4.7 Article

Interaction of Near-Infrared (NIR)-Light Responsive Probes with Lipid Membranes: A Combined Simulation and Experimental Study

Journal

PHARMACEUTICS
Volume 15, Issue 7, Pages -

Publisher

MDPI
DOI: 10.3390/pharmaceutics15071853

Keywords

near-infrared (NIR)-light responsive probes; lipid membranes; molecular dynamics simulations; photothermal therapy (PTT); photodynamic therapy (PDT)

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Cancer poses a significant global challenge for the next decade, and strategies for simultaneous diagnosis and treatment are promising for combatting this disease. Developing nanomaterials with near-infrared (NIR) light responsiveness, such as heptamethine cyanines, has shown great potential for tumor visualization and generating a photothermal/photodynamic effect. Molecular dynamics simulations were performed to understand the interaction between 12 NIR-light responsive probes and lipid membranes, providing valuable insights for selecting suitable molecules and guiding probe modifications to optimize interaction with tumor cell membranes.
Cancer is considered a major societal challenge for the next decade worldwide. Developing strategies for simultaneous diagnosis and treatment has been considered a promising tool for fighting cancer. For this, the development of nanomaterials incorporating prototypic near-infrared (NIR)-light responsive probes, such as heptamethine cyanines, has been showing very promising results. The heptamethine cyanine-incorporating nanomaterials can be used for a tumor's visualization and, upon interaction with NIR light, can also produce a photothermal/photodynamic effect with a high spatio-temporal resolution and minimal side effects, leading to an improved therapeutic outcome. In this work, we studied the interaction of 12 NIR-light responsive probes with lipid membrane models by molecular dynamics simulations. We performed a detailed characterization of the location, orientation, and local perturbation effects of these molecules on the lipid bilayer. Based on this information, the probes were divided into two groups, predicting a lower and higher perturbation of the lipid bilayer. From each group, one molecule was selected for testing in a membrane leakage assay. The experimental data validate the hypothesis that molecules with charged substituents, which function as two polar anchors for the aqueous phase while spanning the membrane thickness, are more likely to disturb the membrane by the formation of defects and pores, increasing the membrane leakage. The obtained results are expected to contribute to the selection of the most suitable molecules for the desired application or eventually guiding the design of probe modifications for achieving an optimal interaction with tumor cell membranes.

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