Recently, a great deal of research has focused on the study of self-healing hydrogels possessing electronic conductivity due to their wide applicability for use in biosensors, bioelectronics, and energy storage. The low solubility, poor biocompatibility, and lack of effective stimuli-responsive properties of their sp 2 carbon-rich hybrid organic polymers, however, have proven challenging for their use in electroconductive self-healing hydrogel fabrication. In this study, we developed stimuli-responsive electrochemical wireless hydrogel biosensors using ureidopyriminone-conjugated gelatin (Gel-UPy) hydrogels that incorporate diselenide-containing carbon dots (dsCD) for cancer detection. The cleavage of diselenide groups of the dsCD within the hydrogels by glutathione (GSH) or reactive oxygen species (ROS) initiates the formation of hydrogen bonds that affect the self-healing ability, conductivity, and adhesiveness of the Gel-UPy/ dsCD hydrogels. The Gel-UPy/dsCD hydrogels demonstrate more rapid healing under tumor conditions (MDA-MB-231) compared to that observed under physiological conditions (MDCK). Additionally, the cleavage of diselenide bonds affects the electrochemical signals due to the degradation of dsCD. The hydrogels also exhibit excellent adhesiveness and in vivo cancer detection ability after exposure to a high concentration of GSH or ROS, and this is comparable to results observed in a low concentration environment. Based on the combined self-healing, conductivity, and adhesiveness properties of the Gel-UPy/ dsCD, this hydrogel exhibits promise for use in biomedical applications, particularly those that involve cancer detection, due to its selectivity and sensitivity under tumor conditions.
This
study investigated a selective and sensitive theragnosis system
for the specific targeting of the membrane and nuclei based on visible-light
and pH-responsive TiO2-integrated cross-linked carbon dot
(C-CD/TiO2) for tumor detection and controllable photothermal
therapy. The cross-linking system was formed by boronate ester linkages
between the TiO2-immobilized Dopa-decyl (D-CD) and zwitterionic-formed
CD (Z-CD) for nuclear targeting, which showed fluorescence “off”
at physiological pH. The fluorescence recovered to the “on”
state in acidic cancer cells owing to cleavages of the boronate ester
bonds, resulting in the disruption of the Förster resonance
energy transfer that generated different CDs useful for tumor-selective
biosensors and therapy. D-CD, which is hydrophobic, can penetrate
the hydrophobic sites of the cell membrane; it caused a loss in the
hydrophobicity of these sites after visible-light irradiation. This
was achieved by the photocatalytic activity of the TiO2 modulating energy bandgap, whereas the Z-CD targeted the nucleus,
as confirmed by merged confocal microscopy images. D-CD augmented
by photothermal heat also exhibited selective anticancer activity
in the acidic tumor condition but showed only minimal effects at a
normal site at pH 7.4. After C-CD/TiO2 injection to an in vivo tumor model, C-CD/TiO2 efficiently ablated
tumors under NIR light irradiation. The C-CD/TiO2 group
showed up-regulation of the pro-apoptotic markers such as P53 and BAX in tumor. This material exhibited
its potential as a theragnostic sensor with excellent biocompatibility,
high sensitivity, selective imaging, and direct anticancer activity
via photothermal therapy.
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