Experience and Enlightenment of Handheld Ultrasound Applications in Multiple Scenarios Based on 5G Technology

In the digital age, the miniaturization of portable ultrasound equipment has brought both opportunities and challenges to the healthcare industry. Handheld ultrasound (HHU) devices are tablet or smartphone-sized scanners that are highly portable, have lower costs, produce no harmful side effects, and consume less power, making them suitable for use in different environments. HHU devices are primarily designed for new users of ultrasound scanners with varying backgrounds to evaluate different structures of the human body in various clinical settings. HHU applications based on Fifth-generation (5G) wireless network communication and artificial intelligence (AI) technology provide new healthcare solutions. The main application scenarios for HHU devices currently include in-hospital use, remote medical treatment, emergency rescue, and home monitoring. These scenarios allow for rapid image acquisition and real-time image interpretation, thereby improving the efficiency and quality of healthcare, reducing medical costs, and improving the allocation and utilization of medical resources. However, there remain some technical challenges and weaknesses such as device safety, data privacy, and network stability. With the continuous integration of AI technology, HHU applications will find wider use and promotion, bringing about more opportunities and challenges to the healthcare industry. This article reviews the application experience and insights of 5G technology in the field of HHU, aiming to provide fresh evidence and references for future research and applications

Point-of-Care Ultrasound: New Concepts and Future Trends

Ultrasound (US) technology, with major advances and new developments, has become an essential and first-line imaging modality for clinical diagnosis and interventional treatment. US imaging has evolved from one-dimensional, twodimensional to three-dimensional display, and from static to real-time imaging, as well as from structural to functional imaging. Based on its portability and advanced digital imaging technique, US was first adopted by emergency medicine in the 1980s and gradually gained popularity among other specialists for clinical diagnosis and interventional treatment. Point-of-Care Ultrasound (POCUS) was then proposed as a new concept and developed for new uses, which greatly extended clinical US applications. Nowadays, artificial intelligence (AI), cloud computing, 5G network, robotics, and remote technologies are starting to be integrated into US equipment. US systems have gradually evolved to an intelligent terminal platform with powerful imaging and communication tools. In addition, specialized US machines tend to be more suitable and important to meet increasing demands and requirements by various clinical specialties and departments. In this article, we review current US technology and POCUS as new concepts and its future trends, as well as related technological developments and clinical applications

Characteristics of the Sediment Transport Process in Vegetation Hillslopes under Different Flow Rates

Vegetation filter strips (VFSs) have always been an important measure to control agricultural soil erosion, especially in mountainous and hilly areas with more sloping farmland. To investigate the mechanism of the sediment-trapping process by VFSs, a series of tests were conducted with four gradients of flow rate, 7.5–45 L min−1 m−1, and two different sediment concentrations of 40 and 120 g L−1. The whole process of overland flow was monitored, and sediment and particle size samples from the inflow and outflow were collected and measured. The results showed that the changes in sediment concentration did not significantly affect the corresponding coefficients in the power function relationship between overland flow rate and velocity. Using the Reynolds number alone cannot effectively indicate the flow pattern of overland flow on vegetation hillslopes. The peak particle size and linear function were effective in describing the relationship between sediment particle composition and delivery rate during the sediment-trapping process by VFSs. During the sediment-trapping process, the sediment-trapping capacity of VFSs continued to decrease. The increase in sediment discharge was accompanied by a higher proportion of coarse particles. Under the same flow rate conditions, when the sediment concentration was higher, the coarse particles and their proportion also increased faster. Therefore, using only a certain particle size threshold to distinguish suspended and transported sediment may lead to inaccurate estimation of the sediment-trapping performance of VFSs. This study deepened the understanding of the mechanism of water–sediment processes on vegetation hillslopes and promoted the widespread and efficient application of VFSs management technology

Refinement Strengthening of AZ31 Magnesium Alloy by Warm Constrained Groove Pressing

The grain refinement and its effect on the mechanical properties of AZ31 magnesium alloys were investigated. The grain refinement was conducted using one of the severe plastic deformation methods, warm constrained groove pressing (CGP) technology. The effective strain was analyzed using the DEFORM-3D software. It was found that the effective strain distribution in AZ31 sheet was homogeneous after a complete four-stage of CGP at 473 K. The average grain size was reduced from 20 μm to 9 μm and the hardness was improved from 55.84 HBW to 69.16 HBW after a complete CGP process at 473 K. The yield stress and ultimate tensile strength increase with grain refinement, from 132 MPa and 240 MPa to 155 MPa and 285 MPa, respectively, following the Hall-Petch relationship. Subjected to annealing at 530 K for 15 minutes, the average grain size of CGP sample decreases slightly and the elongation increased up to 16.2%, close to 17.72% for the pre-CGP samples

The complete mitochondrial genome of the Riparia riparia (Passeriformes: Hirundinidae)

The Sand Martin (Riparia riparia) belongs to Hirundinidae. In this study, the complete mitochondrial genome of R. riparia was sequenced and characterized. The genome was 17,963 bases in length (GenBank accession no. OK537984) including 13 protein-coding genes, two ribosomal RNA (rRNA) genes, 22 transfer RNA (tRNA) genes, and two control regions. The overall base composition of R. riparia mitogenome was 30.5% for A, 31.8% for C, 14.5% for G, and 23.2% for T. Phylogenetic analysis revealed that R. riparia was genetically closest to the species of genus Tachycineta. R. riparia mitogenome could contribute to our understanding of the phylogeny and evolution of this species

US-guided percutaneous radiofrequency ablation of secondary hyperparathyroidism as a bridge to renal transplantation

AbstractPurpose Secondary hyperparathyroidism (SHPT) is a frequently encountered problem in patients with end-stage renal disease (ESRD) prior to renal transplantation (RTP), and the successful management of SPHP currently is challenging. In this study, we aimed to investigate the effectiveness of radiofrequency ablation (RFA) for SHPT as a bridge to RTP and to evaluate post-transplantation outcomes.Methods Patients with SHPT receiving RFA treatment were retrospectively reviewed, and those underwent RTP after ablation were enrolled. Serum parathyroid hormone (PTH), calcium, and phosphate levels were collected before ablation and at follow-up periods. The primary endpoints are PTH values at time of transplantation and at the final follow-up. The secondary endpoints were RFA-related complications, serum calcium and phosphate concentrations, and allograft function.Results Eleven patients with 43 enlarged parathyroid glands were treated with 16 RFA sessions and enrolled in the study. Complete ablation was achieved in all glands with transient hoarseness and hypocalcemia occurring in two and five of the treatments, respectively. At time of transplantation, serum PTH levels (246.7 ± 182.6 pg/mL) were significantly lower than that before RFA (1666.55 ± 874.48 pg/mL, p < 0.001) and were all within guideline-oriented range. The median follow-up period was 57.2 months. At last visit, all patients were alive, with normal PTH values and functioning grafts.Conclusions Ultrasound-guided RFA is effective for destroying hyperplastic parathyroid tissues in SHPT patients, whose PTH values fall within the guideline-oriented range both pre-and post-transplantation. Percutaneous RFA acts as an effective bridge to RTP and might provide a new management paradigm designed to improve post-transplant outcomes