electrotonic

简明释义

英[ɪˌlektrəʊˈtɒnɪk]美[ɪˌlektrəˈtɑnɪk]

adj. 电紧张的

英英释义

单词用法

同义词

反义词

例句

1.Conclusion: t wave changes after ablation are most likely caused by electrotonic modulation, and are not a sign of myocardial injury.

结论：提示显性旁道射频消融术后T波改变为电张调整性T波改变，非心肌损伤所致。

2.Conclusion: t wave changes after ablation are most likely caused by electrotonic modulation, and are not a sign of myocardial injury.

结论：提示显性旁道射频消融术后T波改变为电张调整性T波改变，非心肌损伤所致。

3.Objective:To discuss the reason of misdiagnosis of acute myocardial infarction in electrotonic modulation T-wave change.

目的：探讨电张调整性T波改变患者被误诊为急性心肌梗塞的原因。

4.The scientist conducted an experiment to measure the effects of electrotonic 电传导的 stimulation on nerve cells.

科学家进行了实验，测量电传导的刺激对神经细胞的影响。

5.In neurology, understanding electrotonic 电传导的 properties is crucial for developing effective treatments.

在神经学中，理解电传导的特性对于开发有效的治疗方法至关重要。

6.The electrotonic 电传导的 response of the muscle fibers was recorded during the study.

在研究中记录了肌纤维的电传导的反应。

7.Researchers are exploring how electrotonic 电传导的 signaling can affect brain function.

研究人员正在探索电传导的信号如何影响大脑功能。

8.The electrotonic 电传导的 properties of neurons play a key role in synaptic transmission.

神经元的电传导的特性在突触传递中起着关键作用。

作文

In the realm of modern technology, the term electrotonic refers to the study and application of electrical phenomena in biological systems. This fascinating field combines principles from both electronics and biology, leading to innovative solutions for various medical and technological challenges. The word itself is derived from the combination of 'electro,' relating to electricity, and 'tonic,' which suggests a strengthening or invigorating effect. As we delve deeper into the implications of electrotonic devices and systems, we can see their profound impact on healthcare and beyond. One of the most significant applications of electrotonic technology is in the development of medical devices that enhance bodily functions. For example, pacemakers are electrotonic devices that regulate heart rhythms, ensuring that patients with arrhythmias can lead normal lives. These devices work by delivering electrical impulses to the heart muscle, prompting it to contract at a regular pace. The success of such technologies highlights the importance of understanding electrotonic principles in designing effective medical interventions. Moreover, the field of neuroprosthetics has greatly benefited from electrotonic advancements. Neuroprosthetics involves the use of electronic devices to restore lost sensory or motor functions. For instance, cochlear implants are electrotonic devices that provide a sense of sound to individuals who are profoundly deaf or severely hard of hearing. By converting sound waves into electrical signals and stimulating the auditory nerve, these implants allow users to perceive sounds, significantly improving their quality of life. Furthermore, electrotonic technologies have found applications in rehabilitation therapies. Functional Electrical Stimulation (FES) is a technique that uses electrical currents to stimulate muscles in individuals with paralysis or muscle weakness. By applying electrotonic principles, therapists can help patients regain movement and strength, facilitating recovery and enhancing mobility. The integration of electrotonic systems into everyday life is not limited to medical applications. In the field of entertainment, for example, virtual reality (VR) systems utilize electrotonic components to create immersive experiences. These systems rely on sensors and electrical signals to track user movements and provide real-time feedback, allowing users to interact with digital environments in a way that feels natural and engaging. As we continue to explore the potential of electrotonic innovations, it is essential to consider the ethical implications of such technologies. The ability to manipulate biological systems through electrical means raises questions about consent, privacy, and the long-term effects of these interventions. It is crucial for researchers, developers, and policymakers to engage in discussions about the responsible use of electrotonic technologies, ensuring that they benefit society as a whole. In conclusion, the term electrotonic encompasses a wide range of applications that bridge the gap between technology and biology. From medical devices that save lives to rehabilitation techniques that enhance recovery, the impact of electrotonic advancements is undeniable. As we move forward, embracing the possibilities of this exciting field while addressing its ethical considerations will be vital in shaping a future where technology and humanity coexist harmoniously.

在现代科技领域，术语electrotonic指的是电现象在生物系统中的研究和应用。这个迷人的领域结合了电子学和生物学的原则，为各种医疗和技术挑战提供了创新的解决方案。这个词本身源于'电'（electro）与'强壮'（tonic）的结合，暗示着一种增强或振奋的效果。随着我们深入探讨electrotonic设备和系统的影响，我们可以看到它们对医疗保健及其他领域的深远影响。 electrotonic技术最重要的应用之一是开发增强身体功能的医疗设备。例如，心脏起搏器就是一种electrotonic设备，它调节心律，确保心律失常患者能够正常生活。这些设备通过向心肌发出电脉冲来工作，促使其以规律的速度收缩。这种技术的成功突显了理解electrotonic原理在设计有效医疗干预措施中的重要性。 此外，神经假体领域也因electrotonic的进步而受益匪浅。神经假体涉及使用电子设备恢复丧失的感觉或运动功能。例如，人工耳蜗是一种electrotonic设备，为重度聋或严重听力损失的人提供声音感知。通过将声波转换为电信号并刺激听神经，这些植入物使用户能够感知声音，显著改善他们的生活质量。 此外，electrotonic技术还在康复治疗中找到了应用。功能性电刺激（FES）是一种使用电流刺激瘫痪或肌肉无力个体肌肉的技术。通过应用electrotonic原理，治疗师可以帮助患者恢复运动和力量，促进康复并增强活动能力。 将electrotonic系统整合到日常生活中不仅限于医疗应用。例如，在娱乐领域，虚拟现实（VR）系统利用electrotonic组件创造沉浸式体验。这些系统依赖传感器和电信号跟踪用户动作，并提供实时反馈，使用户能够以自然和引人入胜的方式与数字环境互动。 随着我们继续探索electrotonic创新的潜力，考虑这些技术的伦理影响至关重要。通过电手段操纵生物系统的能力引发了关于同意、隐私和这些干预的长期影响的问题。研究人员、开发者和政策制定者必须参与关于负责任使用electrotonic技术的讨论，确保它们惠及整个社会。 总之，术语electrotonic涵盖了广泛的应用，架起了技术与生物之间的桥梁。从拯救生命的医疗设备到增强恢复的康复技术，electrotonic进步的影响不可否认。随着我们向前发展，拥抱这一令人兴奋的领域的可能性，同时解决其伦理考虑，将在塑造一个技术与人类和谐共存的未来中至关重要。