A157: The Effect of Whole-Body Vibration Therapy on the Motor Abilities of Patients with Sarcopenia

Purpose: The highly morbid condition known as sarcopenia affects middle-aged and elderly people and is characterized by a progressive loss of whole-body muscle mass accelerated by aging. It is also accompanied by a decline in muscle strength and physiological function. These weakening functions manifest as impaired physical movement, increased risk of falls, disability, lower quality of life, and even death. Sarcopenia is progressively emerging as a new public health issue in China with a quickly aging population, making it vital to investigate effective exercise therapies for sarcopenic patients. Methods: Sixty sarcopenic patients (aged 60-75) from a local hospital in northeast China participated in the study. They were randomly divided into a test group and a control group, with 30 patients in each. The test group underwent a 40-minute whole-body vibration training session for 12 weeks, five times a week, while the control group kept regular routines. Data were collected at the end of the experiment, including muscle strength, muscle mass, muscle function, gait speed, berg balance scale (BBS), five sit-to-stand test (FTSST), activities of daily living (ADL), fall risk assessment scale (FRA), and Sarcopenia Quality of Life Scale (SarQoL) scores. Results: The 12-week whole-body vibration training intervention resulted in a significantly higher value of muscular strength, muscle mass, and muscle function among the test group compared to the control group. The former achieved substantially higher SPPB, ADL, FTSST, and BBS scores than the latter (p \u3c 0.01). With much lower FRA scores and significantly better SarQoL ratings compared to baseline, the test group also significantly outperformed the control group in terms of fall risk and quality of life (p \u3c 0.01). Conclusion: With whole-body vibration training, people with sarcopenia can increase their skeletal muscle strength, considerably enhance their motor function, lower their risk of falls and accidents, and generally improve their quality of life. Whole-body vibration training is worthy of therapeutic use since it is both feasible and practical

A Method against Interrupted-Sampling Repeater Jamming Based on Energy Function Detection and Band-Pass Filtering

Interrupted-sampling repeater jamming (ISRJ) is a new kind of coherent jamming to the large time-bandwidth linear frequency modulation (LFM) signal. Many jamming modes, such as lifelike multiple false targets and dense false targets, can be made through setting up different parameters. According to the “storage-repeater-storage-repeater” characteristics of the ISRJ and the differences in the time-frequency-energy domain between the ISRJ signal and the target echo signal, one new method based on the energy function detection and band-pass filtering is proposed to suppress the ISRJ. The methods mainly consist of two parts: extracting the signal segments without ISRJ and constructing band-pass filtering function with low sidelobe. The simulation results show that the method is effective in the ISRJ with different parameters

Enhanced surface acceleration of fast electrons by using sub-wavelength grating targets

Surface acceleration of fast electrons in intense laser-plasma interaction is improved by using sub-wavelength grating targets. The fast electron beam emitted along the target surface was enhanced by more than three times relative to that by using planar target. The total number of the fast electrons ejected from the front side of target was also increased by about one time. The method to enhance the surface acceleration of fast electron is effective for various targets with sub-wavelength structured surface, and can be applied widely in the cone-guided fast ignition, energetic ion acceleration, plasma device, and other high energy density physics experiments.Comment: 14 pages, 4figure

Theory of polygonal phases self-assembled from T-shaped liquid crystalline polymers

Extensive experimental studies have shown that numerous ordered phases can be formed via the self-assembly of T-shaped liquid crystalline polymers (TLCPs) composed of a rigid backbone, two flexible end chains and a flexible side chain. However, a comprehensive understanding of the stability and formation mechanisms of these intricately nano-structured phases remains incomplete. Here we fill this gap by carrying out a theoretical study of the phase behaviour of TLCPs. Specifically, we construct phase diagrams of TLCPs by computing the free energy of different ordered phases of the system. Our results reveal that the number of polygonal edges increases as the length of side chain or interaction strength increases, consistent with experimental observations. The theoretical study not only reproduces the experimentally observed phases and phase transition sequences, but also systematically analyzes the stability mechanism of the polygonal phases