bioelectricity
简明释义
英[ˌbaɪəʊˌɪlekˈtrɪsɪti]美[ˈbaɪoɪlekˈtrɪsɪti]
n. 生物电(流)
英英释义
Bioelectricity refers to the electrical phenomena related to living organisms, including the generation and conduction of electric signals in cells and tissues. | 生物电是指与生物体相关的电现象,包括细胞和组织中电信号的产生和传导。 |
单词用法
生物电生成 | |
生物电测量 | |
生物电应用 | |
生物电现象 | |
生物电信号 | |
生物电位 | |
生物电活动 | |
生物电研究 | |
生物电系统 | |
生物电设备 |
同义词
反义词
例句
1.The examination instruments about the medical bioelectricity were used widely in the clinical field. But the most common instruments were electrocardiogram and electroencephalogram.
医用生物电诊断仪器在临床是普遍使用,但最常用的是心电图和脑电图。
2.The part about bioelectricity is one of the most important parts of physiology, and one of the teaching difficulties of physiology.
生物电是生理学的重要内容之一,也是生理学的教学难点。
3.Due to its relative low amplitude properties, the bioelectricity signal is easy influenced by surrounding factor, the amplifier with low noise and voltage offset is required.
由于生物电信号非常微弱,容易受量测环境及电路本身等因素所影响,故要求该放大器具有低噪声和低失调电压的性能。
4.The paper shows the inherent relationship between freshness of chicken egg and frequency of its bioelectricity, thus launching a kind of research direction for egg quality evaluation.
本研究发现鸡蛋的新鲜度与其生物电信号的频率结构之间存在一定的相关性,为蛋品品质评定提出了一个新的研究方向。
5.Bioelectricity is created the same way fossil fuel-generated electricity is: Biomass is usually burned to generate heat, turning water to steam and driving an electrical generator.
生物电能的产生跟化石燃料的产生的电能相同:生物物质经常被焚烧产热,把水变成蒸汽,然后驱动发电机。
6.A small SUV powered by bioelectricity could travel nearly 14, 000 miles on the energy produced by an acre of switchgrass, while an ethanol-powered SUV could go only 9, 000 miles.
一辆小的生物电能的越野车能行走14,000英里,在用每英亩的柳枝稷供能下,而一辆酒精供能的越野车只能行走9,000英里。
7.The muscle will produce tiny change of bioelectricity. The amplitude and power spectrum of SEMG will change with muscular movement.
肌肉运动时会有很小的生物电变化,表面肌电图的振幅、频谱指标均会发生相应变化。
8.The heart's rhythm is regulated by bioelectricity generated by specialized cells.
心脏的节奏由特殊细胞产生的生物电调节。
9.The study of bioelectricity has led to advancements in medical devices.
对生物电的研究推动了医疗设备的进步。
10.Understanding bioelectricity is crucial for developing new therapies for nerve damage.
理解生物电对于开发治疗神经损伤的新疗法至关重要。
11.Researchers are investigating the role of bioelectricity in wound healing processes.
研究人员正在调查生物电在伤口愈合过程中的作用。
12.Scientists are exploring how bioelectricity can be harnessed for energy production.
科学家们正在探索如何利用生物电进行能源生产。
作文
Bioelectricity is a fascinating field of study that merges biology and electricity. It refers to the electrical phenomena that occur in living organisms, which play a crucial role in various physiological processes. Understanding bioelectricity (生物电) can help us gain insights into how our bodies function and how we can harness this knowledge for medical advancements.One of the most significant examples of bioelectricity (生物电) in action is the way our nerves communicate. Neurons, the basic units of the nervous system, transmit signals through electrical impulses. When a neuron is activated, it generates an electrical charge that travels along its axon to communicate with other neurons or muscle cells. This process is essential for everything from reflex actions to complex thought processes. By studying bioelectricity (生物电), scientists can better understand neurological disorders and develop treatments for conditions such as epilepsy or multiple sclerosis.In addition to the nervous system, bioelectricity (生物电) is also vital in muscle contractions. When a muscle cell receives an electrical signal, it triggers a series of biochemical reactions that lead to contraction. This mechanism is not only important for voluntary movements, such as walking or lifting objects, but also for involuntary functions, like the beating of the heart. Research into bioelectricity (生物电) has led to innovations in cardiac care, including pacemakers that help regulate heartbeats by delivering electrical impulses.Moreover, bioelectricity (生物电) has implications for regenerative medicine. Scientists are exploring how electrical signals can influence cell behavior, potentially leading to breakthroughs in tissue engineering and healing. For instance, applying specific electrical currents to injured tissues may promote faster healing and regeneration. This exciting area of research highlights the potential of bioelectricity (生物电) in developing new therapies for injuries and degenerative diseases.The study of bioelectricity (生物电) is not limited to human biology. Many animals exhibit remarkable bioelectric properties. Electric fish, for example, generate strong electric fields to navigate their environments and communicate with each other. Researchers are investigating these natural phenomena to inspire new technologies, such as bio-inspired sensors and communication devices. This cross-disciplinary approach showcases the importance of understanding bioelectricity (生物电) beyond just human health.In conclusion, bioelectricity (生物电) is a vital aspect of life that influences numerous biological processes. From nerve signaling to muscle contractions and even regenerative medicine, the applications of bioelectricity (生物电) are vast and varied. As research continues to advance, we can expect to see even more innovative uses of this phenomenon in medicine and technology. The exploration of bioelectricity (生物电) not only enhances our understanding of biology but also paves the way for future discoveries that could improve human health and well-being.
生物电是一个迷人的研究领域,它融合了生物学和电学。它指的是在生物体中发生的电现象,这些现象在各种生理过程中发挥着至关重要的作用。理解生物电(bioelectricity)可以帮助我们深入了解身体如何运作,以及我们如何利用这些知识推动医学进步。生物电(bioelectricity)最显著的例子之一就是我们的神经如何交流。神经元是神经系统的基本单位,通过电冲动传递信号。当一个神经元被激活时,它会产生一个电荷沿着其轴突传播,以与其他神经元或肌肉细胞沟通。这个过程对从反射动作到复杂思维过程的一切都至关重要。通过研究生物电(bioelectricity),科学家们可以更好地理解神经系统疾病,并开发治疗癫痫或多发性硬化症等疾病的方法。除了神经系统,生物电(bioelectricity)在肌肉收缩中也至关重要。当肌肉细胞接收到电信号时,它会触发一系列生化反应,导致收缩。这个机制不仅对自愿运动(如走路或举重)重要,而且对不随意功能(如心脏的跳动)也很重要。对生物电(bioelectricity)的研究促成了心脏护理的创新,包括帮助调节心跳的起搏器,通过传递电冲动来实现。此外,生物电(bioelectricity)在再生医学中也有重要意义。科学家们正在探索电信号如何影响细胞行为,可能导致组织工程和愈合方面的突破。例如,将特定的电流应用于受伤组织可能促进更快的愈合和再生。这一激动人心的研究领域突显了生物电(bioelectricity)在开发新疗法方面的潜力,尤其是针对伤害和退行性疾病。生物电(bioelectricity)的研究不仅限于人类生物学。许多动物表现出显著的生物电特性。例如,电鱼产生强大的电场以导航环境并相互交流。研究人员正在调查这些自然现象,以激发新技术,例如仿生传感器和通信设备。这种跨学科的方法展示了理解生物电(bioelectricity)的重要性,超越了人类健康的范畴。总之,生物电(bioelectricity)是生命的一个重要方面,影响着许多生物过程。从神经信号到肌肉收缩,甚至再生医学,生物电(bioelectricity)的应用广泛而多样。随着研究的不断推进,我们可以期待看到这一现象在医学和技术中的更多创新用途。对生物电(bioelectricity)的探索不仅增强了我们对生物学的理解,还为未来的发现铺平了道路,这些发现可能改善人类的健康和福祉。
