物理法則を組み込んだAIで薬物放出予測を高速化(Physics-informed AI Could Accelerate Development of Controlled-release Drug Patches, Bandages)

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2026-07-06 ブラウン大学

米国ブラウン大学の研究チームは、人工知能(AI)を活用して薬物送達(ドラッグデリバリー)材料の設計を効率化する新たな手法を開発した。薬物送達システムでは、薬剤を目的の組織へ安全かつ効率的に届けるため、ナノ粒子や高分子材料の組成や構造を最適化する必要があるが、従来は膨大な実験を繰り返す必要があり、開発に時間とコストを要していた。研究チームは、実験データと機械学習を組み合わせたAIモデルを構築し、多数の材料候補の中から高性能な薬物送達材料を効率よく予測・選定できることを実証した。さらに、AIが有望と判断した候補を実験で検証することで、従来法より少ない試行回数で優れた送達性能を持つ材料を見いだすことに成功した。本技術は、薬剤の標的部位への送達効率向上や副作用の低減、新規医薬品開発の迅速化に貢献するほか、がん、感染症、遺伝子治療など幅広い分野への応用が期待される。研究成果は学術誌「Nature Communications」に掲載された。

<関連情報>

物理法則に基づいたニューラルネットワークを用いた薬剤放出モデリング Drug release modeling using Physics-Informed Neural Networks

Daanish Aleem Qureshi, Khemraj Shukla, Vikas Srivastava
Journal of Drug Delivery Science and Technology  Available online: 1 July 2026
DOI:https://doi.org/10.1016/j.jddst.2026.108654

物理法則を組み込んだAIで薬物放出予測を高速化(Physics-informed AI Could Accelerate Development of Controlled-release Drug Patches, Bandages)

Abstract

Accurate modeling of drug release is essential for designing and developing controlled-release systems. Classical models (Fick, Higuchi, Peppas) rely on simplifying assumptions that limit their accuracy in complex geometries and release mechanisms. Here, we propose a novel approach using Physics-Informed Neural Networks (PINNs) and Bayesian PINNs (BPINNs) for predicting drug release from complex geometries using planar, 1D-wrinkled, and 2D-crumpled films as examples. This approach uniquely integrates Fick’s diffusion law with limited and sparse experimental data to enable accurate long-term predictions from short-term measurements, and is systematically benchmarked against classical drug release models. We incorporated Fick’s second law into the PINN framework as a soft constraint being satisfied at randomly sampled collocation points. Previously published sparse experimental datasets are then used to evaluate drug release performance using mean absolute error (MAE) and root mean square error (RMSE), accounting for noisy conditions and limited data availability. Our approach reduced mean error by up to 40% relative to classical baselines across all film types. The PINN formulation achieved RMSE <0.05 utilizing only the first 6% of the release time data (reducing 94% of release time required for the experiments) for the planar film. For wrinkled and crumpled films, the PINN reached RMSE<0.05 in 33% of the release time data. BPINNs provide tighter and more reliable uncertainty quantification under noise. By combining physical laws with experimental data, the proposed framework yields highly accurate long-term release predictions from short-term measurements, offering a practical route for accelerated characterization and more efficient early-stage drug release system formulation. Unlike conventional machine learning approaches, which often lack clear theoretical convergence guarantees, PINNs provide convergence assurances for broad classes of elliptic and parabolic equations. With Fick’s diffusion equation as parabolic, our proposed PINNs based method offers a theoretically consistent and stable framework for modeling drug diffusion processes. The codes are available at https://github.com/SrivastavaResearchLab/drug_release_modeling_PINN-2025

有機化学・薬学
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