Photothermal-modulated reversible volume transition of wireless hydrogels embedded with redox-responsive carbon dots.
Abstract
The reversible volume transition of redox-responsive hydrogels by near-infrared (NIR) irradiation has recently attracted significant attention as a novel therapy matrix for tracking and treating cancer via stimuli-responsive fluorescence on/off with controllable volume transition via a wireless sensing system. Herein, a NIR-induced redox-sensitive hydrogel was synthesized by blending a hydrogel with IR825-loaded carbon dots (CD) to achieve enhanced mobility of nanoparticles inside a gel network, and reversible volume phase transitions remotely controlled by a smartphone application via the induction of different redox environments. The presence of CD-IR825 in the thermosensitive poly(N-isopropylacrylamide) hydrogel network imparted fluorescence, electronic and photothermal properties to the hydrogels, which resulted in volume shrinkage behavior of the hydrogel upon exposure to NIR laser irradiation due to the redox-sensitive CDs. Under the NIR on/off cycles, the photothermal temperature, fluorescence, and porous structure were reversed after turning off the NIR laser. The hydrogel responsiveness under GSH and NIR light was studied using a wireless device based on the changes in the resistance graph on a smartphone application, generating a fast and simple method for the investigation of hydrogel properties. The in vitro cell viabilities of the MDA-MB cancer cells incubated with the composite hydrogel in the presence of external GSH exhibited a higher photothermal temperature, and the cancer cells were effectively killed after the NIR irradiation. Therefore, the NIR-induced redox-responsive nanocomposite hydrogel prepared herein has potential for use in cancer treatment and will enable the study of nanoparticle motion in hydrogel networks under multiple stimuli via a wireless device using a faster and more convenient method.
Keywords
health care
Wireless sensor networks
Internet of Things
authenticity
cloud computing
cryptography
patient monitoring
protocols
computational cost
doctors
accurate operations
computationally efficient mutual authentication protocol
continuous operations
cryptographic protocols
existing protocol
healthcare monitoring system
incubator monitoring systems
message authentication
public key cryptography
received information
remote healthcare monitoring
remote infant incubator monitoring system
resource-limited sensors
telecommunication security
wireless medical sensor networks
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DOI:
10.1039/c9bm00734b
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47962
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phuong2019photothermalmodulatedbiomaterials
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