Bogusz Maciej J, Enazi Eid Al, Hassan Huda, Abdel-Jawaad Jamil, Ruwaily Jamal Al, Tufail Mohammed Al
King Faisal Specialist Hospital and Research Centre, 11211 Riyadh, Saudi Arabia.
J Chromatogr B Analyt Technol Biomed Life Sci. 2007 May 1;850(1-2):471-80. doi: 10.1016/j.jchromb.2006.12.048. Epub 2007 Jan 11.
The purpose of the study was to develop rapid and simple procedure for simultaneous determination of cyclosporine A (CsA), tacrolimus (TCR), and sirolimus (SIR) in whole blood and mycophenolic acid (MPA) in plasma. Ascomycin (ASCO), cyclosporine D (CsD), and desmethoxysirolimus (DMSIR) were used as internal standards (IS) for TCR, CsA and MPA, and SIR, respectively. In the method development, six-level blood calibrators were used for CsA (range 47-1725 ng/ml), TCR (range 2.1-38.8 ng/ml), and SIR (range 2.4-39.6 ng/ml). Four-level calibrators were used for MPA (range 0.15-5.48 microg/ml). Four levels of quality control (QC) standards were used for blood samples, together with two levels of QC standards in plasma. All QC standards and calibrators were obtained from commercial sources. Sample preparation based on precipitation of 50 microl of sample in zinc sulfate-methanol-acetonitrile mixture containing IS, followed by centrifugation. HPLC was performed on ChromSpher pi column, 30 mm x 3 mm, in ballistic gradient of ammonium formate buffer-methanol at 0.8 ml flow rate. Following gradient elution profile was applied: 0-1.2 min at 30% methanol (divert valve to waste), 1.21-3.1 min 97% methanol (divert valve to detector), 3.11-3.7 min 30% methanol (divert valve to waste). ESI-MS-MS (MRM) was done on TSQ Quantum instrument with ESI source in positive ion mode. Ammoniated adducts of protonated molecules were used as precursor ions for all analytes but MPA. For this compound sodium adduct was used. Following transitions were monitored: for CsA m/z 1220-1203; for CsD 1234-1217; for SIR 931.6-864.5 and 882.6; for DMSIR 902-834.5; for TCR 821.5-768.5 and 785.5; for ASCO 809.5-756; for MPA 343-211.6; for MPA-glucuronide 514-306 and 211.6. The limits of quantitation were: 1 ng/ml for TCR and SIR, 20 ng/ml for CsA, and 0.1 microg/ml for MPA. Post-column infusion experiments showed that no positive or negative peaks appeared after injection of matrix in the elution range of target compounds. General signal suppression caused by matrix ranged from 20-40%, and was caused mainly by zinc sulfate present in deproteinizing solution. Extracted samples were stable for 2 days at 4 degrees C and for at least 20 days at -20 degrees C. MPA was fully separated from its glucuronide, which was eluted at around 0.7-0.8 min and directed to the waste. Some mutual cross-contribution of CsD and CsA was observed (below 1%), other IS did not contribute to target compounds and vice versa. Observations of chromatograms from patients taken single therapy demonstrated that possible metabolites of CsA, TCR, or SIR did not interfere with target compounds or IS.
本研究的目的是开发一种快速简便的方法,用于同时测定全血中的环孢素A(CsA)、他克莫司(TCR)和西罗莫司(SIR)以及血浆中的霉酚酸(MPA)。分别将子囊霉素(ASCO)、环孢素D(CsD)和去甲氧基西罗莫司(DMSIR)用作TCR、CsA和MPA以及SIR的内标(IS)。在方法开发过程中,使用六级血液校准品测定CsA(范围为47 - 1725 ng/ml)、TCR(范围为2.1 - 38.8 ng/ml)和SIR(范围为2.4 - 39.6 ng/ml)。使用四级校准品测定MPA(范围为0.15 - 5.48 μg/ml)。血液样本使用四级质量控制(QC)标准品,血浆使用两级QC标准品。所有QC标准品和校准品均购自商业来源。基于在含有内标的硫酸锌 - 甲醇 - 乙腈混合物中沉淀50 μl样品,随后进行离心来制备样品。在ChromSpher pi柱(30 mm×3 mm)上进行HPLC,采用甲酸铵缓冲液 - 甲醇的快速梯度洗脱,流速为0.8 ml/min。应用以下梯度洗脱程序:0 - 1.2 min,甲醇含量30%(分流阀接至废液);1.21 - 3.1 min,甲醇含量97%(分流阀接至检测器);3.11 - 3.7 min,甲醇含量30%(分流阀接至废液)。在TSQ Quantum仪器上采用ESI源在正离子模式下进行ESI - MS - MS(MRM)分析。除MPA外,所有分析物均使用质子化分子的铵加合物作为前体离子。对于该化合物,使用钠加合物。监测以下跃迁:CsA的m/z 1220 - 1203;CsD的1234 - 1217;SIR的931.6 - 864.5和882.6;DMSIR的902 - 834.5;TCR的821.5 - 768.5和785.5;ASCO的809.5 - 756;MPA的343 - 211.6;MPA - 葡萄糖醛酸苷的514 - 306和211.6。定量限为:TCR和SIR为1 ng/ml,CsA为20 ng/ml,MPA为0.1 μg/ml。柱后注入实验表明,在目标化合物的洗脱范围内注入基质后未出现正峰或负峰。由基质引起的一般信号抑制范围为20% - 40%,主要是由去蛋白溶液中存在的硫酸锌导致的。提取后的样品在4℃下可稳定保存2天,在 - 20℃下至少可稳定保存20天。MPA与其葡萄糖醛酸苷完全分离,葡萄糖醛酸苷在约0.7 - 0.8 min洗脱并导向废液。观察到CsD和CsA之间存在一些相互交叉贡献(低于1%),其他内标对目标化合物无贡献,反之亦然。对接受单一治疗患者的色谱图观察表明,CsA、TCR或SIR的可能代谢物不会干扰目标化合物或内标。
