3 research outputs found
Theragnostic pH-Sensitive Gold Nanoparticles for the Selective Surface Enhanced Raman Scattering and Photothermal Cancer Therapy
We report a nanoparticle-based probe
that can be used for a “turn-on”
theragnostic agent for simultaneous Raman imaging/diagnosis and photothermal
therapy. The agent consists of a 10 nm spherical gold nanoparticle
(NP) with pH-responsive ligands and Raman probes on the surface. They
are engineered to exhibit the surface with both positive and negative
charges upon mildly acidic conditions, which subsequently results
in rapid aggregations of the gold NPs. This aggregation simultaneously
provides hot spots for the SERS probe with the enhancement factor
reaching 1.3 × 10<sup>4</sup> and shifts the absorption to far-red
and near-infrared (which is optimal for deep tissue penetration) by
the coupled plasmon resonances; this shift was successfully exploited
for low-threshold photothermal therapy. The theragnostic gold NPs
are cancer-specific because they aggregate rapidly and accumulate
selectively in cancerous cells. As the result, both Raman imaging
and photothermal efficacy were turned on under a cancerous local environment.
In addition, the relatively small hydrodynamic size can have the potential
for better access to targeted delivery in vivo and facilitated excretion
after therapy
Restacking-Inhibited 3D Reduced Graphene Oxide for High Performance Supercapacitor Electrodes
Graphene has received considerable attention in both scientific and technological areas due to its extraordinary material properties originating from the atomically single- or small number-layered structure. Nevertheless, in most scalable solution-based syntheses, graphene suffers from severe restacking between individual sheets and thus loses its material identity and advantages. In the present study, we have noticed the intercalated water molecules in the dried graphene oxide (GO) as a critical mediator to such restacking and thus eliminated the hydrogen bonding involving the intercalated water by treating GO with melamine resin (MR) monomers. Upon addition of MR monomers, porous restacking-inhibited GO sheets precipitated, leading to the carbonaceous composite with an exceptionally large surface area of 1040 m<sup>2</sup>/g after a thermal treatment. Utilizing such high surface area, the final graphene composite exhibited excellent electrochemical performance as a supercapacitor electrode material: specific capacitance of 210 F/g, almost no capacitance loss for 20 000 cycles, and ∼7 s rate capability. The current study delivers a message that various condensation reactions engaging GO sheets can be a general synthetic approach for restacking-inhibited graphene in scalable solution processes
Polypyrrole/Agarose-Based Electronically Conductive and Reversibly Restorable Hydrogel
Conductive hydrogels are a class of composite materials that consist of hydrated and conducting polymers. Due to the mechanical similarity to biointerfaces such as human skin, conductive hydrogels have been primarily utilized as bioelectrodes, specifically neuroprosthetic electrodes, in an attempt to replace metallic electrodes by enhancing the mechanical properties and long-term stability of the electrodes within living organisms. Here, we report a conductive, smart hydrogel, which is thermoplastic and self-healing owing to its unique properties of reversible liquefaction and gelation in response to thermal stimuli. In addition, we demonstrated that our conductive hydrogel could be utilized to fabricate bendable, stretchable, and patternable electrodes directly on human skin. The excellent mechanical and thermal properties of our hydrogel make it potentially useful in a variety of biomedical applications such as electronic skin