人工神经网络
纳米颗粒
生物系统
人工智能
计算机科学
弹道
粒子(生态学)
召回
预测建模
粘度
纳米粒子跟踪分析
跟踪(教育)
材料科学
机器学习
纳米技术
化学
物理
生物
天文
语言学
心理学
复合材料
生态学
教育学
小RNA
哲学
基因
生物化学
微泡
作者
Chad Curtis,Mike McKenna,Hugo Pontes,Dorsa Toghani,Alex Choe,Elizabeth Nance
出处
期刊:Nanoscale
[The Royal Society of Chemistry]
日期:2019-01-01
卷期号:11 (46): 22515-22530
被引量:18
摘要
Predictive models of nanoparticle transport can drive design of nanotherapeutic platforms to overcome biological barriers and achieve localized delivery. In this paper, we demonstrate the ability of artificial neural networks to predict both nanoparticle properties, such as size and protein adsorption, and aspects of the brain microenvironment, such as cell internalization, viscosity, and brain region by using large (>100 000) trajectory datasets collected via multiple particle tracking in in vitro gel models of the brain and cultured organotypic brain slices. Our neural network achieved a 0.75 recall score when predicting gel viscosity based on trajectory datasets, compared to 0.49 using an obstruction scaling model. When predicting in situ nanoparticle size based on trajectory datasets, neural networks achieved a 0.90 recall score compared to 0.83 using an optimized Stokes-Einstein predictor. To distinguish between nanoparticles of different sizes in more complex nanoparticle mixtures, our neural network achieved up to a recall score of 0.85. Even in cases of more nuanced output variables where mathematical models are not available, such as protein adhesion, neural networks retained the ability to distinguish between particle populations (recall score of 0.89). These findings demonstrate how trajectory datasets in combination with machine learning techniques can be used to characterize the particle-microenvironment interaction space.
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