Abstract 5496: From transcripts to cells: Dissecting sensitivity, signal contamination, and specificity in Xenium spatial transcriptomics.

Abstract Understanding cell states and interactions within tumors requires accurate spatial gene measurements. Spatial transcriptomics provides this capability by mapping gene expression directly within intact tissue, offering a powerful framework for studying tumor ecosystems. The purpose of this study was to systematically evaluate the performance of the Xenium platform in cancer samples and to develop an improved strategy for refining cell-level signals.We generated one of the largest Xenium datasets to date, comprising 41 breast and lung tumor sections from 27 donors and profiled using multiple targeted panels as well as the newer 5K panel. Using matched snRNA-seq, we assessed assay specificity, panel performance, segmentation strategies, and the prevalence of transcript spillover—a major source of technical variability in densely intermixed tumor ecosystems.We found that broader panel content increases biological coverage but reduces per-gene sensitivity. We further show that transcript spillover from adjacent cells significantly affects signal specificity, producing mixed profiles that obscure critical immune programs in cancer tissues. Building on these insights, we developed SPLIT (Spatial Purification of Layered Intracellular Transcripts), a method that combines snRNA-seq with deconvolution to correct spillover and recover cleaner cell-type signatures. SPLIT improved background correction, enhanced cell-type resolution, and revealed features such as T-cell exhaustion linked to local tumor-immune proximity that were not detectable using raw, contaminated data.In conclusion, our study provides a comprehensive performance assessment of Xenium in cancer contexts and introduces a scalable and interpretable approach for signal refinement, enabling more reliable inference of cellular programs and interactions within the tumor microenvironment. This dataset and methodology offer an important resource for designing, benchmarking, and interpreting spatial transcriptomics studies in cancer. Citation Format: Mariia Bilous, Daria Buszta, Jonathan Bac, Senbai Kang, Yixing Dong, Stephanie Renaud-Tissot, Sylvie Andre, Marina Alexandre-Gaveta, Christel Voize, Solange Peters, Krisztian Homicsko, Raphael Gottardo. From transcripts to cells: Dissecting sensitivity, signal contamination, and specificity in Xenium spatial transcriptomics abstract. In: Proceedings of the American Association for Cancer Research Annual Meeting 2026; Part 1 (Regular Abstracts); 2026 Apr 17-22; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2026;86(7 Suppl):Abstract nr 5496.