Charge balanced aggregation: A universal approach to aqueous organic nanocrystals

Organic nanocrystals, particularly those composed of conjugated molecules, hold immense potential for various applications. However, their practical utility is often hindered by the challenge of achieving stable aqueous dispersions, which are essential for biological compatibility and effective delivery. This study introduces a novel and versatile strategy for preparing stable aqueous organic nanocrystals using a modified reprecipitation method. We demonstrate the broad applicability of this approach by successfully preparing a diverse library of nanocrystals from 27 conjugated molecules. Our findings reveal a charge-balanced aggregation mechanism for nanocrystal formation, highlighting the crucial role of surface charge in controlling particle size and stability. Based on this mechanism, we establish a comprehensive molecular combination strategy that directly links molecular properties to colloidal behaviour, enabling the straightforward prediction and preparation of stable aqueous dispersions without the need for excipients. This strategy provides a practical workflow for tailoring the functionality of these nanocrystals for a wide range of applications. To illustrate their therapeutic potential, we demonstrate the enhanced efficacy of these nanocrystals in treating acute ulcerative colitis, myocardial ischemia/reperfusion injury, and cancer in mouse models. This work paves the way for developing next-generation nanomaterials with tailored functionalities for diverse biomedical applications.