Simple dilute-and-shoot method for urinary vanillylmandelic acid and homovanillic acid by liquid chromatography tandem mass spectrometry.

BACKGROUND: Neuroblastomas are pediatric tumors characterized by overproduction of catecholamines. The catecholamine metabolites, vanillylmandelic acid (VMA) and homovanillic acid (HVA), are used in clinical evaluation of neuroblastoma. Tandem mass spectrometry (LC-MS/MS) is an effective analytical method for measurement of VMA and HVA in urine. METHODS: Dilute-and-shoot sample preparation was performed in a 96-well format using a liquid handler. Chromatographic separation was achieved using a reverse phase column; detection was accomplished by triple quadrupole mass spectrometry with electrospray ionization in positive mode. Data were acquired by multiple reaction monitoring. Two transitions, quantifier and qualifier, were monitored for each analyte and its stable isotope-labeled internal standard. Analytical specificity studies were performed. RESULTS: Injection-to-injection time was 4min. The method was validated for linearity, limit of quantification, imprecision, accuracy, and interference. Linearity was 0.5-100mg/l for both analytes. Within-run, between-day, and total imprecision were 1.0-4.1% for VMA and 0.8-3.8% for HVA. The method correlated well with our established HPLC method. Interferences precluding quantitation of VMA in 3% of specimens were reduced significantly (to 0.1% of specimens) using a modified LC gradient to reanalyze affected samples. CONCLUSIONS: A simple, robust, economical, fast LC-MS/MS method was developed and validated for measurement of urinary VMA and HVA.

Practical LC-MS/MS Method for 5-Hydroxyindoleacetic Acid in Urine.

BACKGROUND: Serotonin, an endogenous biogenic amine found in enterochromaffin cells of the gastrointestinal tract, is produced in excess by carcinoid tumors. The primary urinary metabolite of serotonin, 5-hydroxyindoleacetic acid (5-HIAA), is used in the diagnosis and management of carcinoid disease. This study describes the development and validation of a dilute-and-shoot LC-MS/MS method for the measurement of 5-HIAA in urine. METHODS: Samples were prepared by dilution in a 96-well format using an automated liquid handler. Chromatographic isolation of the analyte was achieved using a reversed-phase analytical column. A triple quadrupole mass spectrometer with electrospray ionization in positive mode was used for detection and quantification. Data were acquired by multiple reaction monitoring. Two transitions, quantifier (192.1/146.1) and qualifier (192.1/118.1), were monitored for the analyte and its stable isotope-labeled internal standard [5-hydroxyindole-4,6,7-d3-3-acetic-2,2-d2 acid (5-HIAA-d5)]. Chromatography was designed to elute the analyte outside of major suppression zones. RESULTS: Injection-to-injection time was 4 min. The method was validated for linearity, limit of quantification, accuracy, and imprecision. The analytical measurement range was 0.5-100 mg/L. Coefficients of variation for within-run, between-day, and total imprecision ranged from 0.8% to 5.4%. The method produced accurate 5-HIAA concentrations and correlated well (R = 0.9876) with a comparison HPLC method. Matrix effects were evaluated by post-column infusion of urine samples. An analytical specificity study of endogenous compounds, vitamins, medications, and drugs showed minimal interference. CONCLUSIONS: A simple, inexpensive LC-MS/MS method was developed for measurement of 5-HIAA in urine. Results from the assay can be used clinically to assess carcinoid tumors.

Development and implementation of an HPLC-ECD method for analysis of vitamin C in plasma using single column and automatic alternating dual column regeneration.

OBJECTIVES: Vitamin C (l-ascorbic acid) is a water-soluble micronutrient necessary for human life. Inadequate intake can lead to the fatal disease scurvy. Measurement of vitamin C is used to assess nutritional status and to monitor supplementation. The goal of this study was to develop a chromatographic method for the quantitation of vitamin C in human plasma. DESIGN AND METHODS: Samples were prepared by protein precipitation, addition of internal standard, and reduction with dithiothreitol. Separation of ascorbic acid was accomplished by isocratic elution on a reverse-phase column; concentration was determined by coulometry. The method was validated through studies of assay linearity, sensitivity, imprecision, accuracy, analytical specificity, and carryover. RESULTS: The new assay was developed using a single pump/single analytical column HPLC system. Results correlated well with our previously used spectrophotometric method. The analytical measurement range was 1.0-2500 µmol/L. The injection-to-injection time was 13 min. Subsequently, to increase method throughput and shorten turnaround time, a dual LC pump system with a 2-position/10-port switching valve capable of performing automatic alternating column regeneration was validated and implemented. The injection-to-injection time was reduced 2-fold to 6 min. The method was linear to 5000 µmol/L; limit of quantification was 1.9 µmol/L. Total imprecision was less than 5%. CONCLUSIONS: We have developed a robust method suitable for routine clinical measurement of vitamin C in plasma specimens. The method incorporates a simplified sample preparation and a stable, non-endogenous internal standard to specifically quantify vitamin C. Faster throughput was achieved by employing an automatic alternating column regeneration system.

Correction for isotopic interferences between analyte and internal standard in quantitative mass spectrometry by a nonlinear calibration function.

Stable isotope-labeled internal standards are of great utility in providing accurate quantitation in mass spectrometry (MS). An implicit assumption has been that there is no "cross talk" between signals of the internal standard and the target analyte. In some cases, however, naturally occurring isotopes of the analyte do contribute to the signal of the internal standard. This phenomenon becomes more pronounced for isotopically rich compounds, such as those containing sulfur, chlorine, or bromine, higher molecular weight compounds, and those at high analyte/internal standard concentration ratio. This can create nonlinear calibration behavior that may bias quantitative results. Here, we propose the use of a nonlinear but more accurate fitting of data for these situations that incorporates one or two constants determined experimentally for each analyte/internal standard combination and an adjustable calibration parameter. This fitting provides more accurate quantitation in MS-based assays where contributions from analyte to stable labeled internal standard signal exist. It can also correct for the reverse situation where an analyte is present in the internal standard as an impurity. The practical utility of this approach is described, and by using experimental data, the approach is compared to alternative fits.

Urinary metanephrines by liquid chromatography tandem mass spectrometry: using multiple quantification methods to minimize interferences in a high throughput method.

Determination of urinary metanephrines is requested frequently for the differential diagnosis and monitoring of pheochromocytoma. Although numerous methods have been developed, interferences are common and hinder most available assays. This study describes the development, validation and implementation of a reliable high-throughput LC-MS/MS method for the measurement of metanephrine and normetanephrine in urine. Metanephrine and normetanephrine were isolated from urine samples subjected to acid hydrolysis using solid phase extraction on a mixed mode cation exchange sorbent in 96-well format. The extracts were injected directly onto a Restek perfluorophenyl column and separated isocratically in 0.2% formic acid in 5% methanol with a gradient cleanout step to 50% methanol. Detection was accomplished using an API 3200 triple quadrupole mass spectrometer with electrospray ionization in positive mode. Data were acquired in multiple reaction monitoring mode. Three transitions were monitored for metanephrine and its deuterated internal standard; two transitions were monitored for normetanephrine and its deuterated internal standard. Two quantification methods were used to address metanephrine interferences without reducing throughput. The method was linear to 15,000 nmol/L. The limits of detection and quantification were 2.5 and 10 nmol/L, respectively. Within run, between-day and total imprecision values were at or below 1.9%, 2.5% and 2.7% for both analytes. The method correlated well with our previously used GC-MS method. Injection-to-injection time was 6 min. The validated LC-MS/MS method for measurement of metanephrine and normetanephrine in urine specimens was placed into service in August 2010 and has performed exceptionally well.