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This review will provide an overview of the synthesis strategies which have been designed to achieve the crystal phase control in TMDs, and the chemical mechanisms that can drive the synthesis of metastable phases. We will provide a critical comparison between growth pathways in vapour- and liquid-phase synthesis techniques. Morphological and chemical characteristics of synthesized materials will be described along with their ability to act as electrocatalysts for the hydrogen evolution reaction from water. Phase stability and reversibility will be discussed and new potential applications will be introduced. This review aims at providing insights into the fundamental understanding of the favourable synthetic conditions for the stabilization of metastable TMD crystals and at stimulating future advancements in the field of large-scale synthesis of materials with crystal phase control.The anions pertechnetate, TcO4-, and perrhenate, ReO4-, exhibit very similar chemical and physical properties. Revealing and understanding disparities between them enhances fundamental understanding of both. Electrospray ionization generated the gas-phase proton bound dimer (TcO4-)(H+)(ReO4-). Collision induced dissociation of the dimer yielded predominantly HTcO4 and ReO4-, which according to Cooks' kinetic method indicates that the proton affinity (PA) of TcO4- is greater than that of ReO4-. Density functional theory computations agree with the experimental observation, providing PA[TcO4-] = 300.1 kcal mol-1 and PA[ReO4-] = 297.2 kcal mol-1. Attempts to rationalize these relative PAs based on elementary molecular parameters such as atomic charges indicate that the entirety of bond formation and concomitant bond disruption needs to be considered to understand the energies associated with such protonation processes. Although in both the gas and solution phases, TcO4- is a stronger base than ReO4-, it is noted that the significance of even such qualitative accordance is tempered by the very different natures of the underlying phenomena.Room-temperature ionic liquids (RTILs) are being increasingly employed as novel solvents in several fields, including chemical engineering, electrochemistry, and synthetic chemistry. To further increase their usage potential, a better understanding of the structure of their surface layer is essential. Bi-layering at the surfaces of RTILs consisting of 1-alkyl-3-methylimidazolium ([Cnmim]+; n = 4, 6, 8, 10, and 12) cations and bis(trifluoromethanesulfonyl)amide ([TFSA]-) anions was demonstrated via infrared-visible sum-frequency generation (IV-SFG) vibrational spectroscopy and molecular dynamics (MD) simulations. It was found that the sum-frequency (SF) signal from the [TFSA]- anions decreases as the alkyl chain length increases, whereas the SF signal from the r+ mode (the terminal CH3 group) of the [Cnmim]+ cations is almost the same regardless of chain length. MD simulations show the formation of a bi-layered structure consisting of the outermost first layer and a submerged second layer in a "head-to-head" molecular arrangement. The decrease in the SF signals of the normal modes of the [TFSA]- anions is caused by destructive and out-of-phase interference of vibrations of corresponding molecular moieties oriented toward each other in the first and second layers. In contrast, the r+ mode of [Cnmim]+ does not experience destructive interference because the peak position of the r+ mode differs marginally at the surface and in the bulk. Our conclusions are not limited to the system presented here. Similar bi-layered structures can be expected for the surfaces of conventional RTILs, which necessitates the consideration of bi-layering in the design and application.Monomeric sarcosine oxidase (MSOX) is a fundamental - yet one of the simplest - member of a family of flavoenzymes able to catalyze the oxidation of sarcosine (N-methylglycine) and other secondary amines. MSOX is one of the best characterized members of the amine oxidoreductases (AOs), however, its reaction mechanism is still controversial. selleckchem A single electron transfer (SET) process was suggested on the basis of studies with N-cyclopropylglycine (CPG), although a hydride transfer mechanism would be more consistent in general for AOs. To shed some light on the detailed reaction mechanisms of CPG in MSOX, we performed hybrid quantum mechanical/molecular mechanical (QM/MM) simulations. We found that the polar mechanism is energetically the most favorable. The free energy profile indicates that the first rate-limiting step is the CPG binding to the flavin ring which simultaneously proceeds with the ring-opening of the CPG cyclopropyl group. This reaction step of the CPG adduct formation corresponds to the nucleophilic attack of the cyclopropyl group (C3 atom) to the flavin ring (C4a atom), whereas the expected radical species formation in the SET mechanism was not observed. The following inactivated species, which accumulates during the CPG oxidation in MSOX, can be ascribed to an imine state, and not an enamine state, on the basis of the computed UV/Vis spectra. The conformation of CPG was found to be crucial for reactions following the CPG adduct formation.We investigate the phase behaviours of Pluronic L62 in aqueous solution in the presence of aerosol-OT (AOT) molecules by small angle neutron scattering (SANS). The presence of AOT significantly changes the micellization phenomenon of L62 micelles in aqueous solution, including their critical micelle temperature (CMT), global size, and asphericity. The origin of these observations is attributed to the complexation between the neutral L62 surfactants and the ionic AOT molecules, which additionally provides charge to the mixed micelles we analyse the data and extract meaningful information using the Ornstein-Zernike integral formalism. As a result, we observe that the co-micellization of L62 and AOT is very stable across a wide temperature range.Cancer immunotherapy is an emerging treatment strategy that modulates the immune system to fight against cancer. Although several immunotherapeutic agents have been utilized in the clinic for cancer treatment, low patient response rates and potential immune-related adverse events remain two major challenges. With the merits of delivery controllability and modular flexibility, nanomedicines provide opportunities to facilitate immunotherapies for clinical translation in a safe and effective manner. In this review, we discuss the convergence of nanomedicine with immunotherapy with a focus on molecular and nanoengineering approaches towards activatable cancer immunotherapy. These activatable nanoagents exert immunotherapeutic action only in response to internal or external stimuli. This allows them to locally reprogram the tumor microenvironment and activate antitumor immunity while reducing the incidence of immune-related adverse events. The category of activatable immunotherapeutic nanoagents are discussed along with an overview of their clinical translation prospects and challenges.

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