PO.BCS01.12 · 生物信息与计算
Resolving phenotyping discordance with SPACEMAP, an integrated machine learning framework
作者与单位
摘要 Abstract
Introduction and Purpose: Multiplex imaging provides powerful insight into cellular organization, yet the complexity of these datasets requires robust analytical tools to extract meaningful biological information. The purpose of this study was to develop a unified analytical framework enabling reliable, high-resolution characterization of the tissue microenvironments in multiplex images. To achieve this, we developed SPACEMAP (Spatial Phenotyping And Classification with Enhanced Multiplex Analysis Pipeline), a comprehensive Python and Qupath-based platform that integrates image registration, cell segmentation, quality check, artifact removal, tissue and zone classification, spatial feature extraction, and a consolidated phenotyping approach into a single workflow.
Methods: To determine an optimal cell-classification strategy, we benchmarked our phenotyping method, RESOLVE, against three established approaches, Leiden clustering, Self-Organizing Maps, and SCIMAP. This evaluation revealed substantial inconsistencies among existing methods. To address this, SPACEMAP incorporates two complementary workflows: (1) a machine learning model trained on expert-annotated cells, and (2) a consensus-based model that integrates high-confidence cell assignments across methods, enabling robust classification even when manual references are limited.
Summary: We applied SPACEMAP to newly generated multiplex imaging datasets from colorectal tissue samples and further evaluated performance using a publicly available dataset. These analyses demonstrate that SPACEMAP improves classification consistency, reduces variability introduced by method selection, and supports reproducible extraction of spatial features for further downstream analysis.
Conclusions: SPACEMAP provides a standardized, high-fidelity workflow for spatial phenotyping that minimizes reliance on labor-intensive manual annotation and improves reproducibility in multiplex imaging studies. Its design supports adaptation to evolving imaging technologies and marker panels, enabling researchers to more effectively investigate tissue organization and generate biologically meaningful insights.
利益披露 Disclosure
A. Perez Rodriguez, None..
B. Dawod, None..
S. Diegeler, None.
E. A. Elghonaimy,
ALPA Biosciences Stock.
M. Wachsmann, None..
P. Gopal, None..
D. Hein, None..
P. H. Acosta, None..
A. Jamieson, None..
G. Danuser, None..
R. Timmerman, None..
S. Rajaram, None.
T. A. Aguilera,
Novocure Other, Advisory Board.
Renovo Rx Travel.
Avelas Biosciences Stock.
ALPA Biosciences Other, Board of Directors, non-salaried role.