Photoresponsive Protein-Graphene-Protein Hybrid Capsules with Dual Targeted Heat-Triggered Drug Delivery Approach for Enhanced Tumor Therapy

Photoresponsive Protein-Graphene-Protein Hybrid Capsules with Dual Targeted Heat-Triggered Drug Delivery Approach for Enhanced Tumor Therapy

A novel photo‐responsive protein–graphene–protein (PGP) capsule that doubles as a photothermal agent with core/shell structure is constructed by anchoring reduced graphene oxide nanosheets on one‐component protein (lactoferrin) shell through a double emulsion method. PGP capsules can transport fully...

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Veröffentlicht in:Advanced functional materials 2014-07, Vol.24 (26), p.4144-4155
Hauptverfasser: Hu, Shang-Hsiu, Fang, Ren-Hong, Chen, Yu-Wei, Liao, Bang-Jie, Chen, I-Wei, Chen, San-Yuan
Format: Artikel
Sprache:eng
Schlagworte:
Actuation
Biocompatibility
Biomedical materials
Chemotherapy
Core-shell structure
double emulsion
Doxorubicin
Drug delivery systems
Graphene
graphene oxide
Hyperthermia
Irradiation
Materials science
nanocapsules
Near infrared radiation
Oxides
Proteins
Radiation damage
Shells
synergic therapy
Therapy
Tumors
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container_end_page 4155
container_issue 26
container_start_page 4144
container_title Advanced functional materials
container_volume 24
creator Hu, Shang-Hsiu
Fang, Ren-Hong
Chen, Yu-Wei
Liao, Bang-Jie
Chen, I-Wei
Chen, San-Yuan
description A novel photo‐responsive protein–graphene–protein (PGP) capsule that doubles as a photothermal agent with core/shell structure is constructed by anchoring reduced graphene oxide nanosheets on one‐component protein (lactoferrin) shell through a double emulsion method. PGP capsules can transport fully concealed hydrophilic anticancer cargo, doxorubicin (Dox), with a large payload (9.43 μmol g‐1) to be later unloaded in a burst‐like manner by photo‐actuation triggered by near‐infrared irradiation. Being biocompatible yet with a high cancer cell targeting efficiency, PGP capsules have successfully eradicated subcutaneous tumors in 10 d following a single 5 min NIR irradiation without distal damage. Besides, the photochemothermal therapy of PGP capsules eradicates tumor cells not only in the light‐treating area but also widely light‐omitted tumor cells, overcoming the tumor recurrence due to efficient cell killing efficacy. These results demonstrate that the PGP capsule is a potential new drug delivery platform for local‐targeting, on‐demand, photoresponsive, combined chemotherapy/hyperthermia for tumor treatment and other biomedical applications. Core–shell photoresponsive protein–graphene–protein capsules supported on a reduced graphene oxide substrate and one‐single component of protein display targeted chemotherapy with synergistic hyperthermia effects, eradicating not only the targeted cells but also cancerous cells omitted near infrared irradiation in vivo and in vitro.
doi_str_mv 10.1002/adfm.201400080
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source Wiley Online Library Journals Frontfile Complete
subjects Actuation
Biocompatibility
Biomedical materials
Chemotherapy
Core-shell structure
double emulsion
Doxorubicin
Drug delivery systems
Graphene
graphene oxide
Hyperthermia
Irradiation
Materials science
nanocapsules
Near infrared radiation
Oxides
Proteins
Radiation damage
Shells
synergic therapy
Therapy
Tumors
title Photoresponsive Protein-Graphene-Protein Hybrid Capsules with Dual Targeted Heat-Triggered Drug Delivery Approach for Enhanced Tumor Therapy
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