This study demonstrates
the preparation of dual cross-linked hydrogels
capable of selective, spontaneous de-cross-linking behavior triggered
by head-to-tail depolymerization. A primary covalent structure of
the materials was established on a thermoresponsive network containing
pendant functional moieties that could induce noncovalent interaction
when combined with a macro-cross-linker. The incorporation of the
macro-cross-linker not only reinforced the entire structure while
providing secondary physical cross-linking but also caused the resulting
materials to show autonomous responses via depolymerization. As a
result, transformation of the material was achieved without structural
collapse, as the noncovalent network in the materials was rapidly,
selectively, and completely removed through the depolymerization reaction
of the polymer cross-linker when initiated by a trace (<0.01 wt
%) stimulus. Thus, the macroscopic changes in the physical and chemical
properties of the hydrogels were investigated. Furthermore, we used
the proposed strategy to design actuating materials that exhibit reversible,
programmed, large-scale behavior and finally demonstrated re-cross-linking
by the addition of an extra macro-cross-linker after the de-cross-linking
reaction.
Ag 2 Te is well-known as a silver ion conductor. In this compound, a phase transition occurs at around 420 K and silver ions jump to interstitial sites repeatedly at the point of starting the phase transition. We consider that the active movement of silver ions would have influence on the scatterings of both charge carriers and heat carrying phonons in Ag 2 Te. In order to evaluate the effect of the silver ion conduction on the thermoelectric properties of Ag 2 Te, the Seebeck coefficient, electrical resistivity, thermal conductivity and Hall coefficient of polycrystalline bulk samples of Ag 2 Te were examined in the temperature range from room temperature to 650 K. The electrical resistivity and the Seebeck coefficient dramatically changed at around 420 K due to the change of the carrier concentration before and after the phase transition. However, the carrier mobility and the lattice thermal conductivity showed no remarkable change at around the phase transition temperature. These results imply that the thermoelectric transport properties of Ag 2 Te were affected by the change of the crystal structure rather than the presence or absence of the movement of silver ions.
This study has demonstrated the design of stimuli-responsive double-network hydrogels that are formed by sequential polymerization and show chemical transformation by selective de-cross-linking without structural failure owing to chemical orthogonality. Each self-immolative and thermoresponsive network established together the double-network structure through a thiol−ene click reaction and radical polymerization. The hydrogel exhibited enhanced mechanical strength but chemically transformed through the selective de-cross-linking of specific network triggered by a molecular stimulus, which significantly alters physical properties of the material such as tunable toughness and lower critical solution temperature behavior. In addition, the material displayed a thermoresponsive, controlled release. Only after treatment with the stimulus did the hydrogel release cargo molecules on demand via de-cross-linking while maintaining the entire structure.
Over the past few decades, the photoacoustic (PA) effect has been widely investigated, opening up diverse applications, such as photoacoustic spectroscopy, estimation of chemical energies, or point-of-care detection. Notably, photoacoustic imaging (PAI) has also been developed and has recently received considerable attention in bio-related or clinical imaging fields, as it now facilitates an imaging platform in the near-infrared (NIR) region by taking advantage of the significant advancement of exogenous imaging agents. The NIR PAI platform now paves the way for high-resolution, deep-tissue imaging, which is imperative for contemporary theragnosis, a combination of precise diagnosis and well-timed therapy. This review reports the recent progress on NIR PAI modality, as well as semiconducting contrast agents, and outlines the trend in current NIR imaging and provides further direction for the prospective development of PAI systems.
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