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Machine-learning-assisted single-vessel analysis of nanoparticle permeability in tumour vasculatures.

Mingsheng ZhuJie ZhuangZhe LiQiqi LiuRongping ZhaoZhanxia GaoAdam C MidgleyTianyi QiJingwei TianZhixuan ZhangDe-Ling KongZhenyu ZhangXiyun YanXinglu Huang
Published in: Nature nanotechnology (2023)
The central dogma that nanoparticle delivery to tumours requires enhanced leakiness of vasculatures is a topic of debate. To address this, we propose a single-vessel quantitative analysis method by taking advantage of protein-based nanoprobes and image-segmentation-based machine learning (nano-ISML). Using nano-ISML, >67,000 individual blood vessels from 32 tumour models were quantified, revealing highly heterogenous vascular permeability of protein-based nanoparticles. There was a >13-fold difference in the percentage of high-permeability vessels in different tumours and >100-fold penetration ability in vessels with the highest permeability compared with vessels with the lowest permeability. Our data suggest passive extravasation and transendothelial transport were the dominant mechanisms for high- and low-permeability tumour vessels, respectively. To exemplify the nano-ISML-assisted rational design of nanomedicines, genetically tailored protein nanoparticles with improved transendothelial transport in low-permeability tumours were developed. Our study delineates the heterogeneity of tumour vascular permeability and defines a direction for the rational design of next-generation anticancer nanomedicines.
Keyphrases
  • endothelial cells
  • machine learning
  • deep learning
  • big data
  • protein protein
  • smoking cessation
  • small molecule
  • fluorescence imaging