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Self-assembling dendrimer nanodrug formulations for decreased hERG-related toxicity and enhanced therapeutic efficacy

Xi Liu, Dinesh Dhumal, Patricia Santofimia‐Castaño, Juan Liu, Marion Casanova, Alicia Comino Garcia-Muñoz, Teodora‐Adriana Perles‐Barbacaru, Abdechakour Elkihel, Wenzheng Zhang, Tom Roussel, Christina Galanakou, Jing Wu, Eleni Zerva, Nelson Dusetti, Yi Xia, Xing‐Jie Liang, Angèle Viola, Juan Iovanna, Ling Peng

2025Science Advances9 citationsDOIOpen Access PDF

Abstract

Cardiotoxicity, especially human ether-a-go-go-related gene (hERG)-related toxicity, is a leading cause of drug failure or market withdrawal. Reducing hERG binding to obviate potential cardiac toxicity is crucial. Nanotechnology has been applied to drug delivery for reducing drug toxicity and improving efficacy, but few studies have addressed hERG-related cardiotoxicity. We report the use of self-assembling dendrimer nanosystems for drug formulation and delivery, which effectively reduced hERG binding and associated toxicity while promoting therapeutic efficacy. Specifically, these dendrimer nanosystems efficiently encapsulated the antimalarial drug chloroquine, the anticancer agent doxorubicin, and the NUPR1 inhibitor ZZW115, all three having high affinity to hERG channels. These nanoformulations showed three- to eightfold reduced hERG binding affinity, which, in animal models, translated to abolished toxicity. These nanodrugs exhibited prolonged circulation, leading to enhanced accumulation at disease sites and improved treatment outcomes. This study highlights the potential of nanotechnology to reduce hERG binding and related toxicity while improving drug efficacy, offering valuable perspectives for drug development.

Topics & Concepts

DendrimerhERGToxicityPharmacologyChemistryMedicineComputational biologyBiologyBiochemistryInternal medicinePotassium channelDendrimers and Hyperbranched PolymersRNA Interference and Gene DeliveryNanoparticle-Based Drug Delivery