The pathways for nanoparticle transport across tumour endothelium

Jamie L.Y. Wu; Qin Ji; Colin Blackadar; Luan N.M. Nguyen; Zachary P. Lin; Zahra Sepahi; Benjamin P. Stordy; Adrian Granda Farias; Shrey Sindhwani; Wayne Ngo; Katherine Chan; Andrea Habsid; Jason Moffat; Warren C.W. Chan

doi:10.1038/s41565-025-01877-5

The pathways for nanoparticle transport across tumour endothelium

Jamie L.Y. Wu, Qin Ji, Colin Blackadar, Luan N.M. Nguyen, Zachary P. Lin, Zahra Sepahi, Benjamin P. Stordy, Adrian Granda Farias, Shrey Sindhwani, Wayne Ngo, Katherine Chan, Andrea Habsid, Jason Moffat, Warren C.W. Chan^*

^*Corresponding author for this work

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

2 Citations (Scopus)

Abstract

The active transport and retention principle is an alternative mechanism to the enhanced permeability and retention effect for explaining nanoparticle tumour delivery. It postulates that nanoparticles actively transport across tumour endothelial cells instead of passively moving through gaps between these cells. How nanoparticles transport across tumour endothelial cells remains unknown. Here we show that nanoparticles cross tumour endothelial cells predominantly using the non-receptor-based macropinocytosis pathway. We discovered that tumour endothelial cell membrane ruffles capture circulating nanoparticles, internalize them in intracellular vesicles and release them into the tumour interstitium. Tumour endothelial cells have a higher membrane ruffle density than healthy endothelium, which may partially explain the elevated nanoparticle tumour accumulation. Receptor-based endocytosis pathways such as clathrin-mediated endocytosis contribute to nanoparticle transport to a lesser extent. Nanoparticle size determines the degree of contribution for each pathway. Elucidating the nanoparticle transport mechanism is crucial for developing strategies to control nanoparticle tumour delivery.

Original language	English
Article number	10649
Journal	Nature Nanotechnology
DOIs	https://doi.org/10.1038/s41565-025-01877-5
Publication status	Accepted/In press - 2025
Externally published	Yes

Bibliographical note

Publisher Copyright:
© The Author(s), under exclusive licence to Springer Nature Limited 2025.

ASJC Scopus Subject Areas

Bioengineering
Atomic and Molecular Physics, and Optics
Biomedical Engineering
General Materials Science
Condensed Matter Physics
Electrical and Electronic Engineering

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title = "The pathways for nanoparticle transport across tumour endothelium",

abstract = "The active transport and retention principle is an alternative mechanism to the enhanced permeability and retention effect for explaining nanoparticle tumour delivery. It postulates that nanoparticles actively transport across tumour endothelial cells instead of passively moving through gaps between these cells. How nanoparticles transport across tumour endothelial cells remains unknown. Here we show that nanoparticles cross tumour endothelial cells predominantly using the non-receptor-based macropinocytosis pathway. We discovered that tumour endothelial cell membrane ruffles capture circulating nanoparticles, internalize them in intracellular vesicles and release them into the tumour interstitium. Tumour endothelial cells have a higher membrane ruffle density than healthy endothelium, which may partially explain the elevated nanoparticle tumour accumulation. Receptor-based endocytosis pathways such as clathrin-mediated endocytosis contribute to nanoparticle transport to a lesser extent. Nanoparticle size determines the degree of contribution for each pathway. Elucidating the nanoparticle transport mechanism is crucial for developing strategies to control nanoparticle tumour delivery.",

author = "Wu, {Jamie L.Y.} and Qin Ji and Colin Blackadar and Nguyen, {Luan N.M.} and Lin, {Zachary P.} and Zahra Sepahi and Stordy, {Benjamin P.} and {Granda Farias}, Adrian and Shrey Sindhwani and Wayne Ngo and Katherine Chan and Andrea Habsid and Jason Moffat and Chan, {Warren C.W.}",

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doi = "10.1038/s41565-025-01877-5",

language = "English",

journal = "Nature Nanotechnology",

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AU - Wu, Jamie L.Y.

AU - Ji, Qin

AU - Blackadar, Colin

AU - Nguyen, Luan N.M.

AU - Lin, Zachary P.

AU - Sepahi, Zahra

AU - Stordy, Benjamin P.

AU - Granda Farias, Adrian

AU - Sindhwani, Shrey

AU - Ngo, Wayne

AU - Chan, Katherine

AU - Habsid, Andrea

AU - Moffat, Jason

AU - Chan, Warren C.W.

PY - 2025

Y1 - 2025

N2 - The active transport and retention principle is an alternative mechanism to the enhanced permeability and retention effect for explaining nanoparticle tumour delivery. It postulates that nanoparticles actively transport across tumour endothelial cells instead of passively moving through gaps between these cells. How nanoparticles transport across tumour endothelial cells remains unknown. Here we show that nanoparticles cross tumour endothelial cells predominantly using the non-receptor-based macropinocytosis pathway. We discovered that tumour endothelial cell membrane ruffles capture circulating nanoparticles, internalize them in intracellular vesicles and release them into the tumour interstitium. Tumour endothelial cells have a higher membrane ruffle density than healthy endothelium, which may partially explain the elevated nanoparticle tumour accumulation. Receptor-based endocytosis pathways such as clathrin-mediated endocytosis contribute to nanoparticle transport to a lesser extent. Nanoparticle size determines the degree of contribution for each pathway. Elucidating the nanoparticle transport mechanism is crucial for developing strategies to control nanoparticle tumour delivery.

AB - The active transport and retention principle is an alternative mechanism to the enhanced permeability and retention effect for explaining nanoparticle tumour delivery. It postulates that nanoparticles actively transport across tumour endothelial cells instead of passively moving through gaps between these cells. How nanoparticles transport across tumour endothelial cells remains unknown. Here we show that nanoparticles cross tumour endothelial cells predominantly using the non-receptor-based macropinocytosis pathway. We discovered that tumour endothelial cell membrane ruffles capture circulating nanoparticles, internalize them in intracellular vesicles and release them into the tumour interstitium. Tumour endothelial cells have a higher membrane ruffle density than healthy endothelium, which may partially explain the elevated nanoparticle tumour accumulation. Receptor-based endocytosis pathways such as clathrin-mediated endocytosis contribute to nanoparticle transport to a lesser extent. Nanoparticle size determines the degree of contribution for each pathway. Elucidating the nanoparticle transport mechanism is crucial for developing strategies to control nanoparticle tumour delivery.

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The pathways for nanoparticle transport across tumour endothelium

Abstract

Bibliographical note

ASJC Scopus Subject Areas

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