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Abstract INTRODUCTION:
Formalin-fixed paraffin-embedded (FFPE) tissues are essential clinical resources, yet conventional deparaffinization methods are slow, laborious, and environmentally unfriendly, relying heavily on toxic solvents. Addressing these limitations, we introduce HistoProbe, a novel microfluidic platform enabling rapid, localized, and minimally solvent-dependent analysis and imaging of FFPE tissues by mass spectrometry (MS).
METHODS:
HistoProbe integrates a modified liquid microjunction surface sampling probe (LMJ-SSP) with precise thermal regulation adapted from 3D printer hardware. The platform operates in two distinct modes: Online and Offline. Online-HistoProbe enables direct metabolite extraction and real-time analysis from FFPE tissue sections at elevated temperatures (~60 °C) without any prior sample preparation or deparaffinization. It functions as a standalone tool by interfacing directly with the electrospray ionization (ESI) source of the mass spectrometer, offering a plug-and-play solution for rapid FFPE tissue analysis. Offline-HistoProbe enables targeted thermal deparaffinization using reduced volumes of solvents (i.e., ethyl acetate, toluene, or xylene) at controlled temperatures (up to 75 °C). This mode drastically lowers solvent usage compared to standard protocols while maintaining compatibility with high-resolution imaging. Both modes were coupled with desorption electrospray ionization mass spectrometry (DESI-MS) for metabolic profiling and hyperspectral molecular imaging. Data were analyzed using principal component analysis (PCA) for dimensionality reduction and unsupervised clustering of metabolic features.
RESULTS:
Optimization studies demonstrated that Online-HistoProbe eliminated the need for sample preparation and solvent use, reducing total analysis time to approximately 17 minutes per sample and enabling high-throughput analysis exceeding 80 samples per day. The practical spatial resolution of the online mode was approximately 1 millimeter, suitable for rapid tissue screening and metabolic profiling. Offline-HistoProbe, optimized with ethyl acetate at 75 °C, achieved comparable or superior metabolite recovery to traditional xylene-based deparaffinization, while reducing solvent consumption by over 99.5%. It supported a practical spatial resolution of 50–100 micrometers, allowing fine-grained molecular imaging. Both modes reliably distinguished neoplastic from non-neoplastic regions in melanoma FFPE tissues and enabled annotation of key biomolecules, including fatty acids, phosphatidylinositols, and oxidized lipids relevant to cancer metabolism.
CONCLUSION:
HistoProbe represents a significant advancement in mass spectrometry-based histopathology, combining speed, analytical precision, automation, and sustainability. Its dual-mode functionality addresses clinical demands by offering high-throughput direct analysis (Online mode) and high-resolution molecular imaging (Offline mode). HistoProbe substantially reduces solvent consumption, sample preparation time, and environmental impact, demonstrating immense potential for clinical diagnostics, biomarker discovery, and rapid intraoperative tissue assessments.
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= Discovery stage. (53.14%, 2025)
= Translation stage. (22.33%, 2025)
= Clinically available. (24.53%, 2025)
