Simpler and faster quartz crystal microbalance for macromolecule detection using fixed frequency drive.

Despite advancements in analytical technologies, their complexity and cost have largely restricted their application in scalable online or multiplexed measurements. Here we report a quartz crystal resonator (QCR)-based method for detection of macromolecules that allows immensely simpler and faster measurements by employing for the first time a fixed frequency drive (FFD) and analytical expressions of acoustic parameters. Using human immunoglobulin E (hIgE) as an exemplar macromolecule and an anti-hIgE aptamer functionalised on a QCR, quantitative accuracy was benchmarked against the traditional impedance analysis method. The ability of FFD to capture data over longer observation periods at significantly higher acquisition rates at a fixed amplitude showed improvement in the QCR's sensitivity and specificity of transduction. The foundations for low-cost and low-power online integration and large-scale multiplexability are also discussed. • Analytical expressions for acoustic shift measurement. • Simpler quartz crystal microbalance (QCM) using a fixed frequency drive. • Ultrafast QCM with sub-millisecond time resolution. • Ultralow baseline noise, higher transduction sensitivity and specificity. • Promising for online integration and large-scale multiplexability. [ABSTRACT FROM AUTHOR]