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Improved Orthogonality in Naphthalimide/Cyanine Dyad Boosts Superoxide Generation: a Tumor‐Targeted Type‐I Photosensitizer for Photodynamic Therapy of Tumor by Inducing Ferroptosis
https://orcid.org/0000-0002-3163-9742
AbstractIt is highly desired to achieve Type‐I photosensitizer (PS) to overcome the hypoxic limitation found in most clinically used PSs. Herein, a new heavy‐atom‐free Type‐I PS T‐BNCy5 is presented by incorporating a biotin‐modified naphthalimide (NI) unit into the meso‐position of a N‐benzyl‐functionalized, strongly photon‐capturing pentamethine cyanine (Cy5) dye. Such molecular engineering induces a rigid orthogonal geometry between NI and Cy5 units by introducing an intramolecular sandwich‐like π–π stacking assembly, which effectively promotes intersystem crossing (ISC) and greatly extends the triplet‐state lifetime (τ = 389 µs), thereby markedly improving the superoxide (O2•−)‐generating ability. In vitro assays reveal that T‐BNCy5 specifically accumulates in mitochondria, where it not only generates O2•− under photoirradiation but also induces the burst of the most cytotoxic hydroxy radical (HO•) by a cascade of biochemical reactions, ultimately triggering cell ferroptosis with the IC50 value up to ≈0.45 µm whether under normoxia or hypoxia. In vivo assays manifest that, benefiting from its biotin unit, T‐BNCy5 displays a strong tumor‐targeting ability, and after a single PDT treatment, it can not only ablate the tumor almost completely but also be cleared from the body through biosafe urinary excretion, indicating its potential for future clinical translation.
Improved Orthogonality in Naphthalimide/Cyanine Dyad Boosts Superoxide Generation: a Tumor‐Targeted Type‐I Photosensitizer for Photodynamic Therapy of Tumor by Inducing Ferroptosis
https://orcid.org/0000-0002-3163-9742
AbstractIt is highly desired to achieve Type‐I photosensitizer (PS) to overcome the hypoxic limitation found in most clinically used PSs. Herein, a new heavy‐atom‐free Type‐I PS T‐BNCy5 is presented by incorporating a biotin‐modified naphthalimide (NI) unit into the meso‐position of a N‐benzyl‐functionalized, strongly photon‐capturing pentamethine cyanine (Cy5) dye. Such molecular engineering induces a rigid orthogonal geometry between NI and Cy5 units by introducing an intramolecular sandwich‐like π–π stacking assembly, which effectively promotes intersystem crossing (ISC) and greatly extends the triplet‐state lifetime (τ = 389 µs), thereby markedly improving the superoxide (O2•−)‐generating ability. In vitro assays reveal that T‐BNCy5 specifically accumulates in mitochondria, where it not only generates O2•− under photoirradiation but also induces the burst of the most cytotoxic hydroxy radical (HO•) by a cascade of biochemical reactions, ultimately triggering cell ferroptosis with the IC50 value up to ≈0.45 µm whether under normoxia or hypoxia. In vivo assays manifest that, benefiting from its biotin unit, T‐BNCy5 displays a strong tumor‐targeting ability, and after a single PDT treatment, it can not only ablate the tumor almost completely but also be cleared from the body through biosafe urinary excretion, indicating its potential for future clinical translation.
Improved Orthogonality in Naphthalimide/Cyanine Dyad Boosts Superoxide Generation: a Tumor‐Targeted Type‐I Photosensitizer for Photodynamic Therapy of Tumor by Inducing Ferroptosis
https://orcid.org/0000-0002-3163-9742
AbstractIt is highly desired to achieve Type‐I photosensitizer (PS) to overcome the hypoxic limitation found in most clinically used PSs. Herein, a new heavy‐atom‐free Type‐I PS T‐BNCy5 is presented by incorporating a biotin‐modified naphthalimide (NI) unit into the meso‐position of a N‐benzyl‐functionalized, strongly photon‐capturing pentamethine cyanine (Cy5) dye. Such molecular engineering induces a rigid orthogonal geometry between NI and Cy5 units by introducing an intramolecular sandwich‐like π–π stacking assembly, which effectively promotes intersystem crossing (ISC) and greatly extends the triplet‐state lifetime (τ = 389 µs), thereby markedly improving the superoxide (O2•−)‐generating ability. In vitro assays reveal that T‐BNCy5 specifically accumulates in mitochondria, where it not only generates O2•− under photoirradiation but also induces the burst of the most cytotoxic hydroxy radical (HO•) by a cascade of biochemical reactions, ultimately triggering cell ferroptosis with the IC50 value up to ≈0.45 µm whether under normoxia or hypoxia. In vivo assays manifest that, benefiting from its biotin unit, T‐BNCy5 displays a strong tumor‐targeting ability, and after a single PDT treatment, it can not only ablate the tumor almost completely but also be cleared from the body through biosafe urinary excretion, indicating its potential for future clinical translation.
Improved Orthogonality in Naphthalimide/Cyanine Dyad Boosts Superoxide Generation: a Tumor‐Targeted Type‐I Photosensitizer for Photodynamic Therapy of Tumor by Inducing Ferroptosis
Advanced Science
Yao, Guangxiao (Autor:in) / Miao, Junfeng (Autor:in) / Huo, Yingying (Autor:in) / Guo, Wei (Autor:in)
06.03.2025
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
Carrier-free photosensitizer nanocrystal for photodynamic therapy
| British Library Online Contents | 2014
| British Library Online Contents | 2019