High-Throughput Validated Method for the Quantitation of Busulfan in Plasma Using Ultrafast SPE-MS/MS.

BACKGROUND: Busulfan is an alkylating agent used to ablate bone marrow cells before hematopoietic stem cell transplantation. Because of its highly variable pharmacokinetics, studies have shown that therapeutic drug monitoring is clinically useful for patients undergoing bone marrow transplant so that toxic effects associated with high drug exposure could be reduced and improve clinical outcomes. Current methods for assaying busulfan include the use of gas chromatography mass spectrometry (GC/MS), high-performance liquid chromatography, and liquid chromatography mass spectrometry. The clinical need for faster turnaround times and increased testing volumes has required laboratories to develop faster methods of analysis for higher throughput of samples. Therefore, we present a method for the quantification of busulfan in plasma using an ultrafast solid-phase extraction/tandem mass spectrometry, which has much faster sample cycle times and similar analytical results to GC/MS. METHOD: Calibration standards, quality controls, and patient samples after addition of busulfan-d4 internal standard were extracted into n-butyl chloride from plasma. The organic fraction was dried and reconstituted in 600 µL of water containing ammonium acetate, trifluoroacetic acid, and formic acid. Sample analysis was performed at a rate of less than 20 seconds per sample using a Rapidfire 300 system coupled to an Agilent 6490 MS/MS using electrospray ionization in positive ion mode. Concentrations were calculated based on a 5-point calibration curve using a 1/x linear curve fit. RESULTS: The analytical method shows excellent precision, sensitivity, and specificity. Minimal ion suppression or enhancement due to the matrix effect was observed. No significant carryover was seen following a sample containing 15,000 ng/mL of busulfan. Seventy-two patient samples were cross-validated with a current GC/MS method. All patient results throughout the analytical range correlated within the acceptance criteria of ±20%. The linear regression demonstrated the following: slope = 1.0067, r = 0.9964, and intercept = -6.2. CONCLUSIONS: A simple, fast, and robust method was developed for the quantitation of busulfan in plasma with solid-phase extraction/tandem mass spectrometry cycle times of <20 seconds per sample.

Simultaneous analysis of nicotine, nicotine metabolites, and tobacco alkaloids in serum or urine by tandem mass spectrometry, with clinically relevant metabolic profiles.

BACKGROUND: Assessment of nicotine metabolism and disposition has become an integral part of nicotine dependency treatment programs. Serum nicotine concentrations or urine cotinine concentrations can be used to guide nicotine patch dose to achieve biological concentrations adequate to provide the patient with immediate relief from nicotine withdrawal symptoms, an important factor in nicotine withdrawal success. Absence of nicotine metabolites and anabasine can be used to document abstinence from tobacco products, an indicator of treatment success. METHODS: The procedure was designed to quantify nicotine, cotinine, trans-3'-hydroxycotinine, anabasine, and nornicotine in human serum or urine. The technique required simple extraction of the sample with quantification by HPLC-tandem mass spectrometry. RESULTS: The procedure for simultaneous analysis of nicotine, its metabolites, and tobacco alkaloids simultaneously quantified five different analytes. Test limit of quantification, linearity, imprecision, and accuracy were adequate for clinical evaluation of patients undergoing treatment for tobacco dependency. The test readily distinguished individuals who had no exposure to tobacco products from individuals who were either passively exposed or were abstinent past-tobacco users from those who were actively using a tobacco or nicotine product. CONCLUSIONS: Nicotine, cotinine, trans-3'-hydroxycotinine, nornicotine, and anabasine can be simultaneously and accurately quantified in either serum or urine by HPLC-tandem mass spectrometry with imprecision <10% at physiologic concentrations and limits of quantification ranging from 0.5 to 5 micro g/L. Knowledge of serum or urine concentrations of these analytes can be used to guide nicotine replacement therapy or to assess tobacco abstinence in nicotine dependency treatment. These measurements are now an integral part of the clinical treatment and management of patients who wish to overcome tobacco dependence.