Determination of hydroxyurea in human plasma by HPLC-UV using derivatization with xanthydrol.

A simple and rapid high performance liquid chromatography (HPLC) method using ultraviolet (UV) detection was developed to determine hydroxyurea (HU) concentration in plasma sample after derivatization with xanthydrol. Two hundred microliters samples were spiked with methylurea (MeU) as internal standard and proteins were precipitated by adding methanol. Derivatization of HU and MeU was immediately performed by adding 0.02M xanthydrol and 1.5M HCl in order to obtain xanthyl-derivatives of HU and MeU that can be further separated using HPLC and quantified using UV detection at 240nm. Separation was achieved using a C18 column with a mobile phase composed of 20mM ammonium acetate and acetonitrile in gradient elution mode at a flow rate of 1mL/min. The total analysis time did not exceed 18min. The method was found linear from 5 to 400µM and all validation parameters fulfilled the international requirements. Between- and within-run accuracy error ranged from -4.7% to 3.2% and precision was lower than 12.8%. This simple method requires small volume samples and can be easily implemented in most clinical laboratories to develop pharmacokinetics studies of HU and to promote its therapeutic monitoring.

Simultaneous Determination of Eight ß-Lactam Antibiotics, Amoxicillin, Cefazolin, Cefepime, Cefotaxime, Ceftazidime, Cloxacillin, Oxacillin, and Piperacillin, in Human Plasma by Using Ultra-High-Performance Liquid Chromatography with Ultraviolet Detection.

A simple and rapid ultra-high-performance liquid chromatography (UHPLC) method using UV detection was developed for the simultaneous determination of eight ß-lactam antibiotics in human plasma, including four penicillins, amoxicillin (AMX), cloxacillin (CLX), oxacillin (OXA), and piperacillin (PIP), and four cephalosporins, cefazolin (CFZ), cefepime (FEP), cefotaxime (CTX), and ceftazidime (CAZ). One hundred-microliter samples were spiked with thiopental as an internal standard, and proteins were precipitated by acetonitrile containing 0.1% formic acid. Separation was achieved on a pentafluorophenyl (PFP) column with a mobile phase composed of phosphoric acid (10 mM) and acetonitrile in gradient elution mode at a flow rate of 500 µl/min. Detection was performed at 230 nm for AMX, CLX, OXA, and PIP and 260 nm for CFZ, FEP, CTX, and CAZ. The total analysis time did not exceed 13 min. The method was found to be linear at concentrations ranging from 2 to 100 mg/liter for each compound, and all validation parameters fulfilled international requirements. Between- and within-run accuracy errors ranged from -5.2% to 11.4%, and precision was lower than 14.2%. This simple method requires small-volume samples and can easily be implemented in most clinical laboratories to promote the therapeutic drug monitoring of ß-lactam antibiotics. The simultaneous determination of several antibiotics considerably reduces the time to results for clinicians, which may improve treatment efficiency, especially in critically ill patients.

Validation of a simple HPLC-UV method for rifampicin determination in plasma: Application to the study of rifampicin arteriovenous concentration gradient.

In clinical practice, rifampicin exposure is estimated from its concentration in venous blood samples. In this study, we hypothesized that differences in rifampicin concentration may exist between arterial and venous plasma. An HPLC-UV method for determining rifampicin concentration in plasma using rifapentine as an internal standard was validated. The method, which requires a simple protein precipitation procedure as sample preparation, was performed to compare venous and arterial plasma kinetics after a single therapeutic dose of rifampicin (8.6 mg/kg i.v, infused over 30 min) in baboons (n=3). The method was linear from 0.1 to 40 µg mL(-1) and all validation parameters fulfilled the international requirements. In baboons, rifampicin concentration in arterial plasma was higher than in venous plasma. Arterial Cmax was 2.1±0.2 fold higher than venous Cmax. The area under the curve (AUC) from 0 to 120 min was ∼80% higher in arterial plasma, indicating a significant arteriovenous concentration gradient in early rifampicin pharmacokinetics. Arterial and venous plasma concentrations obtained 6h after rifampicin injection were not different. An important arteriovenous equilibration delay for rifampicin pharmacokinetics is reported. Determination in venous plasma concentrations may considerably underestimate rifampicin exposure to organs during the distribution phase.

An optimal LC-MS/MS method for determination of azithromycin in white blood cells: application to pediatric samples.

BACKGROUND: Studies suggest that particular antimicrobial and anti-inflammatory properties of azithromycin (AZM) can be related to its extensive accumulation in white blood cells (WBCs). However, available methods for determination of AZM in WBCs require large blood volumes unsuited to a pediatric context. Therefore, an LC-MS/MS method was developed for determination of AZM in WBCs. RESULTS: WBCs were isolated from 500 µl of whole blood by lysing red blood cells. Then, lysis of WBCs was performed with methanol/buffer containing AZM-d3-(13)C as internal standard. After reversed phase LC, detection was performed under multiple reaction monitoring conditions in positive electrospray mode. Linearity ranged from 0.5 to 200 ng per WBC sample. Within-run and overall accuracy and precision ranged from 95.3 to 101.1% and from 1.6 to 4.7%, respectively. All validation parameters fulfilled international requirements. CONCLUSIONS: This method can be easily performed on small samples and provides reliable data, including in children and neonates.

Simultaneous determination of three carbapenem antibiotics in plasma by HPLC with ultraviolet detection.

A simple, precise and accurate high-performance liquid chromatography (HPLC) method using ultraviolet (UV) detection has been developed for simultaneous determination of carbapenem antibiotics: imipenem, meropenem and ertapenem in human plasma. Samples were spiked with ceftazidime as internal standard and proteins were precipitated by acetonitrile. Separation was achieved on a C8 column with a mobile phase composed of phosphate buffer 0.1M (pH 6.8) and methanol in gradient elution mode. Detection was performed at 298 nm. Calibration curves were linear from 0.5 to 80 mg/L for each compound, with correlation coefficients over 0.997. Intra- and inter-day validation studies showed accuracy between -4.5 and 8.1% and precision below 10.4%. Mean recoveries were 82.2, 90.8 and 87.7% for imipenem, meropenem and ertapenem, respectively. This method provides a useful tool for the therapeutic drug monitoring of carbapenems.

[Non-guideline use of innovative and expensive drugs in pediatrics: assessing clinical practice]. / Utilisation hors recommandations des médicaments innovants et coûteux en pédiatrie.

OBJECTIVE: The objective of this study was to analyze in a pediatric hospital the use of expensive drugs as part of the new activity-based system (T2A) of funding for French public hospitals. We identified and analyzed the therapeutic use of these drugs in indications not included in the expert recommendations issued to accompany this change, with the goal of proposing specific pediatric recommendations. METHOD: Analysis of prescriptions from May through September 2005 showed that 259 patients received expensive drugs subject to special reimbursement. The computerized prescription system enabled us to monitor and validate prescriptions daily. Indications for these expensive drugs were ranked by relevance. RESULTS: The prescriptions analyzed covered 26 expensive drugs. Among the 344 "patient-drugs", 80% were expensive drugs for an accepted therapeutic use, 5% for a pertinent therapeutic use (under evaluation), and 15% for "off-label" uses (2% "not approved" and 13% for indications not considered by the recommendations). CONCLUSION: This study showed that some therapeutic uses not approved by the official recommendations are nevertheless justified. Gathering data from other pediatric hospitals is essential to determine the need for pediatric clinical trials.