Tailored Confining Microenvironment for Lung Cancer Spheroids

Overview

Journal Mater Today Bio

Specialty Biomedical Engineering

Date 2025 Mar 12

PMID 40070872

Authors

Yixiao Dong

Shuyi Qian

Xuechun Wang

Wang Zhang

Weisheng Lu

Ju Qu

Meihua Cui

Linzhi Chen

Yingshuai Zhao

Yuehua Gao

Monica Giomo

Anna Urciuolo

Jian Feng

Yijun Zheng

Biao Jiang

Ruling Shen

Xianmin Zhu

Nicola Elvassore

Affiliations

Soon will be listed here.

Abstract

The mechanical properties and physical confinement of the extracellular matrix (ECM) are crucial roles in regulating tumor growth and progression. Extensive efforts have been dedicated to replicating the physical characteristics of tumor tissue by developing two-dimensional (2D) and three-dimensional (3D) models. However, it remains a significant challenge to modulate the local microenvironment around the specific cells according to the culture progress. In this study, we develop a 3D culture platform for multicellular lung cancer spheroids using a gelatin-based hydrogel with adjustable density and stiffness. Then, by utilizing a two-photon mediated bioprinting technique, we construct 3D confining microstructures with micrometer accuracy to enclose the selected spheroids within the hydrogel matrix. Diverse transcriptional profilings of cells are observed in response to the increased ECM density and stiffness compared to the additional confining stress. In addition, changed confining stress can regulate the tumor cells with contrary impacts on the cell cycle-related pathways. Our model not only allows for modifications to the mechanical microenvironment of the overall matrix but also facilitates localized adjustments throughout the culture evolution. This approach serves as a valuable tool for investigating tumor progression and understanding cell-ECM interactions.

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