Simultaneous determination of amiodarone and its major metabolite desethylamiodarone in plasma, urine and tissues by high-performance liquid chromatography

A simple and sensitive high-performance liquid chromatographic method for the simultaneous assay of amiodarone and desethylamiodarone in plasma, urine and tissues has been developed. The method for plasma samples and tissue samples after homogenizing with 50% ethanol, involves deproteinization with acetonitrile containing the internal standard followed by centrifugation and direct injection of the supernatant into the liquid chromatograph. The method for urine specimens includes extraction with a diisopropyl ether-acetonitrile (95:5, v/v) mixture at pH 7.0 using disposable Clin-Elut 1003 columns, followed by evaporation of the eluate, reconstitution of the residue in methanol-acetonitrile (1:2, v/v) mixture and injection into the chromatograph. Separation was obtained using a Radial-Pak C18 column operating in combination with a radial compression separation unit and a methanol-25% ammonia (99.3:0.7, v/v) mobile phase. A wavelength of 242 nm was used to monitor amiodarone, desethylamiodarone and the internal standard. The influence of the ammonia concentration in the mobile phase on the capacity factors of amiodarone, desethylamiodarone and two other potential metabolites, monoiodoamiodarone (L6355) and desiodoamiodarone (L3937) were investigated. Endogenous substances or a variety of drugs concomitantly used in amiodarone therapy did not interfere with the assay. The limit of sensitivity of the assay was 0.025 micrograms/ml with a precision of +/- 17%. The inter- and intra-day coefficient of variation for replicate analyses of spiked plasma samples was less than 6%. This method has been demonstrated to be suitable for pharmacokinetic and metabolism studies of amiodarone in man.     

Simultaneous determination of gastrodin and its metabolite by HPLC

A rapid and specific HPLC method for the simultaneous determination of gastrodin and its metabolite gastrodigenin (p-hydroxybenzyl alcohol) in rat plasma, bile, liver, urine and faeces is described. The separation was achieved by using a reversed phase column (YWG-C18) eluted with methanol-water (2.5:97.5 v/v). Phloroglucinolum was used as internal standard and the peaks were detected at UV 221 nm. The protein precipitation with ethanol was a very simple and rapid method for sample preparation. The gastrodin and gastrodigenin were quantitated by measuring the peak-height ratios. There was a linear concentration range of 10-320 micrograms/mL in the assay for both compounds. The coefficients of variation (within-day) for samples spiked with gastrodin and gastrodigenin were 2.94% and 3.08%, respectively. The method demonstrated a high specificity and was suitable for use in pharmacokinetic studies.     

Determination of neomycin in plasma and urine by high-performance liquid chromatography. Application to a preliminary pharmacokinetic study.

A reversed-phase high-performance liquid chromatographic (HPLC) method has been developed for the determination of neomycin in plasma and urine. The plasma was deproteinated with trichloroacetic acid and centrifuged. The supernatant was mixed with ion-pair concentrate and centrifuged again. The resultant supernatant was analyzed by HPLC. Urine was centrifuged to remove debris, if any, mixed with ion-pair concentrate and analyzed directly by HPLC. The HPLC conditions consisted of an ion-pairing mobile phase, a reversed-phase column, post-column derivatization with o-phthalaldehyde (OPA) reagent and fluorescence detection. The overall average recovery of neomycin was 97 and 113% from plasma spiked at 0.25-1.0 micrograms/ml, using standard curves prepared in plasma extract and in water, respectively, and 94% for urine spiked at 1-10 micrograms/ml using a standard curve prepared in water. The method was used to detect neomycin in plasma and urine obtained from animals injected intramuscularly with neomycin. Various pharmacokinetic parameters of neomycin were also determined from its profile of plasma concentration versus time.     

Simultaneous determination of the anticonvulsants, cinromide (3-bromo-n-ethylcinnamamide), 3-bromocinnamamide, and carbamazepine in plasma by high-performance liquid chromatography

A high-performance liquid chromatographic method is described for monitoring plasma concentrations of cinromide (3-bromo-N-ethylcinnamamide) and its de-ethylated metabolite. Carbamazepine levels can be easily measured by the same technique. The N-isopropyl analogue of cinromide is used as internal standard, and all compounds are easily separated on a reversed-phase column operated at 55 degrees with a small-diameter pre-column maintained at the same temperature. The extraction is rapid and generally applicable to plasma and urine samples that are to be analyzed by reversed-phase chromatography. Short- and long-term reproducibility studies show less than 4% relative standard deviation for replicate determinations for all drugs. Limits of quantitation are 10-20 ng/ml with an internal standard concentration of 3 micrograms/ml. Another metabolite of cinromide, 3-bromocinnamic acid, which may have some anticonvulsant effect, can be analyzed simultaneously by buffering the mobile phase and adding an ion-pairing reagent.     

Determination of risperidone and 9‐Hydroxyrisperidone using HPLC,in plasma of children and adolescents with emotional and behavioural disorders

A simple, rapid, selective, accurate and precise method is described for the determination of risperidone and its active metabolite, 9‐hydroxyrisperidone, in plasma using a chemical derivative of risperidone (methyl‐risperidone) as the internal standard. The sample workup involved a single‐step extraction of 1 mL plasma, buffered to pH 10, with heptane–isoamyl alcohol (98:2 v/v), then evaporation of the heptane phase and reconstitution of the residue in mobile phase. HPLC separation was carried out at on C₁₈ column using a mobile phase of 0.05 m dipotassium hydrogen orthophosphate (containing 0.3% v/v triethylamine) adjusted to pH 3.7 with orthophosphoric acid (700 mL), and acetonitrile (300 mL). Flow rate was 0.6 mL/min and the detection wavelength was 280 nm. Retention times were 2.6, 3.7 and 5.8 min for 9‐hydroxy risperidone, risperidone and the internal standard, respectively. Linearity in spiked plasma was demonstrated from 2 to 100 ng/mL for both risperidone and 9‐hydroxyrisperidone (r ≥ 0.999). Total imprecision was less than 13% (determined as co‐efficient of variation) and the inaccuracy was less than 12% at spiked concentrations of 5 and 80 ng/mL. The limit of detection, determined as three times the baseline noise, was 1.5 ng/mL. Clinical application of the assay was demonstrated for analysis of post‐dose (0.55–4.0 mg/day) samples from 28 paediatric patients (aged 6.9–17.9 years) who were taking risperidone orally for behavioural and emotional disorders. Copyright © 2009 John Wiley & Sons, Ltd.     

A validated HPLC method with electrochemical detection for simultaneous assay of 5-aminosalicylic acid and its metabolite in human plasma

A high-performance liquid chromatographic method was developed, validated and applied to the simultaneous determination of 5-aminosalicylic acid (5-ASA) and its acetylated metabolite (acetyl-5-ASA) in human plasma. The method involves liquid-liquid extraction with methanol followed by isocratic reversed-phase chromatography on a Kromasil KR100 C(18) column with electrochemical detection. The recovery, selectivity, linearity, precision and accuracy of the method were evaluated from spiked human plasma samples. The effects of mobile phase composition, buffer concentration, mobile phase pH and concentration of organic modifiers on retention of 5-ASA, acetyl 5-ASA and internal standard were investigated. Limits' of detection were 5 ng/mL for 5-ASA and 10 ng/mL for acetyl-5-ASA, respectively. The method can be used for supporting therapeutical drug monitoring and pharmacokinetic studies.     

Pharmacokinetics and excretion study of bergenin and its phase II metabolite in rats by liquid chromatography tandem mass spectrometry

A sensitive and selective liquid chromatographic–tandem mass spectrometric (LC–MS/MS) method for the determination of bergenin and its phase II metabolite in rat plasma, bile and urine has been developed. Biological samples were pretreated with protein precipitation extraction procedure and enzymatic hydrolysis method was used for converting glucuronide metabolite to its free form bergenin. Detection and quantitation were performed by MS/MS using electrospray ionization and multiple reaction monitoring. Negative electrospray ionization was employed as the ionization source. Sulfamethoxazole was used as the internal standard. The separation was performed on a reverse‐phase C₁₈ (250 × 4.6 mm, 5 μm) column with gradient elution consisting of methanol and 0.5% aqueous formic acid. The concentrations of bergenin in all biological samples were in accordance with the requirements of validation of the method. After oral administration of 12 mg/kg of the prototype drug, bergenin and its glucuronide metabolite were determined in plasma, bile and urine. Bergenin in bile was completely excreted in 24 h, and the main excreted amount of bergenin was 97.67% in the first 12 h. The drug recovery in bile within 24 h was 8.97%. In urine, the main excreted amount of bergenin was 95.69% in the first 24 h, and the drug recovery within 24 h was <22.34%. Total recovery of bergenin and its glucuronide metabolite was about 52.51% (20.31% in bile within 24 h, 32.20% in urine within 48 h). The validated method was successfully applied to pharmacokinetic and excretion studies of bergenin.     

Determination of p-methylthiobenzamide and p-methylthiobenzamide-S-oxide from rat plasma using solid-phase extraction and high-performance liquid chromatography

p-Methylthiobenzamide (PMTB) is a thiocarbonyl compound exhibiting marked hepatotoxicity and nephrotoxicity. We describe a high-performance liquid chromatographic method for analyzing PMTB and a metabolite, p-methylthiobenzamide-S-oxide (PMTBSO), from rat plasma using a solid-phase extraction technique. In this way, PMTB and PMTBSO can be extracted from 0.5 ml of plasma and separation achieved by an ODS analytical column in as little as 9 min. The mobile phase used was methanol-water (55:45, v/v) and the wavelength for detection was 290 nm. The limits of detection in plasma were 15 ng/ml for PMTB and 33 ng/ml for PMTBSO; the absolute recovery from spiked plasma samples was greater than 84.4% for both compounds and the internal standard. The method was linear throughout the range used with correlation coefficients greater than 0.969. The intra-day accuracy ranged from 1.52 to 15.23% relative error for the PMTB concentration range 151-3025 ng/ml; accuracy of 4.97% or less was obtained for PMTBSO concentrations of 1672-20,068 ng/ml. The intra-day precision (coefficient of variation) of the procedure was found to be no greater than 5.28% for PMTB and 7.9% for PMTBSO. Inter-day accuracy and precision measurements were similar.     

A sensitive, rapid and specific determination of midazolam in human plasma and saliva by liquid chromatography/electrospray mass spectrometry

A rapid, sensitive and selective liquid chromatography/electrospray mass spectrometry (LC/ES-MS) method was developed for the quantitative determination of the anaesthetic benzodiazepine midazolam (MID) in human saliva and plasma from patients undergoing anesthesia procedures. Biological samples spiked with diazepam-d5, the internal standard, were extracted into diethyl ether. Compounds were separated on a Xterra RP18 column using a mobile phase of acetonitrile/formic acid 0.1% at a flow rate of 0.25 mL/min under a linear gradient. Column effluents were analyzed using MS with an ES source in the positive ionization mode. Calibration curves were linear in the concentration ranges of 1-250 and 0.2-25 ng/mL in plasma and saliva, respectively. The limits of detection were 0.5 ng/mL in plasma and 0.1 ng/mL in saliva, using a 0.5-mL sample volume. The recoveries of the spiked samples were above 65%. The method was applied to ten real samples from patients undergoing midazolam treatment.     

Determination of aniracetam and its main metabolite, N-anisoyl-GABA, in human plasma by high-performance liquid chromatography

Two different reversed-phase high-performance liquid chromatographic methods for the determination of aniracetam (I) and its metabolite N-anisoyl-GABA (II) in human plasma are described. The procedure for I involves direct injection of plasma samples spiked with the internal standard on a clean-up column followed by reversed-phase chromatography on a C18 column. The limit of quantification was 5 ng/ml, using a 200-microliters specimen of plasma. The mean inter-assay precision of the method up to 800 ng/ml was 3%. The procedure for II involved liquid-liquid extraction of II and the internal standard from plasma with ethyl acetate, and reversed-phase chromatography on a C18 column. The limit of quantification was 50 ng/ml using a 0.5-ml plasma specimen. The mean inter-assay precision up to 50 micrograms/ml was 6%. The applicability and accuracy of the methods were demonstrated by the analysis of over 1000 plasma samples from two bioavailability studies in healthy volunteers.     

Liquid Chromatographic Assay for Amodiaquine in Tablets and Biological Fluids

Abstract

A high performance liquid chromatographic assay for quantitating amodiaquine (A) in tablets, urine, plasma, bile and saliva is described. The method involved acid extraction of the drug from tablets and chloroform extraction of its base from the biological fluids after alkalinization with ammonia. Quinidine was used as the internal standard. A μ-Bondapak phenyl column was used for separation together with a mobile phase made of methanol, water and glacial acetic acid (pH 2.3). Good chromatograms with efficient separation of drug and internal standard peaks were observed. Retention times of 5.2 and 7.1 min. were obtained for the drug and the internal standard respectively. Correlation between areas under the curve and drug concentration was high. The mean percentage recovery of A from tablets was 102.03%, while from the biological fluids, it ranged from 85.2 to 104.61%. Urine and saliva obtained from volunteers and bile obtained from animals administering amodiaquine showed chromatograms similar to those obtained for blank samples spiked with A. Interference from table't excipients of biological fluids was undetectable or negligible. The method was found to be precise and simple.     

Validated and optimized high-performance liquid chromatographic determination of tizoxanide, the main active metabolite of nitazoxanide in human urine, plasma and breast milk

A high-performance liquid chromatographic method was optimized and validated for the determination of desacetyl nitazoxanide (tizoxanide), the main active metabolite of nitazoxanide in human plasma, urine and breast milk. The proposed method used a CN column with mobile phase consisting of acetonitrile-12mM ammonium acetate-diethylamine in the ratio of 30:70:0.1 (v/v/v) and buffered at pH 4.0 with acetic acid, with a flow rate of 1.5 mL/min. Quantitation was achieved with UV detection at 260 nm using nifuroxazide as internal standard. A simplified direct injection of urine samples without extraction in addition to the urinary excretion pattern were calculated using the proposed method. Also, the effectiveness of protein precipitation and a clean-up procedure were investigated for biological plasma and human breast milk samples. The validation study of the proposed method was successfully carried out in an assay range between 0.2 and 20 μg/mL.     

Optimization via experimental design of an SPE-HPLC-UV-fluorescence method for the determination of valsartan and its metabolite in human plasma samples

A chemometric approach was applied for the optimization of the extraction and separation of the antihypertensive drug valsartan and its metabolite valeryl-4-hydroxy-valsartan from human plasma samples. Due to the high number of experimental and response variables to be studied, fractional factorial design (FFD) and central composite design (CCD) were used to optimize the HPLC-UV-fluorescence method. First, the significant variables were chosen with the help of FFD; then, a CCD was run to obtain the optimal values for the significant variables. The measured responses were the corrected areas of the two analytes and the resolution between the chromatographic peaks. Separation of valsartan, its metabolite valeryl-4-hydroxy-valsartan and candesartan M1, used as internal standard, was made using an Atlantis dC18 100 mm x 3.9 mm id, 100 angstroms, 3 microm chromatographic column. The mobile phase was run in gradient elution mode and consisted of ACN with 0.025% TFA and a 5 mM phosphate buffer with 0.025% TFA at pH 2.5. The initial percentage of ACN was 32% with a stepness of 4.5%/min to reach the 50%. A flow rate of 1.30 mL/min was applied throughout the chromatographic run, and the column temperature was kept to 40+/-0.2 degrees C. In the SPE procedure, experimental design was also used in order at achieve a maximum recovery percentage and extracts free from plasma interferences. The extraction procedure for spiked human plasma samples was carried out using C8 cartridges, phosphate buffer (pH 2, 60 mM) as conditioning agent, a washing step with methanol-phosphate buffer (40:60 v/v), a drying step of 8 min, and diethyl ether as eluent. The SPE-HPLC-UV-fluorescence method developed allowed the separation and quantitation of valsartan and its metabolite from human plasma samples with an adequate resolution and a total analysis time of 1 h.     

Quantification of trandolapril and its metabolite trandolaprilat in human plasma by liquid chromatography/tandem mass spectrometry using solid-phase extraction

A sensitive high-performance liquid chromatography/electrospray ionization tandem mass spectrometry (MS/MS) method was developed and validated for the simultaneous quantification of trandolapril and its metabolite trandolaprilat in human plasma using ramipril as an internal standard. Following solid-phase extraction, the analytes were separated using an isocratic mobile phase on a reversed-phase column and analyzed by MS/MS in the multiple reaction monitoring mode using the respective [M-H]- ions, m/z 429/168 for trandolapril, m/z 401/168 for trandolaprilat and m/z 415/166 for the internal standard. The method exhibited a linear dynamic range of 20-10,000 pg/mL for both trandolapril and trandolaprilat in human plasma. The lower limit of quantification was 20 pg/mL for both trandolapril and its metabolite. Acceptable precision and accuracy were obtained for concentrations over the standard curve range. A run time of 2.0 min for each sample made it possible to analyze more than 400 human plasma samples per day. The validated method has been successfully used to analyze human plasma samples for application in pharmacokinetic, bioavailability or bioequivalence studies.     

Development and validation of a sensitive liquid chromatographic–tandem mass spectrometric method for the simultaneous analysis of granisetron and 7‐hydroxy granisetron in human plasma and urine samples: application in a clinical pharmacokinetic study in pregnant subject

A liquid chromatography–tandem mass spectrometric method for the quantification of granisetron and its major metabolite, 7‐hydroxy granisetron in human plasma and urine samples was developed and validated. Respective stable isotopically labeled granisetron and 7‐hydroxy granisetron were used as internal standards (IS). Chromatography was performed using an Xselect HSS T3 analytical column with a mobile phase of 20% acetonitrile in water (containing 0.2 mM ammonium formate and 0.14% formic acid, pH 4) delivered in an isocratic mode. Tandem mass spectrometry operating in positive electrospray ionization mode with multiple reaction monitoring was used for quantification. The standard curves were linear in the concentration ranges of 0.5–100 ng/mL for granisetron and 0.1–100 ng/mL for 7‐hydroxy granisetron in human plasma samples, and 2–2000 ng/mL for granisetron and 2–1000 ng/mL for 7‐hydroxy granisetron in human urine samples, respectively. The accuracies were >85% and the precision as determined by the coefficient of variations was <10%. No significant matrix effects were observed for granisetron or 7‐hydroxy granisetron in either plasma or urine samples. Granisetron was stable under various storage and experimental conditions. This validated method was successfully applied to a pharmacokinetic study after intravenous administration of 1 mg granisetron to a pregnant subject. Copyright © 2015 John Wiley & Sons, Ltd.     

Determination of proquazone and its m-hydroxy metabolite by high-performance liquid chromatography. Clinical application: pharmacokinetics of proquazone in children with juvenile rheumatoid arthritis

A method for the determination of proquazone and its m-hydroxy metabolite in serum and urine by reversed-phase high-performance liquid chromatography is described. The technique is based on a single extraction of the unchanged drug, its metabolite and an internal standard from serum or urine with chloroform. The column was packed with mu Bondapak C18 and the mobile phase was acetonitrile--water (50:50) (pH 3). The detection limits for proquazone and its metabolite were 0.02 mumol/l using 500 microliters of sample. For the determination of the total m-hydroxy metabolite only 100 microliters of sample are needed. The method described is suitable for routine clinical and pharmacokinetic studies. The clinical application of this method suggests that the pharmacokinetics of proquazone in adults and children are similar.     

Determination of malotilate and its metabolites in plasma and urine

A method for the determination of malotilate (I), the corresponding monocarboxylic acid (II) and its decarboxylated product (III) in plasma is described. Plasma was extracted with chloroform spiked with internal standard. The residue, dissolved in methanol, was chromatographed on a reversed-phase column with a mobile phase of 60% acetonitrile and 1% acetic acid in water. The sensitivity limit for I, II and III was 50, 25 and 100 ng/ml of plasma, respectively. Compound I in the same plasma extract was also analysed by gas chromatography--electron-impact mass spectrometry. The base peaks m/z 160 for I and m/z 162 for internal standard (IV) were monitored; the sensitivity limit for I was 2.5 ng/ml of plasma. The determination of the metabolites of I, II and its conjugate (V), and isopropyl-hydrogen malonate (VI) in urine by high-performance liquid chromatography is also described. The limit of quantification for VI was 2.0 micrograms/ml, and the overall coefficient of variation of VI was 4.7%. The limit of quantification for II in urine was 0.5 micrograms/ml and that for V was 1.0 micrograms/ml as total II (II + V). The overall precision of the method was satisfactory. The method was used to determine plasma and urine concentrations in four dogs orally dosed with 100, 200 or 400 mg of malotilate.     

Automated determination of verapamil and norverapamil in human plasma with on-line coupling of dialysis to high-performance liquid chromatography and fluorometric detection

A fully automated method for the simultaneous determination of verapamil and its main metabolite norverapamil in human plasma is described. This method is based on on-line sample preparation using dialysis followed by clean-up and enrichment of the dialysate on a precolumn and subsequent HPLC analysis with fluorometric detection. All sample handling operations were performed automatically by a sample processor equipped with a robotic arm (ASTED system). The plasma samples were dialysed on a cellulose acetate membrane (cut-off: 15 kD) and the dialysate was purified and enriched on a short pre-column filled with cyanopropyl silica. Before starting dialysis, this trace enrichment column (TEC) was first conditioned with the HPLC mobile phase and then with pH 3.0 acetate buffer. 370 μl of plasma sample spiked with the internal standard (gallopamil) were dialysed in the static-pulsed mode. The solution at the donor side was pH 3.0 acetate buffer containing Triton X-100 while the acceptor solution was made of the same acetate buffer. When dialysis was discontinued, the analytes were desorbed from the TEC by the HPLC mobile phase and transferred to the C₁₈ analytical column by means of a switching valve. This mobile phase consisted of a mixture of acetonitrile, pH 3.0 acetate buffer and 2-aminoheptane. The influence of different parameters of the dialysis process on the recovery of verapamil and norverapamil has been studied. The effect of the volume, the aspirating and dispensing flow-rates of the dialysis solution has been investigated. The recoveries of verapamil and norverapamil in plasma were close to 75% and the limits of quantification were 5 ng/ml for both analytes. The method was found to be linear in the concentration range from 5 to 500 ng/ml (r²: 0.9996 for both analytes). The intra-day and inter-day reproducibilities at a concentration of 100 ng/ml were 2.3% and 5.6% for verapamil and 1.7% and 5.1% for norverapamil, respectively.     

Simultaneous determination of phenolphthalein and phenolphthalein glucuronide from dog serum, urine and bile by high-performance liquid chromatography.

A procedure is described to simultaneously quantitate phenolphthalein and its glucuronide metabolite from dog serum, urine and bile using high-performance liquid chromatography. The major advantages of this over pre-existing methods include direct analysis of the parent compound and glucuronide metabolite without enzymatic hydrolysis, increased sensitivity and the potential for automation of a large number of samples. Analytes were extracted from serum and urine using a combination of liquid- and solid-phase extraction methodology. Bile samples were analyzed directly after a twenty-fold dilution with mobile phase. The components plus internal standard were separated by reversed-phase high-performance liquid chromatography using step gradient elution and quantitated by the absorbance of ultraviolet light at 230 nm. Limits of detection from 1 ml of serum, 0.1 ml of urine and 0.05 ml of bile were 0.1, 0.5 and 10 microgram/ml for phenolphthalein and 0.1, 10 and 50 microgram/ml for phenolphthalein glucuronide, respectively.     

Stereospecific high-performance liquid chromatographic assay of pirprofen enantiomers in rat plasma and urine.

A stereospecific high-performance liquid chromatographic method was developed for the assay of pirprofen enantiomers in rat plasma and urine. Following addition of internal standard (ketoprofen) and acidifier (L-ascorbic acid) to biological fluids, pirprofen was extracted into an isopropanol-isooctane (5:95) mixture. Diastereomers of pirprofen enantiomers, which were formed using L-leucinamide, were separated on a reversed-phase column with ultraviolet detection at 275 nm using 0.06 M KH2PO4-acetonitrile-triethylamine (64:36:0.1) as mobile phase. The limit of quantitation was 0.1 microgram/ml for each enantiomer, based on 100 microliters of rat plasma. No spontaneous oxidation of pirprofen to its pyrrole metabolite occurred during sample preparation and analysis. In three female rats which were dosed with 10 mg/kg racemic pirprofen orally, plasma concentrations of the enantiomers could be followed for 24 h. Pirprofen enantiomers in plasma were virtually unconjugated, and negligible concentrations of pyrrole metabolites were observed. Less than 10% of the total dose was recovered in urine as intact drug and its glucuroconjugates. The assay was found suitable for the study of the pharmacokinetics of pirprofen enantiomers in the rat.