Reduction of monoclonal antibody viscosity using interpretable machine learning.

IF 5.6 2区 医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL mAbs Pub Date : 2024-01-01 Epub Date: 2024-03-12 DOI:10.1080/19420862.2024.2303781
Emily K Makowski, Hsin-Ting Chen, Tiexin Wang, Lina Wu, Jie Huang, Marissa Mock, Patrick Underhill, Emma Pelegri-O'Day, Erick Maglalang, Dwight Winters, Peter M Tessier
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Abstract

Early identification of antibody candidates with drug-like properties is essential for simplifying the development of safe and effective antibody therapeutics. For subcutaneous administration, it is important to identify candidates with low self-association to enable their formulation at high concentration while maintaining low viscosity, opalescence, and aggregation. Here, we report an interpretable machine learning model for predicting antibody (IgG1) variants with low viscosity using only the sequences of their variable (Fv) regions. Our model was trained on antibody viscosity data (>100 mg/mL mAb concentration) obtained at a common formulation pH (pH 5.2), and it identifies three key Fv features of antibodies linked to viscosity, namely their isoelectric points, hydrophobic patch sizes, and numbers of negatively charged patches. Of the three features, most predicted antibodies at risk for high viscosity, including antibodies with diverse antibody germlines in our study (79 mAbs) as well as clinical-stage IgG1s (94 mAbs), are those with low Fv isoelectric points (Fv pIs < 6.3). Our model identifies viscous antibodies with relatively high accuracy not only in our training and test sets, but also for previously reported data. Importantly, we show that the interpretable nature of the model enables the design of mutations that significantly reduce antibody viscosity, which we confirmed experimentally. We expect that this approach can be readily integrated into the drug development process to reduce the need for experimental viscosity screening and improve the identification of antibody candidates with drug-like properties.

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利用可解释的机器学习降低单克隆抗体粘度。
要简化安全有效的抗体疗法的开发过程,及早发现具有类药物特性的抗体候选物至关重要。对于皮下给药,重要的是识别低自结合的候选抗体,以便在保持低粘度、不透明和低聚集的同时实现高浓度制剂。在此,我们报告了一种可解释的机器学习模型,该模型仅使用抗体可变区(Fv)的序列来预测低粘度的抗体(IgG1)变体。我们的模型是在常见制剂 pH 值(pH 5.2)下获得的抗体粘度数据(>100 mg/mL mAb 浓度)上进行训练的,它识别出了与粘度相关的抗体的三个关键 Fv 特征,即等电点、疏水斑块大小和带负电荷斑块的数量。在这三个特征中,大多数预测有高粘度风险的抗体,包括在我们的研究中具有不同抗体种系的抗体(79 mAbs)以及临床阶段的 IgG1s(94 mAbs),都是那些 Fv 等电点较低(Fv pIs
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来源期刊
mAbs
mAbs 工程技术-仪器仪表
CiteScore
10.70
自引率
11.30%
发文量
77
审稿时长
6-12 weeks
期刊介绍: mAbs is a multi-disciplinary journal dedicated to the art and science of antibody research and development. The journal has a strong scientific and medical focus, but also strives to serve a broader readership. The articles are thus of interest to scientists, clinical researchers, and physicians, as well as the wider mAb community, including our readers involved in technology transfer, legal issues, investment, strategic planning and the regulation of therapeutics.
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