Litcius/Paper detail

TransMA: an explainable multi-modal deep learning model for predicting properties of ionizable lipid nanoparticles in mRNA delivery

Kun Wu, Zixu Wang, Xiulong Yang, Yangyang Chen, Fulvio Mastrogiovanni, Jialü Zhang, Lizhuang Liu

2025Briefings in Bioinformatics13 citationsDOIOpen Access PDF

Abstract

As the primary messenger RNA (mRNA) delivery vehicles, ionizable lipid nanoparticles (LNPs) exhibit excellent safety, high transfection efficiency, and strong immune response induction. However, the screening process for LNPs is time-consuming and costly. To expedite the identification of high-transfection-efficiency mRNA drug delivery systems, we propose an explainable LNPs transfection efficiency prediction model, called TransMA. TransMA employs a multimodal molecular structure fusion architecture, wherein the fine-grained atomic spatial relationship extractor named molecule 3D Transformer captures three-dimensional spatial features of the molecule, and the coarse-grained atomic sequence extractor named molecule Mamba captures one-dimensional molecular features. We design the mol-attention mechanism block, enabling it to align coarse and fine-grained atomic features and capture relationships between atomic spatial and sequential structures. TransMA achieves state-of-the-art performance in predicting transfection efficiency using the scaffold and cliff data splitting methods on the current largest LNPs dataset, including Hela and RAW cell lines. Moreover, we find that TransMA captures the relationship between subtle structural changes and significant transfection efficiency variations, providing valuable insights for LNPs design. Additionally, TransMA's predictions on external transfection efficiency data maintain a consistent order with actual transfection efficiencies, demonstrating its robust generalization capability. We hope that high-accuracy transfection prediction models in the future can aid in LNPs design and initial screening, thereby assisting in accelerating the mRNA design process.

Topics & Concepts

TransfectionHeLaComputer scienceBiological systemChemistryNanotechnologyComputational biologyMaterials scienceBiologyCellBiochemistryGeneRNA Interference and Gene DeliveryAdvanced biosensing and bioanalysis techniquesRNA and protein synthesis mechanisms