What question did this study set out to answer?

This research aims to explore how doxorubicin interacts with graphene oxide to improve drug delivery methods.

May 3, 2026Open Access

Molecular insights into doxorubicin adsorption on graphene oxide: a combined theoretical and experimental study

Key Points

This research aims to explore how doxorubicin interacts with graphene oxide to improve drug delivery methods.
Integrated mathematical modeling and experimental validation.
Used Lennard–Jones potential and a genetic algorithm for predictions.
Assessed the drug-loading capacity and interaction energy of DOX with varying GO oxidation levels.
Higher oxidation degrees of GO show weaker interaction energy with DOX.
The theoretical predictions align with observed experimental data on binding configurations.
The study provides insights for designing efficient drug delivery platforms using GO.

Abstract

Abstract This study integrates mathematical modelling and experimental validation to investigate the fundamental interactions between the chemotherapeutic agent doxorubicin (DOX) and graphene oxide (GO), aiming to advance targeted drug delivery. Our theoretical approach, using the Lennard–Jones potential and the unified non-dominated sorting genetic algorithm III, successfully predicts the energetic landscape and optimal binding configurations of the DOX–GO system. These computational results are directly supported by our experimental findings on drug-loading capacity. We observe that a higher degree of GO oxidation leads to weaker interaction energy, a conclusion consistent with both our theoretical predictions and empirical data. This comprehensive methodology provides a molecular-level understanding of DOX–GO interactions, enabling the rational design of more efficient and therapeutically effective GO-based drug delivery platforms.

Molecular insights into doxorubicin adsorption on graphene oxide: a combined theoretical and experimental study

Key Points

Abstract

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