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The rapid growth of Artificial Intelligence and Internet of Things (AIoT) demands the development of ultra-low-power devices for future advanced technology. In this study, we introduce a capacitive piezotronic sensor specifically designed for tactile sensing, which enables an ultra-low-voltage operation at nearly 0 reading bias conditions with a consistent response within a wide voltage range. This sensor directly detects capacitance changes induced by piezocharges, reflecting perturbation of the effective depletion width, and ensures ultralow power capability by eliminating the necessity of turning on the Schottky diode for the first time. The dynamic response of the sensor demonstrates ultralow power capability and immunity to triboelectric interference, making it particularly suitable for tactile sensing applications in robotics, prosthetics, and wearables. This study provides valuable insights and design guidelines for future ultra-low-power thin-film-based capacitive piezotronic/piezophototronic devices for tactile sensing.

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Microplastics (MPs) have become an important global issue in recent years. However, MPs in the soil have received far less attention than water. Effective and nondestructive extraction of MPs is important for studying MPs in agricultural soils. This study uses different floatation solutions as experiments and uses MgCl2 as the floatation solution of the density extraction method. Five types of standard MPs (PE, PP, PS, PVC, and PET) are used as the objects of this experiment. The recovery of the two particle sizes was between 90.82% and 109.69%. The extracted standard MPs were then subjected to IR and Raman spectroscopic analysis, and the results showed that Raman spectroscopy was more suitable for the identification of the extracted MPs. Finally, this method collected and verified a vast number of soil samples and further analyzed the abundance and characteristics of the collected MPs.

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With the rapid increase in the use of plastic films, microplastic (MP) pollution in agricultural soils has become a global environmental problem. Propiconazole is widely used in agriculture and horticulture; however, its role in plastic film degradation remains elusive. Butylene adipate-co-terephthalate (PBAT) and polyethylene (PE) films were used to analyze the effects of propiconazole on plastic film and MP degradation. We identified the surface morphologies of PBAT and PE at different propiconazole concentrations and soil pH values, as well as the adsorption and release characteristics of heavy metals during the degradation process via scanning electron microscopy, Fourier transform infrared spectroscopy and inductively coupled plasma mass spectrometry. Propiconazole accelerated the degradation of MPs, adsorption of heavy metals (Ni and Zn), and release of Sn at low concentrations (≤40 mg/kg); however, these effects were evidently absent at a high concentration (120 mg/kg). Furthermore, MPs were more prone to degradation in acidic or alkaline soils than in neutral soil when they coexisted with propiconazole. Hence, we suggest that PBAT and PE plastic films may not be suitable for application in acidic and alkaline soils with propiconazole, because of shorter rupture time and more heavy metal adsorption. PBAT degraded faster, absorbed and released more heavy metals than PE. Under all tested conditions, the heavy metal contents in MPs gradually approached those in soil, which proves that MPs are carriers of heavy metal pollutants. These results may help in assessing the impact of MPs on soil environments and provide a theoretical basis for the standardized propiconazole and plastic film usage.

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Distal tibiofibular syndesmosis injury (DTS) occurs frequently with ankle sprains. Current treatments pose several limitations including causing soft tissue irritation, bringing damage to fixation secondary to weight-bearing, and requiring follow-up surgeries. Here, we investigated the clinical effects of a new technique, titanium cable isotonic annular fixation, for the treatment of DTS injury. From January 2015 to June 2017, 36 patients with ankle fractures and DTS injuries had their fractures repaired with the titanium cable isotonic annular fixation system. Recovery was scored by the AOFAS ankle function score system. We also assessed the differences in ankle motion between healthy and operative joints, and recorded the complications. All patients recovered from surgery without any serious complications. We followed all the cases for 18-25 months with an average follow-up of 21.26±3.23 months. 12 months after the operation, X-ray images showed that the titanium cables were fixed in the correct position without any fracture or loosening. Additionally, no degeneration or traumatic arthritis was observed in the ankle joint. There were no incision or bone mineral density changes between the titanium fix and tibiofibular bones. Nearly all patients recovered well except for three who developed inflammation and infection. However, these three patients recovered following 1 week of intravenous antibiotics and local radiofrequency physiotherapy. According to the AOFAS scoring system, all patients achieved satisfactory recovery 12 months post operation. Our titanium cable isotonic annular fixation system has both the advantages of elastic and rigid fixations. It can restore isotonic strength of the distal tibiofibular joint, and its biomechanical performance approaches normal physiological function. After the operation, patients tolerated weight-bearing exercise and recovered joint mobility. Finally, there is no need to remove the distal tibiofibular implant after 12 weeks. Overall, it is a highly effective surgical method to treat DTS injury.

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OBJECTIVE: Oxidative stress plays a critical role in the development of osteoporosis. Hydrogen sulfide (H2S), produces anti-oxidant effect in various biological systems. The present study found that GYY4137, a slow H2S releasing compound, stimulated both mRNA level and activity of alkaline phosphatase, the marker of osteoblast differentiation. This research aims to explore the mechanism on how GYY4137 stimulates osteoblastic cell proliferation and differentiation via an ERK1/2-dependent anti-oxidant approach. METHODS: The MC3T3-E1 osteoblast-like cell line was cultured in plate. After pretreatment with GYY4137 (100 µM) for 30 min, the cells were washed twice with PBS solution and then incubated in freshly prepared low serum medium containing 400 µM H2O2 for 4 h. Cells viability was evaluated with the MTT. Cell apoptosis was evaluated by the Hoechst 33342. Then, ALP activity, NO and the superoxide dismutase (SOD) activity is determined by assay kit accordingly, ALP mRNA is identified by RT-PCR. ERK1/2 was analyzed by Western blot. The ROS production was measured with a fluorescence reader. All data was analyzed by SPSS 16.0. RESULTS: We found in the present study that GYY4137, a slow H2S releasing compound, stimulated both mRNA level and activity of alkaline phosphatase, the marker of osteoblast differentiation. RT-PCR shows that GYY4137 stimulated the transcriptional levels of Runx2, a key transcription factor associated with osteoblast differentiation. These data suggest that GYY4137 may stimulate osteoblastic cell proliferation and differentiation. Moreover, GYY4137, which alone at 1-1000 µM had no significant effect, protected MC3T3-E1 osteoblastic cells against hydrogen peroxide (H2O2)-induced cell death and apoptosis. This was mediated by its anti-oxidant effect, as GYY4137 reversed the reduced superoxide dismutase activity and the elevated productions of reactive oxygen species and nitric oxide in the osteoblastic cells treated with H2O2. Western blotting analysis showed that the protective effects of GYY4137 were mediated by suppression of ERK1/2. CONCLUSIONS: GYY4137 stimulates osteoblastic cell proliferation and bone differentiation via an ERK1/2-dependent anti-oxidant mechanism. Our findings suggest that GYY4137 may have a potentially therapeutic value for osteoporosis.