分析物
多路复用
动态范围
再现性
生物标志物
检出限
计算机科学
生物系统
化学
色谱法
生物
电信
计算机视觉
生物化学
作者
Sharon Newman,Brandon D. Wilson,Daniel Mamerow,Benjamin Wollant,Hnin Yin Yin Nyein,Yael Rosenberg‐Hasson,Holden T. Maecker,Michael Eisenstein,H. Tom Soh
出处
期刊:
[Cold Spring Harbor Laboratory]
日期:2023-02-08
标识
DOI:10.1101/2023.02.07.527534
摘要
Abstract Precision medicine requires highly scalable methods of multiplexed biomarker quantification that can accurately describe patient physiology. Unfortunately, contemporary molecular detection methods are generally limited to a dynamic range of sensitivity spanning just 3–4 orders of magnitude, whereas the actual physiological dynamic range of the human plasma proteome spans more than 10 orders of magnitude. Current methods rely on sample splitting and differential dilution to compensate for this mismatch, but such measures greatly limit the reproducibility and scalability that can be achieved—in particular, the effects of non-linear dilution can greatly confound the analysis of multiplexed assays. We describe here a two- pronged strategy for equalizing the signal generated by each analyte in a multiplexed panel, thereby enabling simultaneous quantification of targets spanning a wide range of concentrations. We apply our ‘EVROS’ strategy to a proximity ligation assay and demonstrate simultaneous quantification of four analytes present at concentrations spanning from low femtomolar to mid-nanomolar levels. In this initial demonstration, we achieve a dynamic range spanning seven orders of magnitude in a single 5 µl sample of undiluted human serum, highlighting the opportunity to achieve sensitive, accurate detection of diverse analytes in a highly multiplexed fashion.
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