ABSTRACT
Objective: To explore the effect of rapid rehabilitation nursing in patients with brucellar spondylitis during the perioperative period. Methods: A total of 68 patients with brucellar spondylitis who underwent surgical treatment in our hospital from August 2019 to May 2022 and met the inclusion criteria were enrolled as study subjects. The patients were divided into a conventional group and a rehabilitation group with 34 cases each according to different nursing methods. The conventional group received routine nursing intervention and the rehabilitation group received perioperative rapid rehabilitation nursing intervention. The clinical data of patients were recorded, and the length of hospital stay, nursing intervention effect, pain perception, kyphotic Cobb angle changes, perioperative complications, and the satisfaction scores of patients were compared between the two groups. Results: The hospitalization time of patients in the rehabilitation group was significantly shorter and the clinical effective rate was significantly higher in the rehabilitation group than that of the conventional group, P < .05. The VAS scores of the rehabilitation group were significantly lower than the conventional group at each time point, P < .05. The total incidence of complications and the kyphotic Cobb angle at 3 days and 2 weeks post-operation of the rehabilitation group was significantly lower than the conventional group, P < .05; while the patient satisfaction was significantly higher in the rehabilitation group, P < .05. Conclusion: Rapid recovery nursing intervention for patients with brucellar spondylitis has a definite effect in the perioperative period, which can effectively reduce the pain experience of patients, improve the treatment effect, shorten the hospitalization time of patients, reduce the occurrence of perioperative complications, improve patient satisfaction, and promote the functional recovery of patients. The findings are significant and warrant the clinical promotion and application of fast recovery nursing intervention in the perioperative period of brucellar spondylitis.
ABSTRACT
The self-assembly of two-dimensional (2D) nanomaterials, an emerging research area, still remains largely unexplored. The strong interlayer attraction between 2D nanosheets leads to face-to-face stacking rather than edge-to-edge coupling. We demonstrate, for the first time, how one can induce and control an edge-to-edge self-assembly process for 2D nanomaterials. The extremely weak van der Waals coupling and strong anisotropy of ReS2 allow us to realize an oriented self-assembly (OSA) process. The aspect ratio of the resulting ReS2 nanoscrolls can be well controlled. In addition, we perform simulations to further explain and confirm the OSA process, demonstrating its great potential to be expanded as a general edge-to-edge self-assembly process suitable for other 2D nanomaterials.
ABSTRACT
Conversion reaction electrode materials (CREMs) have gained significant interest in lithium-ion batteries (LIBs) owing to their high theoretical gravimetric capacity. However, traditional CREMs-based electrodes, with large strain arising from Li(+) intercalation/deintercalation causes pulverization or electrical breakdown and cracking of the active materials which leads to structural collapse, limiting performance. Therefore, in order to construct electrodes with a strong tolerance to the strain incurred during the conversion reaction process, we design a coral-like three-dimensional (3D) hierarchical heterostructure by using cross-linked nanoflakes interspersed with nanoparticles (NPs) standing vertically on graphene foam (GF). The coral-like 3D hierarchical heterostructures can efficiently disperse the strain from both internal and external forces as well as increase the specific surface area for enhanced electrochemical reactions. These features lead to long-cycle stability and excellent flexibility in LIBs. Fe3O4 NPs and CoO NFs are utilized as a model system to demonstrate our strategy. The as-prepared coral-like hierarchical electrode is studied as an anode in LIBs for the first time and is shown to deliver a high reversible specific gravimetric capacity of â¼1200 mA h g(-1) at a rate of 0.5 A g(-1) for 400 cycles. In addition, our batteries can even power a green light-emitting diode when bent to high degrees confirming the excellent flexibility of the material.
ABSTRACT
The synthesis of vertical ReS2 nanowalls on 3D graphene foam (V-ReS2 /3DGF) is demonstrated by a chemical vapor deposition route. The vertical nanowall structure leads to an effective exposure of active sites and enhances the lithium interaction with all of the layers. When serving as the anode material for lithium-ion batteries, the V-ReS2 /3DGF composite demonstrates excellent cycling stability at high-current-density.
ABSTRACT
Magnetite (Fe3O4) is an attractive electrode material due to its high theoretical capacity, eco-friendliness, and natural abundance. However, its commercial application in lithium-ion batteries is still hindered by its poor cycling stability and low rate capacity resulting from large volume expansion and low conductivity. We present a new approach which makes use of supercritical carbon dioxide to efficiently anchor Fe3O4 nanoparticles (NPs) on graphene foam (GF), which was obtained by chemical vapor deposition in a single step. Without the use of any surfactants, we obtain moderately spaced Fe3O4 NPs arrays on the surface of GF. The particle size of the Fe3O4 NPs exhibits a narrow distribution (11 ± 4 nm in diameter). As a result, the composites deliver a high capacity of about 1200 mAh g(-1) up to 500 cycles at 1 C (924 mAh g(-1)) and about 300 mAh g(-1) at 20 C, which reaches a record high using Fe3O4 as anode material for lithium-ion batteries.
