RESUMO
BACKGROUND: Dexamethasone has been shown to alleviate pain, yet the optimal dosing and safety profiles remain unclear. This study aimed to evaluate the analgesic efficacy and impact on sleep quality of three different doses of intravenous dexamethasone in patients undergoing total knee arthroplasty (TKA). METHODS: In this randomized, triple-blind, clinical trial, we assessed the analgesic effects of three doses of intravenous dexamethasone (four, eight, and 16 mg) in adult patients who underwent TKA. Pain was measured using the visual analog scale at one, 12, 24, and 48 hours postoperatively, and sleep quality was assessed two weeks postsurgery. RESULTS: A total of 90 participants were enrolled in the study, with 30 participants in each dosing group. The mean visual analog scale scores at 12, 24, and 48 hours postoperatively showed significant improvement from baseline in all groups. Notably, the 16 mg and eight mg dexamethasone groups demonstrated significantly greater pain reduction compared to the four mg group (P < 0.05). Additionally, sleep quality significantly improved in the 16 mg and eight mg groups (P < 0.05). CONCLUSIONS: Dexamethasone at doses of four, eight, and 16 mg effectively reduces pain and enhances sleep quality in patients undergoing TKA, with the 16 mg dose showing the most pronounced effects at 12, 24, and 48 hours postoperatively.
RESUMO
Core@shell nanoparticles (NPs) have been widely explored to enhance catalysis due to the synergistic effects introduced by their nanoscale interface and surface structures. However, creating a catalytically functional core@shell structure is often a synthetic challenge due to the need to control the shell thickness. Here, we report a one-step synthetic approach to core-shell CuPd@Pd NPs with an intermetallic B2-CuPd core and a thin (â¼0.6 nm) Pd shell. This core@shell structure shows enhanced activity toward selective hydrogenation of Ar-NO2 and allows one-pot tandem hydrogenation of Ar-NO2 to Ar-NH2 and its condensation with Ar-CHO to form Ar-NâCH-Ar. DFT calculations indicate that the B2-CuPd core promotes the Pd shell binding to Ar-NO2 more strongly than to Ar-CHO, thereby selectively activating Ar-NO2. The chemoselective catalysis demonstrated by B2-CuPd@Pd can be extended to a broader scope of substrates, allowing green chemistry synthesis of a wide range of functional chemicals and materials.
RESUMO
Dipole-dipole interactions (V dd) between closely spaced atoms and molecules are related to real photon and virtual photon exchange between them and decrease in the near field connected with the characteristic Coulombic dipole field law. The control and modification of this marked scaling with distance have become a long-standing theme in quantum engineering since dipole-dipole interactions govern Van der Waals forces, collective Lamb shifts, atom blockade effects, and Förster resonance energy transfer. We show that metamaterials can fundamentally modify these interactions despite large physical separation between interacting quantum emitters. We demonstrate a two orders of magnitude increase in the near-field resonant dipole-dipole interactions at intermediate field distances (10 times the near field) and observe the distance scaling law consistent with a super-Coulombic interaction theory curtailed only by absorption and finite size effects of the metamaterial constituents. We develop a first-principles numerical approach of many-body dipole-dipole interactions in metamaterials to confirm our theoretical predictions and experimental observations. In marked distinction to existing approaches of engineering radiative interactions, our work paves the way for controlling long-range dipole-dipole interactions using hyperbolic metamaterials and natural hyperbolic two-dimensional materials.
RESUMO
One of the most important issues in cancer progression is caner stem cells (CSCs) which have illustrated that the bulk tumors can arise from a special combination of cells. Remarkably, it has been proposed to be a notable and strong factor in carcinogenesis and tumorogenesis and also is a key parameter of therapeutic resistance. In this way, recent findings have shown the key roles of epigenetic regulations in cancer development.Considerably, epigenetic regulations of gene expression is an active and dynamic process including histone modification, DNA methylation and chromatin remodeling with a reversible trait.Meaningly, recent and novel findings have described the significance of epigenetic regulatory proteins from divers features comprising tumorogenesis,stem cell proliferation and carcinogenesis. Evidently, abnormal epigenetic regulations is directly related with many serious disorders particularly different cancers. We here review a discussion of how the deregulation of eclectic pathways containing Sonic Hedgehog (SHH), WNT, Beta catenin and NOTCH can help to carcinogenesis specially focusing to survival and maintenance of CSCs in therapeutic approach.
Assuntos
Epigênese Genética/genética , Neoplasias/genética , Células-Tronco Neoplásicas/metabolismo , Transdução de Sinais/genética , HumanosRESUMO
The demonstration of biosensors based on the surface plasmon effect holds promise for future high-sensitive electrodeless biodetection. The combination of magnetic effects with surface plasmon waves brings additional freedom to improve sensitivity and signal selectivity. Stacking biosensors with two-dimensional (2-D) materials, e.g., graphene (Gr) and MoS2, can influence plasmon waves and facilitate surface physiochemical properties as additional versatility aspects. We demonstrate magnetoplasmonic biosensors through the detuning of surface plasmon oscillation modes affected by magnetic effect via the presence of the NiFe (Py) layer and different light absorbers of Gr, MoS2, and Au ultrathin layers in three stacks of Au/Py/M(MoS2, Gr, Au) trilayers. We found minimum reflection, resonance angle shift, and transverse magneto-optical Kerr effect (TMOKE) responses of all sensors in the presence of the ss-DNA monolayer. Very few changes of â¼5×10-7 in the ss-DNA's refractive index result in valuable TMOKE response. We found that the presence of three-layer Gr and two-layer MoS2 on top of the Au/Py bilayer can dramatically increase the sensitivity by nine and four times, respectively, than the conventional Au/Co/Au trilayer. Our results show the highest reported DNA sensitivity based on the coupling of light with 2-D materials in magnetoplasmonic devices.
Assuntos
Técnicas Biossensoriais/instrumentação , DNA/análise , Ressonância de Plasmônio de Superfície , Fenômenos Químicos , Grafite/química , MagnetismoRESUMO
Organic solar cells (OSCs) are a complex assembly of disparate materials, each with a precise function within the device. Typically, the electrodes are flat, and the device is fabricated through a layering approach of the interfacial layers and photoactive materials. This work explores the integration of high surface area transparent electrodes to investigate the possible role(s) a three-dimensional electrode could take within an OSC, with a BHJ composed of a donor-acceptor combination with a high degree of electron and hole mobility mismatch. Nanotree indium tin oxide (ITO) electrodes were prepared via glancing angle deposition, structures that were previously demonstrated to be single-crystalline. A thin layer of zinc oxide was deposited on the ITO nanotrees via atomic layer deposition, followed by a self-assembled monolayer of C60-based molecules that was bound to the zinc oxide surface through a carboxylic acid group. Infiltration of these functionalized ITO nanotrees with the photoactive layer, the bulk heterojunction comprising PC71BM and a high hole mobility low band gap polymer (PDPPTT-T-TT), led to families of devices that were analyzed for the effect of nanotree height. When the height was varied from 0 to 50, 75, 100, and 120 nm, statistically significant differences in device performance were noted with the maximum device efficiencies observed with a nanotree height of 75 nm. From analysis of these results, it was found that the intrinsic mobility mismatch between the donor and acceptor phases could be compensated for when the electron collection length was reduced relative to the hole collection length, resulting in more balanced charge extraction and reduced recombination, leading to improved efficiencies. However, as the ITO nanotrees increased in height and branching, the decrease in electron collection length was offset by an increase in hole collection length and potential deleterious electric field redistribution effects, resulting in decreased efficiency.
RESUMO
Wide-bandgap, metal-oxide thin-film transistors have been limited to low-power, n-type electronic applications because of the unipolar nature of these devices. Variations from the n-type field-effect transistor architecture have not been widely investigated as a result of the lack of available p-type wide-bandgap inorganic semiconductors. Here, we present a wide-bandgap metal-oxide n-type semiconductor that is able to sustain a strong p-type inversion layer using a high-dielectric-constant barrier dielectric when sourced with a heterogeneous p-type material. A demonstration of the utility of the inversion layer was also investigated and utilized as the controlling element in a unique tunnelling junction transistor. The resulting electrical performance of this prototype device exhibited among the highest reported current, power and transconductance densities. Further utilization of the p-type inversion layer is critical to unlocking the previously unexplored capability of metal-oxide thin-film transistors, such applications with next-generation display switches, sensors, radio frequency circuits and power converters.