Controlled ex-vivo plasma hydrolysis of valaciclovir to acyclovir demonstration using tandem mass spectrometry

ABSTRACT Plasma estimation of valaciclovir, an antiviral drug, is challenging due to both in‐vivo and ex‐vivo hydrolysis to active metabolite acyclovir. A simultaneous method is described involving the solid‐phase ion‐exchange extraction procedure requiring 100 μL of plasma volume, a reverse‐phase L...

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Veröffentlicht in:	Biomedical chromatography 2011-11, Vol.25 (11), p.1189-1200
Hauptverfasser:	Goswami, Dipanjan, Khuroo, Arshad, Gurule, Sanjay, Modhave, Yogesh, Monif, Tausif
Format:	Artikel
Sprache:	eng
Schlagworte:	Acyclovir - analogs & derivatives Acyclovir - blood Acyclovir - chemistry Acyclovir - metabolism Acyclovir - pharmacokinetics Chromatography, Liquid Drug Stability drug: active metabolite formation ratio Humans Hydrolysis LC-MS/MS Linear Models Male plasma stability Reproducibility of Results Sensitivity and Specificity simultaneous method development/validation Tandem Mass Spectrometry - methods valaciclovir controlled hydrolysis Valine - analogs & derivatives Valine - blood Valine - chemistry Valine - metabolism Valine - pharmacokinetics
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container_title	Biomedical chromatography
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creator	Goswami, Dipanjan Khuroo, Arshad Gurule, Sanjay Modhave, Yogesh Monif, Tausif
description	ABSTRACT Plasma estimation of valaciclovir, an antiviral drug, is challenging due to both in‐vivo and ex‐vivo hydrolysis to active metabolite acyclovir. A simultaneous method is described involving the solid‐phase ion‐exchange extraction procedure requiring 100 μL of plasma volume, a reverse‐phase Lichrosphere RP Select B (125 × 6 mm, 5 μm) column and isocratic mobile phase to achieve the desired chromatographic separation. ESI‐MS/MS multiple reaction monitoring in positive polarity, detected mass pairs for valaciclovir (m/z 325.5 → 152.2), acyclovir (m/z 226.3 → 152.2) and respective internal standards valganciclovir (m/z 307.1 → 220.3) and acyclovir‐d4 (m/z 230.2 → 152.0). Fully fledged method validation was evaluated as per current regulatory requirements and results were deemed acceptable. The plasma samples showed extensive hydrolysis of valaciclovir when collected or processed at room temperature, without buffer stabilization prior to storage at −15°C. Our results showed that using prechilled K3EDTA vacutainers immersed in an iced‐water bath during blood sample collection, and addition of 50% orthophosphoric acid solution to plasma samples prior to storage at −50°C for at least 120 days controlled the hydrolysis of valaciclovir to acyclovir. While monitoring drug absorption into systematic circulation, the valaciclovir to acyclovir formation ratio was improved to 1:20 in healthy volunteers for the first time. Copyright © 2011 John Wiley & Sons, Ltd.
doi_str_mv	10.1002/bmc.1590
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Our results showed that using prechilled K3EDTA vacutainers immersed in an iced‐water bath during blood sample collection, and addition of 50% orthophosphoric acid solution to plasma samples prior to storage at −50°C for at least 120 days controlled the hydrolysis of valaciclovir to acyclovir. While monitoring drug absorption into systematic circulation, the valaciclovir to acyclovir formation ratio was improved to 1:20 in healthy volunteers for the first time. 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Chromatogr</addtitle><description>ABSTRACT Plasma estimation of valaciclovir, an antiviral drug, is challenging due to both in‐vivo and ex‐vivo hydrolysis to active metabolite acyclovir. A simultaneous method is described involving the solid‐phase ion‐exchange extraction procedure requiring 100 μL of plasma volume, a reverse‐phase Lichrosphere RP Select B (125 × 6 mm, 5 μm) column and isocratic mobile phase to achieve the desired chromatographic separation. ESI‐MS/MS multiple reaction monitoring in positive polarity, detected mass pairs for valaciclovir (m/z 325.5 → 152.2), acyclovir (m/z 226.3 → 152.2) and respective internal standards valganciclovir (m/z 307.1 → 220.3) and acyclovir‐d4 (m/z 230.2 → 152.0). Fully fledged method validation was evaluated as per current regulatory requirements and results were deemed acceptable. The plasma samples showed extensive hydrolysis of valaciclovir when collected or processed at room temperature, without buffer stabilization prior to storage at −15°C. Our results showed that using prechilled K3EDTA vacutainers immersed in an iced‐water bath during blood sample collection, and addition of 50% orthophosphoric acid solution to plasma samples prior to storage at −50°C for at least 120 days controlled the hydrolysis of valaciclovir to acyclovir. While monitoring drug absorption into systematic circulation, the valaciclovir to acyclovir formation ratio was improved to 1:20 in healthy volunteers for the first time. 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subjects	Acyclovir - analogs & derivatives Acyclovir - blood Acyclovir - chemistry Acyclovir - metabolism Acyclovir - pharmacokinetics Chromatography, Liquid Drug Stability drug: active metabolite formation ratio Humans Hydrolysis LC-MS/MS Linear Models Male plasma stability Reproducibility of Results Sensitivity and Specificity simultaneous method development/validation Tandem Mass Spectrometry - methods valaciclovir controlled hydrolysis Valine - analogs & derivatives Valine - blood Valine - chemistry Valine - metabolism Valine - pharmacokinetics
title	Controlled ex-vivo plasma hydrolysis of valaciclovir to acyclovir demonstration using tandem mass spectrometry
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