trigger electrode

简明释义

触发电极

英英释义

例句

1.By placing the trigger electrode at the right location, we can improve the efficiency of the device.

通过将触发电极放置在正确的位置，我们可以提高设备的效率。

2.In our experiment, we adjusted the voltage of the trigger electrode to observe changes in response.

在我们的实验中，我们调整了触发电极的电压以观察响应的变化。

3.The trigger electrode is crucial in the functioning of deep brain stimulation systems.

在深脑刺激系统中，触发电极至关重要。

4.The researchers developed a new type of trigger electrode that minimizes tissue damage.

研究人员开发了一种新型的触发电极，能够最小化组织损伤。

5.The surgeon used a trigger electrode to initiate the heart's rhythm.

外科医生使用了一个触发电极来启动心脏的节律。

作文

In the field of biomedical engineering, the concept of a trigger electrode plays a crucial role in various applications, especially in the development of medical devices that interact with the human body. A trigger electrode is essentially a specialized electrode designed to initiate or control electrical signals in biological tissues. This functionality is vital for devices such as pacemakers, neural stimulators, and other implantable systems that require precise timing and control of electrical impulses.The significance of trigger electrodes can be observed in the functioning of cardiac pacemakers. These devices are implanted in patients with arrhythmias to regulate heartbeats. The trigger electrode within the pacemaker detects the heart’s natural electrical activity and sends out signals when it senses that the heart is beating too slowly or irregularly. By doing so, it helps maintain a steady rhythm, ensuring that the heart pumps blood efficiently throughout the body.Another notable application of trigger electrodes is found in deep brain stimulation (DBS) therapy for conditions like Parkinson's disease. In DBS, the trigger electrode is implanted in specific areas of the brain to modulate neuronal activity. When activated, these electrodes deliver electrical pulses that can alleviate symptoms such as tremors and rigidity. The precision of the trigger electrode is paramount, as it must selectively stimulate targeted neurons without affecting surrounding tissues.The design and implementation of trigger electrodes involve a multidisciplinary approach, incorporating materials science, electrical engineering, and biology. Researchers strive to develop electrodes that are biocompatible, durable, and capable of transmitting signals effectively. Innovations in materials, such as conducting polymers and nano-coatings, have enhanced the performance of trigger electrodes, allowing for better integration with biological systems and reducing the risk of inflammation or rejection by the body.Moreover, advancements in technology have led to the emergence of wireless trigger electrodes. These devices eliminate the need for physical connections, reducing the risk of infection and complications associated with traditional wired systems. Wireless trigger electrodes can be controlled remotely, enabling healthcare providers to adjust settings and monitor patients' conditions in real time, thus improving patient outcomes and quality of life.In conclusion, the role of trigger electrodes in modern medicine cannot be overstated. They are integral to the functionality of various therapeutic devices, helping to restore normal physiological functions and improve the lives of countless individuals. As research continues to advance, the future of trigger electrodes looks promising, with potential developments leading to even more sophisticated and effective medical technologies. Understanding the principles behind trigger electrodes and their applications is essential for anyone interested in the intersection of technology and healthcare, as they represent a significant leap forward in our ability to treat complex medical conditions effectively.

在生物医学工程领域，trigger electrode的概念在各种应用中发挥着至关重要的作用，尤其是在开发与人体互动的医疗设备方面。trigger electrode本质上是一种专门设计的电极，用于启动或控制生物组织中的电信号。这一功能对于诸如心脏起搏器、神经刺激器和其他需要精确时序和电信号控制的植入系统等设备至关重要。trigger electrode的重要性可以在心脏起搏器的功能中得到体现。这些设备被植入有心律失常的患者体内，以调节心跳。起搏器内的trigger electrode检测心脏的自然电活动，并在感知到心脏跳动过慢或不规律时发出信号。通过这样做，它有助于维持稳定的节奏，确保心脏有效地将血液泵送到全身。另一个显著的trigger electrode应用是在帕金森病等疾病的深脑刺激（DBS）治疗中。在DBS中，trigger electrode被植入大脑的特定区域，以调节神经元活动。当激活时，这些电极会传递电脉冲，从而减轻颤抖和僵硬等症状。trigger electrode的精确性至关重要，因为它必须选择性地刺激目标神经元，而不影响周围组织。trigger electrodes的设计和实施涉及多学科的方法，结合了材料科学、电气工程和生物学。研究人员努力开发生物相容性强、耐用且能够有效传递信号的电极。材料的创新，如导电聚合物和纳米涂层，增强了trigger electrodes的性能，使其能够更好地与生物系统集成，并降低炎症或机体排斥的风险。此外，技术的进步导致无线trigger electrodes的出现。这些设备消除了物理连接的需求，减少了感染和传统有线系统相关并发症的风险。无线trigger electrodes可以远程控制，使医疗服务提供者能够实时调整设置和监测患者的状况，从而改善患者的结果和生活质量。总之，trigger electrodes在现代医学中的作用不可低估。它们是各种治疗设备功能的核心，有助于恢复正常生理功能，改善无数个体的生活。随着研究的持续推进，trigger electrodes的未来看起来充满希望，潜在的发展可能导致更复杂和有效的医疗技术。理解trigger electrodes背后的原理及其应用对任何对技术与医疗交叉感兴趣的人来说都是至关重要的，因为它们代表了我们有效治疗复杂医疗条件的重大进步。