730 nm Light‐Induced Cleavage of BODIPY Photocages via Entropy‐Driven Triplet Sensitization

Author:

Isokuortti Jussi1,Long Kaiqi2,Gounani Zahra3,Zhang Yichi2,Alsaedy Omar1,Wang Weiping2ORCID,Laaksonen Timo3,Durandin Nikita A.1

Affiliation:

1. Faculty of Engineering and Natural Sciences Tampere University Tampere FI‐33101 Finland

2. Key Laboratory of Pharmaceutical Biotechnology & Dr. Li Dak‐Sum Research Centre & Department of Pharmacology and Pharmacy The University of Hong Kong Hong Kong 999077 China

3. Division of Pharmaceutical Biosciences Drug Research Program Faculty of Pharmacy University of Helsinki Helsinki FI‐00014 Finland

Abstract

AbstractLight‐activated drug delivery systems allow precise spatiotemporal control of a drug release process. However, safe and efficient drug release activation needs a low‐power nonpulsed red/near‐infrared light with high tissue penetration depth. Nevertheless, such systems remain a challenge. Herein, a self‐assembled nanovehicle made of 2,6‐diiodo‐B‐dimethyl‐boron dipyrromethene (BODIPY)‐based photocleavable trigonal molecules bearing Pt(II) meso‐tetraphenyltetranaphthoporhyrin photosensitizer and a fluorescent release marker Nile Red in hydrophobic core is introduced. The system employs endothermic triplet–triplet energy transfer between the photosensitizer and the trigonal molecule, leading to the cleavage of the trigonal molecule followed by cargo release. This allows to engage 730 nm light to cleave BODIPY photoremovable protecting groups (PPGs) instead of 530 nm light that would be needed for direct photocage excitation. Therefore, the approach unleashes the desired activation of drug release via photocleavage with longer wavelengths (within the phototherapeutic window) without any chemical modification of the PPGs. Cell studies demonstrate fast intracellular uptake of the nanovehices by PC3 human prostate cancer cells with accumulation in lysosomes in 2 h. Light irradiation at 730 nm on nanovehicles dispersed in cell media leads to payload release. Remarkably, the system exhibits higher release efficiency at low oxygen concentration than at ambient thus allowing to tackle aggressive hypoxic solid tumors.

Funder

European Research Council

National Natural Science Foundation of China

Publisher

Wiley

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