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Abstract
Robust high-throughput screening (HTS) approaches to discover new chemical entities are desirable for research and translation. Applications where high-throughput (HT) methods are particularly demanded also include the screening of potential therapeutics for drug discovery and development, profiling of biofluids for disease biomarker discovery, and clinical diagnostics. Complementing the demand for HTS from specific application areas are substantial technological advancements in the fields of automation, microfluidics and ambient ionisation that facilitate highly automated and sophisticated analytical workflows. The time period spanning 2000-2025 has witnessed a significant expansion in mass spectrometry (MS) capabilities and technology. This has included novel ionisation approaches that can achieve rapid analysis with minimal solvent and sample consumption, whilst retaining high sensitivity and specificity in the absence of chromatography. Despite the demand for HTS methods and the well-documented analytical capabilities of MS, optical methods dominate as HTS detection methods of choice. This perspective provides an overview of the evolution of HTS-MS over the last 25 years, focusing on emerging approaches which also provide efficient and sustainable workflows that compete with optical detection. Additionally, this perspective will highlight challenges to the field that may hinder widespread adoption and consider lessons from the COVID-19 pandemic as well as the drive towards sustainability’s impact of the future of HTS-MS and analytical chemistry.
