cefepime ≥ ceftriaxone > ceftazidime and by PK-PD PTA cefepime > ceftazidime > ceftriaxone. Cefepime has a potency advantage over ceftazidime (four- to eight-fold) and superiority at the usual dosing over ceftriaxone (22.7-66.1%) for oxacillin-susceptible staphylococci. Ceftazidime pharmacokinetic overcomes by-weight activity disadvantages, while a low proportion (<5%) of active free-drug penalizes ceftriaxone in the PTA calculations. PTA remained at ≥0.9 to a breakpoint of 8 mg/L for cefepime (1 g q8 or 12 hours) and ceftazidime and to a breakpoint of 2 mg/L for ceftriaxone. Regardless of applied breakpoint (CLSI or PKPD), cefepime has the widest and most potent anti-staphylococcal activity among commonly used “third- or fourth-generation” cephems. When used at doses ≥3 g/day, cefepime assures maximal coverage of oxacillin-susceptible staphylococci whether using existing (CLSI) or modified (PK-PD) breakpoints. Ceftriaxone should be used with caution.

Synthesis and in Vitro Biological Evaluation of Mannose-Containing Prodrugs Derived from Clinically Used HIV-Protease Inhibitors with Improved Transepithelial Transport

In an approach to improve the pharmacological properties, safety and pharmacokinetic profiles, and their penetration into HIV reservoirs or sanctuaries, and consequently, the therapeutic potential of the current protease inhibitors (PIs) used in clinics, we investigated the synthesis of various mannose-substituted saquinavir, nelfinavir, and indinavir prodrugs, their in vitro stability with respect to hydrolysis, anti-HIV activity, cytotoxicity, and permeation through a monolayer of Caco-2 cells used as a model of the intestinal barrier. Mannose-derived conjugates were prepared in two steps, in good yields, by condensing an acid derivative of a protected mannose with the PIs, followed by deprotection of the sugar protecting group. With respect to hydrolysis, these PI prodrugs are chemically stable with half-life times in the 50-60 h range that are compatible with an in vivo utilization aimed at improving the absorption/penetration or accumulation of the prodrug in specific cells/tissues and liberation of the active free drug inside HIV-infected cells. These stabilities correlate closely with the low in vitro anti-HIV activity measured for those prodrugs wherein the coupling of mannose to the PIs was performed through the peptidomimetic PI's hydroxyl. Importantly, mannose conjugation to the PIs was further found to improve the absorptive transepithelial transport of saquinavir and indinavir but not of nelfinavir across Caco-2 cell monolayers, by contrast to glucose conjugation which had the opposite effect. The mannose-linked prodrugs of saquinavir and indinavir display therefore a most promising therapeutic potential provided that bioavailability, penetration into the HIV infected macrophages, and HIV-reservoirs of these PIs are improved.

Potential Role of Mycophenolate Mofetil in the Management of Neuroblastoma Patients

AbstractFor Abstract see ChemInform Abstract in Full Text.

Potential Role of Mycophenolate Mofetil in the Management of Neuroblastoma Patients

In human neuroblastoma cell lines (LAN5, SHEP and IMR32), mycophenolic acid (MPA) at concentrations (10− 7–10− 6 M) readily attainable during immunosuppressive therapy with mycophenolate mofetil (Cellcept), induces guanine nucleotide depletion leading to cell cycle arrest and apoptosis through a p53 mediated pathway (up‐regulation of p53, p21 and bax and down‐regulation of bcl‐2 and survivin). MPA‐induced apoptosis is also associated to a marked decrease of p27 protein. In the same cell lines MPA, at lower concentrations (50 nM), corresponding to the plasma levels of the active free drug during Cellcept therapy, induces differentiation toward the neuronal phenotype by causing a partial chronic guanine nucleotide depletion. MPA‐induced differentiation is not associated to p27 accumulation as occurs using retinoic acid. At a fixed concentration of MPA a higher percentage of apoptotic or differentiated cells is obtained when non dialysed serum substitutes for the dialysed one, due to the higher hypoxanthine concentration in the former (about 10 µM) leading to competition on HPRT‐mediated salvage of guanine. At hypoxanthine or oxypurinol concentrations higher than 1 µM (up to 100 µM) no further enhancement of MPA effects was obtained, in agreement with the recently described safety of the allopurinol‐mycophenolate mofetil combination in the treatment of hyperuricemia of kidney transplant recipients. The apoptotic effects of MPA do not appear to be significantly increased by the UDP‐glucuronosyltransferase inhibitor niflumic acid.

Prodrugs of HIV Protease Inhibitors — Saquinavir, Indinavir and Nelfinavir — Derived from Diglycerides or Amino Acids: Synthesis, Stability and anti‐HIV Activity.

With the aim of improving the pharmacological properties of current protease inhibitors (PIs), the synthesis of various acyl and carbamate amino acid- or diglyceride-containing prodrugs derived from saquinavir, indinavir and nelfinavir, their in vitro stability with respect to hydrolysis and their anti-HIV activity in CEM-SS and MT4 cells have been investigated. L-Leucine (Leu) and L-phenylalanine (Phe) were connected through their carboxyl to the PIs while L-tyrosine (Tyr) was conjugated through its aromatic hydroxyl via various spacer units. Hydrolysis of the prodrug with liberation of the active free drug was crucial for antiviral activity. The Leu- and Phe-PI prodrugs released the active free drug very rapidly (half-lives of hydrolysis in buffer at 37 °C of 3–4 h). The Tyr-PI conjugates with a –C(O)(CH2)4- linker exhibited half-lives in the 40–70 h range and antiviral activities in the 21–325 nM range (from 2 to 22 nM for the free PIs). The chemically very stable carbamate “peptidomimetic” Tyr-PI prodrugs (no hydrolysis detected after 7 days in buffer) displayed a very low anti-HIV activity or were even inactive (EC50 from 2300 nM to >10 µM). A very low antiviral activity was measured for the diglyceride-substituted saquinavir and for all of the disubstituted indinavir and nelfinavir prodrugs. All these prodrugs probably released the active parent PI too slowly under the antiviral assay conditions. These results combined with those from transepithelial transport studies (Rouquayrol et al., Pharm. Res., 2002, 19, 1704–1712) indicate that conjugation of amino acids (through their carboxyl) to the PIs constitutes a most appealing alternative which could improve the intestinal absorption of the PIs and reduce their recognition by efflux carriers.

Prodrugs of HIV protease inhibitors-saquinavir, indinavir and nelfinavir-derived from diglycerides or amino acids: synthesis, stability and anti-HIV activity.

With the aim of improving the pharmacological properties of current protease inhibitors (PIs), the synthesis of various acyl and carbamate amino acid- or diglyceride-containing prodrugs derived from saquinavir, indinavir and nelfinavir, their in vitro stability with respect to hydrolysis and their anti-HIV activity in CEM-SS and MT4 cells have been investigated. l-Leucine (Leu) and l-phenylalanine (Phe) were connected through their carboxyl to the PIs while l-tyrosine (Tyr) was conjugated through its aromatic hydroxyl via various spacer units. Hydrolysis of the prodrug with liberation of the active free drug was crucial for antiviral activity. The Leu- and Phe-PI prodrugs released the active free drug very rapidly (half-lives of hydrolysis in buffer at 37 degree C of 3-4 h). The Tyr-PI conjugates with a -C(O)(CH(2))(4)- linker exhibited half-lives in the 40-70 h range and antiviral activities in the 21-325 nM range (from 2 to 22 nM for the free PIs). The chemically very stable carbamate "peptidomimetic" Tyr-PI prodrugs (no hydrolysis detected after 7 days in buffer) displayed a very low anti-HIV activity or were even inactive (EC(50) from 2300 nM to >10 microM). A very low antiviral activity was measured for the diglyceride-substituted saquinavir and for all of the disubstituted indinavir and nelfinavir prodrugs. All these prodrugs probably released the active parent PI too slowly under the antiviral assay conditions. These results combined with those from transepithelial transport studies (Rouquayrol et al., Pharm. Res., 2002, 19, 1704-1712) indicate that conjugation of amino acids (through their carboxyl) to the PIs constitutes a most appealing alternative which could improve the intestinal absorption of the PIs and reduce their recognition by efflux carriers.

Synthesis and anti-HIV activity of glucose-containing prodrugs derived from saquinavir, indinavir and nelfinavir

With the aim at improving the transport of the current HIV protease inhibitors across the intestinal and blood brain barriers and their penetration into the central nervous system, the synthesis of various acyl and carbamatoyl glucose-containing prodrugs derived from saquinavir, indinavir and nelfinavir, their in vitro stability with respect to hydrolysis, and their anti-HIV activity have been investigated. d-Glucose, which is actively transported across these barriers, was connected through its 3-hydroxyl to these antiproteases via a linker. The liberation of the active free drug during the incubation time of the prodrugs with the cells was found to be crucial for HIV inhibition. The labile ester linking of the glucose-containing moiety to the peptidomimetic hydroxyl of saquinavir or to the indinavir C-8 hydroxyl, which is not part of the transition state isostere, is not an obstacle for anti-HIV activity. This is not the case for its stable carbamate linking to the peptidomimetic hydroxyl of saquinavir, indinavir and nelfinavir. The chemical stability with respect to hydrolysis of some of the saquinavir and indinavir prodrugs reported here, the liberation rate of the active free drug and the HIV inhibitory potency are acceptable for an in vivo use of these prodrugs. These glucose-linked ester and carbamate prodrugs display a promising therapeutic potential provided that their bioavailability, penetration into the HIV sanctuaries, and/or the liberation of the active free drug from the carbamate prodrugs are improved. Furthermore, no cytotoxicity was detected for the prodrugs for concentrations as high as 10 or even 100 μM, thus indicating an encouraging therapeutic index.

The use of preclinical pharmacokinetic and pharmacodynamic data to predict clinical doses: current and future perspectives

The obtainment of appropriate pharmacokinetics and pharmacodynamics is critical to achieving an efficacious and safe clinical dose range. Therefore, the combination of pharmacokinetic and pharmacodynamic considerations at the preclinical discovery stage should lead to drugs with optimum performance characteristics in the clinic. Indeed, the pharmacokinetic phase, incorporating the absorption, distribution and clearance of the compound can have a profound impact on the in vivo potency, duration and selectivity of the compound being tested. Human pharmacokinetic parameters can be predicted from preclinical pharmacokinetic and metabolism data, and thus, human oral exposure of pharmacologically active free drug can be estimated. The potential variability in human oral exposure, due to factors such as variable absorption and polymorphic enzymes, can also be predicted. The potency of a compound against the target receptor can be determined from values such as K i, p A 2, EC 50, etc. However, in order to turn such a value into an appropriate target efficacy concentration, it is necessary to know the degree of receptor occupancy required to exert an effect. It is known that the required receptor occupancy can vary considerably from as little as 20% for agonists to close to 100% for enzyme inhibitors. If these issues can be resolved dose projections for efficacy can be made, from anticipated oral exposure and knowledge of the occupation of the target receptor, to guide dose selection for initial clinical dose escalation studies. In a similar manner, safety and toleration can be predicted from the potency of the compound against other receptors demonstrated in broad ligand binding studies.

Synthesis and anti-HIV activity of prodrugs derived from saquinavir and indinavir.

With a view to improving the pharmacological properties, safety and pharmacokinetic profiles of current protease inhibitors, the synthesis of various acyl-substituted saquinavir and indinavir prodrugs, their in vitro stability with respect to hydrolysis and their anti-HIV (LAI and HTLV IIIB) activity and cytotoxicity in CEM-SS and MT4 cells have been investigated. Hydrolysis of the ester bond and liberation of the active free drug was found to be crucial for HIV inhibition: the faster the hydrolysis, the closer the anti-HIV activity was to that of the respective parent drug. This is the case for most of the C-14-substituted indinavir and saquinavir derivatives (IC50 from 10 to 360 nM for ester half-lives of 90 min to 40 h). Concomitantly, the level of HIV inhibition is very low for the prodrugs for which hydrolysis is very slow. This is the case with the myristoyl or oleyl saquinavir esters, owing to the stable masking of the hydroxyl that is part of the peptidomimetic non-cleavable transition state isostere responsible for the inhibitory potency of saquinavir (and indinavir). In contrast, the anti-HIV activity of the monosubstituted C-8 indinavir prodrugs seems not to be correlated with their resistance to hydrolysis, as expected (the C-8 hydroxyl of indinavir is not involved in the transition state isostere). No cytotoxicity was detected for the indinavir and saquinavir prodrugs for concentrations as high as 10 or even 100 microM, thus indicating promising therapeutic potential.

Prediction of Free Phenytoin Levels Based on [Total Phenytoin]/[Albumin] Ratios: Potential Errors with Hypoalbuminemia

Therapeutic monitoring of the pharmacologically active (free drug) fraction of protein-bound medications (e.g., phenytoin) represents a major diagnostic challenge in clinical and laboratory medicine. While free drug levels may be beneficial in many clinical situations, current methods for predicting free phenytoin concentrations are unreliable and not recommended for general use. The authors have demonstrated a linear relationship (r2 = 0.98) between serum levels of total and bound phenytoin in 56 patients with seizure disorders. No significant correlations were observed when total phenytoin and albumin levels were compared independently to measured concentrations of free phenytoin or percent free phenytoin. A good correlation (r2 = 0.89) existed between free phenytoin levels and [total phenytoin]/[albumin] ratios in patients with normal or elevated albumin levels, but significantly weaker correlations were found in patients with hypoalbuminemia. Thus, [total phenytoin]/[albumin] ratios may have clinical value in predicting free phenytoin levels in uncomplicated patients without hypoalbuminemia.

Potential applications of free drug level monitoring in cardiovascular therapy.

Cardiovascular drugs, as a class, have low therapeutic indices, but also have great therapeutic potential. Plasma concentration information is therefore often of value when using these drugs. Unfortunately, the total plasma concentration may not reflect the concentration of pharmacologically active free drug, since a number of factors including disease states, heparin anticoagulation, non-linear binding characteristics, and in vitro artefacts can affect the protein binding of these agents. This may also explain their poor dose-response relationships and great interindividual variability in plasma concentration data. Careful studies relating bound and free drug concentration to pharmacological response may provide the clinician with a better guide to therapy, and enhance the usefulness of these drugs.