An optimization strategy for charged aerosol detection to linearize the detector response in the multicomponent quantitative analysis of Qishen Yiqi dripping pills

Wu, Linlin; Gong, Xingchu; Qu, Haibin

doi:10.1002/jssc.202300784

J of Separation Science

2024

DOI: 10.1002/jssc.202300784

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An optimization strategy for charged aerosol detection to linearize the detector response in the multicomponent quantitative analysis of Qishen Yiqi dripping pills

Linlin Wu,

Xingchu Gong,

Haibin Qu

Abstract: Charged aerosol detection, increasingly recognized for quantifying pharmaceutical compounds with weak ultraviolet absorption, is a universal detection technique for high‐performance liquid chromatography (HPLC). Charged aerosol detection shows a non‐linear response with increasing analyte concentration over a wide range, limiting its versatility in various analytical applications. In this work, a co‐optimization strategy for power function value (PFV) and power laws was proposed and applied to broaden the line… Show more

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Cited by 3 publications

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Investigational Study of Mesalamine Dissolution Discrepancy: Utilization of Hyphenated Ultrahigh Performance Liquid Chromatography‐Charged Aerosol Detection‐High‐Resolution Mass Spectrometry

Kumar,

Vakkala,

Ganesan

et al. 2024

Separation Science Plus

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Pentasa (mesalamine/MSLM) is a widely prescribed delayed‐release capsule formulation for the treatment of inflammatory bowel disease. During dissolution study of Pentasa through ultraviolet (UV) spectroscopy, an unusual end‐release of about 110% has been observed. Initial liquid chromatography‐UV (LC‐UV) analyses of these dissolution samples confirmed three prominent peaks other than MSLM with a significant area percentage. Further systematic investigation was carried out by incubating active pharmaceutical ingredient in dissolution media for a longer duration and at elevated temperature followed by analysis through an inverse gradient LC‐charged aerosol detector (CAD). LC–high‐resolution mass spectrometry (HRMS) and online hydrogen‐deuterium exchange (HDX) mass spectrometry were also employed to identify and characterize these artifact products. The area % of prominent artifacts in LC‐UV was found to be way significant when compared to the area % obtained through inverse LC‐CAD, as CAD quantifies the peaks independent of the UV wavelength of absorbance. Inverse LC‐CAD was suitable to determine the relative response factor, whereas LC‐HRMS/MS and online HDX‐MS supported the characterization of these artifacts. These artifacts were found to be trimers, tetramers of MSLM formed due to polymerization, imparting additional pi‐bonds resulting in high UV absorptivity. These techniques when used in combinations serve complimentary to each other during such investigations.

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Investigational Study of Mesalamine Dissolution Discrepancy: Utilization of Hyphenated Ultrahigh Performance Liquid Chromatography‐Charged Aerosol Detection‐High‐Resolution Mass Spectrometry

Kumar,

Vakkala,

Ganesan

et al. 2024

Separation Science Plus

View full text Add to dashboard Cite

show abstract

A simplified tutorial on charged aerosol detection: Understanding the basics, optimization, and troubleshooting

Barnhart,

Farooq,

Ahmad

2024

Journal of Chromatography Open

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Role of the Power Function Value in Linearity and Universality for Charged Aerosol Detectors: Theoretical Elucidations from a Validated Model

Handlovic,

Roy,

Barnhart

et al. 2024

Anal. Chem.

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High-throughput drug discovery on the microgram scale is now common, making analyte quantitation without molecule-specific calibration imperative. The charged aerosol detector (CAD) was invented to be a next-generation universal liquid chromatography (LC) detector with excellent response universality for nonvolatile analytes as well as sensitivity for nonchromophoric compounds. Although the CAD is a mass flowsensitive detector, its response to mass is inherently nonlinear, which challenges traditional quantitation. In CAD software, there is a "power function value" (p) setting that can be used to linearize the signal through digital signal processing. The exact workings of this power function value algorithm remain unknown; however, its optimization is a crucial aspect of analytical method development for LC-CAD. Herein, we developed a theoretical relationship that can be used to predict the chromatogram (plus peak area, width, and height) at any p if the data are collected at p = 1. This model was validated using a diverse dataset comprising 1440 measurements including peak heights, areas, and widths. Predicted areas had an average error of less than 2% showing excellent agreement between calculated and experimental results. An open-access automated code is tested and provided, which predicts the power function value that produces the most linear response. It is vital to note that optimizing the power function value affects peaks of different heights disproportionately. Low-level impurities were shown to be minimized and eventually eliminated by increasing the power function value. This model provides an easy-to-implement tool (MATLAB or Excel) that assists in choosing the optimal p for each LC-CAD method, increasing the speed of method development and improving the accuracy of quantitative workflows.

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An optimization strategy for charged aerosol detection to linearize the detector response in the multicomponent quantitative analysis of Qishen Yiqi dripping pills

Cited by 3 publications

References 18 publications

Investigational Study of Mesalamine Dissolution Discrepancy: Utilization of Hyphenated Ultrahigh Performance Liquid Chromatography‐Charged Aerosol Detection‐High‐Resolution Mass Spectrometry

Investigational Study of Mesalamine Dissolution Discrepancy: Utilization of Hyphenated Ultrahigh Performance Liquid Chromatography‐Charged Aerosol Detection‐High‐Resolution Mass Spectrometry

A simplified tutorial on charged aerosol detection: Understanding the basics, optimization, and troubleshooting

Role of the Power Function Value in Linearity and Universality for Charged Aerosol Detectors: Theoretical Elucidations from a Validated Model

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