基于人工智能的纳米颗粒神经退行性疾病给药系统的添加式发现

IF 2.6 4区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY Beilstein Journal of Nanotechnology Pub Date : 2024-05-15 DOI:10.3762/bjnano.15.47
Shan He, Julen Segura Abarrategi, Harbil Bediaga, S. Arrasate, Humberto González-Díaz
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引用次数: 0

摘要

神经退行性疾病的特征是神经细胞缓慢死亡。由于药物溶解性差、生物利用度低以及无法有效穿过血脑屏障,传统的药物治疗策略往往会失败。因此,开发新的神经退行性疾病药物(NDDs)刻不容缓。纳米粒子(NP)系统在将 NDDs 运送到中枢神经系统方面越来越受到关注。然而,发现有效的纳米颗粒神经元疾病给药系统(N2D3Ss)具有挑战性,因为纳米颗粒和 NDD 化合物的组合数量庞大,而且涉及各种检测方法。人工智能/机器学习(AI/ML)算法可以预测最有前景的 NDD 和 NP 候选化合物,从而加速这一过程。然而,与化验的 NDD 相比,有关 N2D3S 活性的报告数据相对有限,这使得 AI/ML 分析具有挑战性。在这项工作中,我们采用了 IFPTML 技术来应对这一挑战,该技术结合了信息融合(IF)、扰动理论(PT)和机器学习(ML)。最初,我们将 ChEMBL 中的 4403 项 NDD 检测和期刊论文中的 260 项 NP 细胞毒性检测融合到一个统一的数据集中。通过重新取样过程,生成了三个新的工作数据集,每个数据集包含 500,000 个病例。我们利用线性判别分析(LDA)以及人工神经网络(ANN)算法,如多层感知器(MLP)和深度学习网络(DLN),构建了线性和非线性 IFPTML 模型。IFPTML-LDA 模型的灵敏度(Sn)和特异度(Sp)值分别为 70% 至 73%(大于 375,000 个训练病例)和 70% 至 80%(大于 125,000 个验证病例)。相比之下,IFPTML-MLP 和 IFPTML-DLN 在训练和验证序列中的 Sn 值和 Sp 值均在 85% 到 86% 之间。此外,IFPTML-ANN 模型的接收器工作曲线下面积(AUROC)约为 0.93 至 0.95。这些结果表明,IFPTML 模型可以作为设计神经科学药物输送系统的重要工具。
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On the additive artificial intelligence-based discovery of nanoparticle neurodegenerative disease drug delivery systems
Neurodegenerative diseases are characterized by slowly progressing neuronal cell death. Conventional drug treatment strategies often fail because of poor solubility, low bioavailability, and the inability of the drugs to effectively cross the blood–brain barrier. Therefore, the development of new neurodegenerative disease drugs (NDDs) requires immediate attention. Nanoparticle (NP) systems are of increasing interest for transporting NDDs to the central nervous system. However, discovering effective nanoparticle neuronal disease drug delivery systems (N2D3Ss) is challenging because of the vast number of combinations of NP and NDD compounds, as well as the various assays involved. Artificial intelligence/machine learning (AI/ML) algorithms have the potential to accelerate this process by predicting the most promising NDD and NP candidates for assaying. Nevertheless, the relatively limited amount of reported data on N2D3S activity compared to assayed NDDs makes AI/ML analysis challenging. In this work, the IFPTML technique, which combines information fusion (IF), perturbation theory (PT), and machine learning (ML), was employed to address this challenge. Initially, we conducted the fusion into a unified dataset comprising 4403 NDD assays from ChEMBL and 260 NP cytotoxicity assays from journal articles. Through a resampling process, three new working datasets were generated, each containing 500,000 cases. We utilized linear discriminant analysis (LDA) along with artificial neural network (ANN) algorithms, such as multilayer perceptron (MLP) and deep learning networks (DLN), to construct linear and non-linear IFPTML models. The IFPTML-LDA models exhibited sensitivity (Sn) and specificity (Sp) values in the range of 70% to 73% (>375,000 training cases) and 70% to 80% (>125,000 validation cases), respectively. In contrast, the IFPTML-MLP and IFPTML-DLN achieved Sn and Sp values in the range of 85% to 86% for both training and validation series. Additionally, IFPTML-ANN models showed an area under the receiver operating curve (AUROC) of approximately 0.93 to 0.95. These results indicate that the IFPTML models could serve as valuable tools in the design of drug delivery systems for neurosciences.
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来源期刊
Beilstein Journal of Nanotechnology
Beilstein Journal of Nanotechnology NANOSCIENCE & NANOTECHNOLOGY-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
5.70
自引率
3.20%
发文量
109
审稿时长
2 months
期刊介绍: The Beilstein Journal of Nanotechnology is an international, peer-reviewed, Open Access journal. It provides a unique platform for rapid publication without any charges (free for author and reader) – Platinum Open Access. The content is freely accessible 365 days a year to any user worldwide. Articles are available online immediately upon publication and are publicly archived in all major repositories. In addition, it provides a platform for publishing thematic issues (theme-based collections of articles) on topical issues in nanoscience and nanotechnology. The journal is published and completely funded by the Beilstein-Institut, a non-profit foundation located in Frankfurt am Main, Germany. The editor-in-chief is Professor Thomas Schimmel – Karlsruhe Institute of Technology. He is supported by more than 20 associate editors who are responsible for a particular subject area within the scope of the journal.
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