RESUMEN
Ingenious approaches to supramolecular assembly for fabricating smart nanodevices is one of the more significant topics in nanomaterials research. Herein, by using surface quaternized cationic carbon dots (CDots) as the assembly and fluorescence platform, anionic sulfonatocalix[4]arene with modifiable lower and upper rims as a connector, as well as in situ coordination of Tb(3+) ions, we propose an elaborate supramolecular assembly strategy for the facile fabrication of a multifunctional nanodevice. The dynamic equilibrium characteristics of the supramolecular interaction can eventually endow this nanodevice with functions of fluorescent ratiometric molecular recognition and as a nano-logic gate with two output channels.
RESUMEN
Elaborately designed stimuli-responsive smart systems simultaneously enabling activatable imaging and selective treatment are highly desirable for precise diagnosis and therapy of cancer. Herein, such a smart theranostic nanoprobe composed of hollow gold nanospheres (HAuNs), photosensitizer (PS), matrix metalloproteinase 2 (MMP2) substrate peptide, and model drug doxorubicin (DOX) was designed. In the design, HAuNs served as the acceptor of Förster resonance energy transfer (FRET), photothermal therapy (PTT) reagent, and nanocarrier. The fluorescence and 1O2 generation of PS were inhibited by HAuNs through FRET effect, avoiding phototoxicity to normal tissues during circulation. Meanwhile, owing to the MMP2-triggered peptide cleavage, the PS could be efficiently activated in a tumor for selective fluorescence imaging and photodynamic therapy (PDT). The recovered fluorescence could be applied for detecting MMP2, locating tumor in vivo, and further guiding the local triple-combination therapies including PDT, PTT, and chemotherapy. The synergistic treatments of activated PDT, PTT, and controlled DOX release were achieved with single light, which provided the best therapeutic effects with enhanced stability and remarkably reduced nonspecific toxicity of PS and anticancer drug. This study helps to design novel stimuli-responsive systems for precise molecular sensing and site-specific cancer treatment.
RESUMEN
With the rapid development of information science, it is urgent that memory devices possessing high security, density, and desirable storage ability should be developed. In this work, a smart duplicate response of stimuli has been developed and a time-gate nanohybrid based on variable valence Eu2+/Eu3+ coencapsulated has been fabricated and acts as active material in the multilevel and multidimensional memory devices. The luminescence lifetime of Eu3+ in this nanohybrid gave a stimuli response due to which the energy level of the coordinated ligand could be modulated. Furthermore, by a simple sintering procedure, Eu3+ was partially in situ reduced to Eu2+ with a short lifetime in the system. And the in situ reduction ensured both Eu3+ and Eu2+ ions' uniform distribution in the nanohybrid and simultaneous response upon light excitation of variable valence Eu ions. Interestingly, Eu3+ revealed a prolonged lifetime because of the presence of an energy-transfer effect of Eu2+ â Eu3+. Such a nanohybrid had abundant luminescent properties, including the short lifetime of Eu2+, the energy transfer from the Eu2+ to Eu3+ ions, and the stimuli response of the Eu3+ lifetimes when exposed to acidic or basic vapor, thus giving birth to interesting recording and encryption performance in spatial-temporal dimensions. We believe that this research will point out a new direction for the future development of multilevel and multidimensional optical recording and encryption materials.
RESUMEN
Core-shell MOF-based smart nanocomposite UCNPs/MB@ZIF-8@catalase (UCNPs = upconversion nanoparticles; MB = methylene blue; ZIF = zeolitic imidazolate framework) has been constructed for bio-imaging and efficient NIR/H2O2-responsive photodynamic therapy against hypoxic tumor cells. The nanoporous MOF shell can prevent aggregation of photosensitizers and serve as an efficient self-sufficient oxygen gas acceptor.