Impact of 3D cell culture hydrogels derived from basement membrane extracts or nanofibrillar cellulose on CAR-T cell activation

Sonia Aristin Revilla; Alessandro Cutilli; Eugenia Cambiaso; Dedeke Rockx-Brouwer; Cynthia Lisanne Frederiks; Marc Falandt; Riccardo Levato; Onno Kranenburg; Caroline A. Lindemans; Paul James Coffer; Victor Peperzak; Enric Mocholi; Marta Cuenca

doi:10.1016/j.isci.2025.113234

Impact of 3D cell culture hydrogels derived from basement membrane extracts or nanofibrillar cellulose on CAR-T cell activation

Sonia Aristin Revilla
, Alessandro Cutilli
, Eugenia Cambiaso
, Dedeke Rockx-Brouwer
, Cynthia Lisanne Frederiks
, Marc Falandt
, Riccardo Levato
, Onno Kranenburg
, Caroline A. Lindemans
, Paul James Coffer
, Victor Peperzak
, Enric Mocholi
, Marta Cuenca

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Research output: Contribution to journal › Article › peer-review

4 Citations (Scopus)

Abstract

Hydrogel-based 3D culture systems are increasingly used for preclinical evaluation of cell-based immunotherapies, including chimeric antigen receptor T (CAR-T) cells. However, hydrogel properties can influence T cell behavior, potentially affecting interpretation of immunotherapy studies. We assessed CD4⁺ T and CAR-T cell responses in two chemically undefined matrices—Matrigel and basement membrane extract (BME)— and in a synthetic nanofibrillar cellulose (NFC) hydrogel. Although NFC was mechanically stiffer, T cell activation and proliferation were higher in NFC than in Matrigel or BME. Murine CD4⁺ T cells acquired a regulatory phenotype in Matrigel and BME but not in NFC. Similarly, CAR-T cell function was reduced in Matrigel and BME but maintained in NFC. These findings underscore how matrix composition can shape T cell responses in 3D culture. NFC provides a chemically defined alternative that preserves T cell activity, supporting its use in more accurate preclinical testing of immunotherapies.

Original language	English
Article number	113234
Journal	iScience
Volume	28
Issue number	9
DOIs	https://doi.org/10.1016/j.isci.2025.113234
Publication status	Published - 19 Sept 2025

Keywords

Biological sciences
Biomaterials
Cell biology
Immune response
Materials science

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Revilla, S. A., Cutilli, A., Cambiaso, E., Rockx-Brouwer, D., Frederiks, C. L., Falandt, M., Levato, R., Kranenburg, O., Lindemans, C. A., Coffer, P. J., Peperzak, V., Mocholi, E., & Cuenca, M. (2025). Impact of 3D cell culture hydrogels derived from basement membrane extracts or nanofibrillar cellulose on CAR-T cell activation. iScience, 28(9), Article 113234. https://doi.org/10.1016/j.isci.2025.113234

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title = "Impact of 3D cell culture hydrogels derived from basement membrane extracts or nanofibrillar cellulose on CAR-T cell activation",

abstract = "Hydrogel-based 3D culture systems are increasingly used for preclinical evaluation of cell-based immunotherapies, including chimeric antigen receptor T (CAR-T) cells. However, hydrogel properties can influence T cell behavior, potentially affecting interpretation of immunotherapy studies. We assessed CD4+ T and CAR-T cell responses in two chemically undefined matrices—Matrigel and basement membrane extract (BME)— and in a synthetic nanofibrillar cellulose (NFC) hydrogel. Although NFC was mechanically stiffer, T cell activation and proliferation were higher in NFC than in Matrigel or BME. Murine CD4+ T cells acquired a regulatory phenotype in Matrigel and BME but not in NFC. Similarly, CAR-T cell function was reduced in Matrigel and BME but maintained in NFC. These findings underscore how matrix composition can shape T cell responses in 3D culture. NFC provides a chemically defined alternative that preserves T cell activity, supporting its use in more accurate preclinical testing of immunotherapies.",

keywords = "Biological sciences, Biomaterials, Cell biology, Immune response, Materials science",

author = "Revilla, \{Sonia Aristin\} and Alessandro Cutilli and Eugenia Cambiaso and Dedeke Rockx-Brouwer and Frederiks, \{Cynthia Lisanne\} and Marc Falandt and Riccardo Levato and Onno Kranenburg and Lindemans, \{Caroline A.\} and Coffer, \{Paul James\} and Victor Peperzak and Enric Mocholi and Marta Cuenca",

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Revilla, SA, Cutilli, A, Cambiaso, E, Rockx-Brouwer, D, Frederiks, CL, Falandt, M, Levato, R, Kranenburg, O, Lindemans, CA, Coffer, PJ, Peperzak, V, Mocholi, E & Cuenca, M 2025, 'Impact of 3D cell culture hydrogels derived from basement membrane extracts or nanofibrillar cellulose on CAR-T cell activation', iScience, vol. 28, no. 9, 113234. https://doi.org/10.1016/j.isci.2025.113234

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T1 - Impact of 3D cell culture hydrogels derived from basement membrane extracts or nanofibrillar cellulose on CAR-T cell activation

AU - Revilla, Sonia Aristin

AU - Cutilli, Alessandro

AU - Cambiaso, Eugenia

AU - Rockx-Brouwer, Dedeke

AU - Frederiks, Cynthia Lisanne

AU - Falandt, Marc

AU - Levato, Riccardo

AU - Kranenburg, Onno

AU - Lindemans, Caroline A.

AU - Coffer, Paul James

AU - Peperzak, Victor

AU - Mocholi, Enric

AU - Cuenca, Marta

PY - 2025/9/19

Y1 - 2025/9/19

N2 - Hydrogel-based 3D culture systems are increasingly used for preclinical evaluation of cell-based immunotherapies, including chimeric antigen receptor T (CAR-T) cells. However, hydrogel properties can influence T cell behavior, potentially affecting interpretation of immunotherapy studies. We assessed CD4+ T and CAR-T cell responses in two chemically undefined matrices—Matrigel and basement membrane extract (BME)— and in a synthetic nanofibrillar cellulose (NFC) hydrogel. Although NFC was mechanically stiffer, T cell activation and proliferation were higher in NFC than in Matrigel or BME. Murine CD4+ T cells acquired a regulatory phenotype in Matrigel and BME but not in NFC. Similarly, CAR-T cell function was reduced in Matrigel and BME but maintained in NFC. These findings underscore how matrix composition can shape T cell responses in 3D culture. NFC provides a chemically defined alternative that preserves T cell activity, supporting its use in more accurate preclinical testing of immunotherapies.

AB - Hydrogel-based 3D culture systems are increasingly used for preclinical evaluation of cell-based immunotherapies, including chimeric antigen receptor T (CAR-T) cells. However, hydrogel properties can influence T cell behavior, potentially affecting interpretation of immunotherapy studies. We assessed CD4+ T and CAR-T cell responses in two chemically undefined matrices—Matrigel and basement membrane extract (BME)— and in a synthetic nanofibrillar cellulose (NFC) hydrogel. Although NFC was mechanically stiffer, T cell activation and proliferation were higher in NFC than in Matrigel or BME. Murine CD4+ T cells acquired a regulatory phenotype in Matrigel and BME but not in NFC. Similarly, CAR-T cell function was reduced in Matrigel and BME but maintained in NFC. These findings underscore how matrix composition can shape T cell responses in 3D culture. NFC provides a chemically defined alternative that preserves T cell activity, supporting its use in more accurate preclinical testing of immunotherapies.

KW - Biological sciences

KW - Biomaterials

KW - Cell biology

KW - Immune response

KW - Materials science

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C2 - 40837221

AN - SCOPUS:105012943449

SN - 2589-0042

VL - 28

JO - iScience

JF - iScience

IS - 9

M1 - 113234

ER -

Impact of 3D cell culture hydrogels derived from basement membrane extracts or nanofibrillar cellulose on CAR-T cell activation

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