Living human lung slices for ex vivo modelling of lung cancer
Siavash Mansouri, Annika Karger, Clemens Ruppert, Marc A. Schneider, Andreas Weigert, Rajender Nandigama, Blerina Aliraj, Lisa Strotmann, Anoop V. Cherian, Diethard Pruefer, Peter Dorfmuller, Ludger Fink, Ibrahim Alkoudmani, Stefan Gattenlöhner, Bastian Eul, Andre Althoff, Peter Kleine, Hauke Winter, Andreas Guenther, Hossein-Ardeschir Ghofrani, Soni S. Pullamsetti, Friedrich Grimminger, Werner Seeger, Rajkumar Savai
Siavash Mansouri, Annika Karger, Clemens Ruppert, Marc A. Schneider, Andreas Weigert, Rajender Nandigama, Blerina Aliraj, Lisa Strotmann, Anoop V. Cherian, Diethard Pruefer, Peter Dorfmuller, Ludger Fink, Ibrahim Alkoudmani, Stefan Gattenlöhner, Bastian Eul, Andre Althoff, Peter Kleine, Hauke Winter, Andreas Guenther, Hossein-Ardeschir Ghofrani, Soni S. Pullamsetti, Friedrich Grimminger, Werner Seeger, Rajkumar Savai
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Research Article Immunology Oncology

Living human lung slices for ex vivo modelling of lung cancer

Abstract

The tumor microenvironment (TME) markedly affects cancer progression, yet traditional animal models do not fully recapitulate the situation in humans. To address this, we developed tumor-derived precision lung slices (TD-PCLS), an ex vivo platform for studying the lung TME and evaluating therapies. TD-PCLS, viable for 8–10 days, preserve the heterogeneity and metabolic activity of primary tumors, as confirmed by seahorse analysis. Using multispectral FACS and phenocycler multiplex imaging, we spatially profiled TME components and cancer cell functionality. Additionally, TD-PCLS revealed patient-specific responses to chemo- and immunotherapies. To complement TD-PCLS, we established tumor-cell–seeded PCLS (TCS-PCLS) by introducing tumor and immune cells into healthy lung slices. This model highlighted macrophage-tumor interactions as critical for tumor cell proliferation, migration, and immune modulation. Together, these platforms provide a robust tool for lung cancer research, enabling precision medicine and advancing therapeutic discovery.

Authors

Siavash Mansouri, Annika Karger, Clemens Ruppert, Marc A. Schneider, Andreas Weigert, Rajender Nandigama, Blerina Aliraj, Lisa Strotmann, Anoop V. Cherian, Diethard Pruefer, Peter Dorfmuller, Ludger Fink, Ibrahim Alkoudmani, Stefan Gattenlöhner, Bastian Eul, Andre Althoff, Peter Kleine, Hauke Winter, Andreas Guenther, Hossein-Ardeschir Ghofrani, Soni S. Pullamsetti, Friedrich Grimminger, Werner Seeger, Rajkumar Savai

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Figure 1

Preparation and culture of TD-PCLS from fresh human lung tumor.

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Preparation and culture of TD-PCLS from fresh human lung tumor. (A and B...
(A and B) Immediately after lobectomy, the removed lung was filled with 1% low-melting agar in the operating room or pathology department and waited for the agar to solidify. (C) The filled lung was evaluated and sectioned by the expert pathologist to identify the tumor area for clinical purposes and also to provide the proper piece for TD-PCLS preparation. (D) The tumor piece was transferred on ice to the molecular biology laboratory. First, the tumor was cut in the shape with sharp angle (about 90 degrees) and then stuck to the metal plate, which was then moved into the vibratome sample box filled by cold PBS. (E and F) TD-PCLS was prepared by cutting tumor pieces in various thickness, depending on tumor type and structure and subjected to further treatment, imaging, and analysis. The thickness was between 200–500 μm from lung adenocarcinoma. The criteria that defines the thickness was tumor size, thickness, solidity, and necrotic area.