bioelectrical

简明释义

英[/ˌbaɪəʊɪˈlɛktrɪkəl/]美[/ˌbaɪoʊɪˈlɛktrɪkəl/]

生物电的

英英释义

单词用法

同义词

反义词

例句

1.EEG are bioelectrical activity generated by the central nervous system, it contains a lot of the information about status and changes in the nervous system.

脑电信号(EEG)是中枢神经系统产生的生物电活动，它包含了丰富的神经系统状态和变化的信息。

2.Objective To measure the body compositions of patients under hemodialysis (HD) by bioelectrical impedance analysis (BIA).

目的用随机对照方法比较肠内和肠外营养支持途径对术后患者人体组成的影响。

3.If using a bioelectrical impedance scale, be sure to measure under the same circumstances each time. Hydration, food intake and skin temperature can affect body fat measurements.

如果是使用生物阻抗电子秤，确认每次是在同样的条件下。水和作用，吸入的食物和皮肤温度能过影响体脂的测量。

4.Bioelectrical impedance analysis included body cell mass, bone mineral content, skeletal muscle mass and body fat mass.

其中生物电阻抗分析包括身体细胞量、骨矿物质含量、骨骼肌含量和身体脂肪含量。

5.The bioelectrical impedance method has become a popular and widely used method to determine body composition.

生物电阻抗是近年来被广泛应用的一种快速、简便、安全测量体成分的方法。

6.Bioelectrical impedance technology is a detection technology which extracts biomedical information using the electrical characters of biological tissue and organs and their changes.

生物电阻抗技术，是利用生物组织与器官的电特性及其变化提取人体生物医学信息的一种检测技术。

7.This paper bases on the modern theory . First, the paper introduces filter methods and then discusses the modern analysis of bioelectrical-signal.

本文从现代理论出发，首先给出生物电信号的滤波方法，然后讨论生物电信号的现代分析方法。

8.Objective To evaluate the fluid balance and dry weight with whole body bioelectrical impedance analysis (BIA) in patients with maintenance hemodialysis (MHD).

目的采用全身生物电阻抗分析(BIA)法评估维持性血液透析(MHD)患者水平衡动态变化及干体质量。

9.Wearable devices that monitor bioelectrical 生物电的 activity have become increasingly popular.

监测bioelectrical 生物电的活动的可穿戴设备变得越来越受欢迎。

10.The heart generates bioelectrical 生物电的 impulses that regulate its rhythm.

心脏产生的bioelectrical 生物电的冲动调节其节律。

11.The bioelectrical 生物电的 impedance analysis can help assess body composition effectively.

使用bioelectrical 生物电的阻抗分析可以有效评估身体成分。

12.The study of bioelectrical 生物电的 signals in the human body can lead to advancements in medical technology.

研究人体内的bioelectrical 生物电的信号可以推动医疗技术的进步。

13.Researchers are exploring bioelectrical 生物电的 methods for treating neurological disorders.

研究人员正在探索用于治疗神经系统疾病的bioelectrical 生物电的方法。

作文

In recent years, the field of medicine has seen a remarkable advancement in understanding the role of the human body's natural electrical processes. One term that has gained significant attention is bioelectrical, which refers to the electrical signals produced by living organisms. These signals play a crucial role in various bodily functions, including muscle contractions, nerve impulses, and even cellular communication. The study of bioelectrical phenomena has opened new avenues for medical research and treatment, particularly in the areas of neurology and rehabilitation.The human body operates through a complex network of cells that communicate with each other using electrical impulses. This is where bioelectrical signals come into play. For instance, when a nerve cell is activated, it generates an electrical impulse that travels along its axon to transmit information to other neurons. This process is essential for everything from reflexes to conscious thought. Understanding how these bioelectrical signals work can lead to breakthroughs in treating neurological disorders such as epilepsy, Parkinson's disease, and multiple sclerosis.Moreover, the concept of bioelectrical activity extends beyond the nervous system. Muscle cells also rely on electrical signals to contract and relax. When your brain sends a signal to your muscles to move, it does so through a series of bioelectrical impulses. This understanding has significant implications for physical therapy and rehabilitation. By harnessing bioelectrical signals, therapists can develop targeted treatments to help patients recover from injuries or surgeries more effectively.One exciting application of bioelectrical research is in the development of prosthetic limbs. Engineers and scientists are working together to create prosthetics that can respond to the bioelectrical signals generated by the user's remaining muscles. This technology allows amputees to control their prosthetic devices with their thoughts, providing a sense of agency and improving their quality of life. Such innovations highlight the importance of understanding bioelectrical signals in creating more advanced and responsive medical devices.Furthermore, the study of bioelectrical phenomena is not limited to human health. Researchers are exploring the bioelectrical properties of plants and animals to understand how they interact with their environment. For example, some studies have shown that certain plants can generate electrical signals in response to stress, which may help them adapt to changing conditions. This knowledge could lead to advancements in agriculture, allowing us to develop crops that are more resilient to environmental challenges.In conclusion, the term bioelectrical encompasses a fascinating area of study that bridges biology and electrical engineering. As we continue to explore the intricacies of bioelectrical signals, we unlock new possibilities for medical treatments, rehabilitation techniques, and even advancements in agriculture. The future of bioelectrical research holds great promise, and it is an exciting time for scientists and medical professionals alike. By deepening our understanding of these natural electrical processes, we can improve health outcomes and enhance the quality of life for individuals around the world.

近年来，医学领域在理解人体自然电过程的作用方面取得了显著进展。一个备受关注的术语是生物电，它指的是由生物体产生的电信号。这些信号在各种身体功能中发挥着至关重要的作用，包括肌肉收缩、神经冲动，甚至细胞通信。对生物电现象的研究为医学研究和治疗开辟了新的途径，特别是在神经学和康复领域。人体通过复杂的细胞网络运作，这些细胞通过电冲动相互交流。这就是生物电信号发挥作用的地方。例如，当一个神经细胞被激活时，它会产生一个电冲动，该冲动沿着其轴突传播，以向其他神经元传递信息。这个过程对于从反射到意识思维的所有事物都是必不可少的。理解这些生物电信号的工作原理可以带来突破，帮助治疗癫痫、帕金森病和多发性硬化症等神经系统疾病。此外，生物电活动的概念不仅限于神经系统。肌肉细胞也依赖电信号进行收缩和放松。当你的大脑向肌肉发送移动信号时，它是通过一系列的生物电冲动来实现的。这种理解对物理治疗和康复具有重要意义。通过利用生物电信号，治疗师可以开发出有针对性的治疗方法，帮助患者更有效地从伤害或手术中恢复。生物电研究的一个令人兴奋的应用是假肢的开发。工程师和科学家正在共同努力，创造能够响应用户剩余肌肉产生的生物电信号的假肢。这项技术使截肢者能够用他们的思想控制假肢设备，提供了一种自主感，改善了他们的生活质量。这些创新突显了理解生物电信号在创建更先进和反应灵敏的医疗设备中的重要性。此外，生物电现象的研究并不限于人类健康。研究人员正在探索植物和动物的生物电特性，以了解它们如何与环境互动。例如，一些研究表明，某些植物在应对压力时可以产生电信号，这可能帮助它们适应变化的条件。这些知识可能导致农业的进步，使我们能够开发出对环境挑战更具韧性的作物。总之，生物电这个术语涵盖了一个迷人的研究领域，连接了生物学和电气工程。随着我们继续探索生物电信号的复杂性，我们为医学治疗、康复技术甚至农业的进步解锁了新的可能性。生物电研究的未来充满希望，对于科学家和医疗专业人员来说，都是一个激动人心的时刻。通过加深我们对这些自然电过程的理解，我们可以改善健康结果，提高全球个人的生活质量。