biological electronics

简明释义

生物电子学

英英释义

例句

1.The field of biological electronics 生物电子学 holds promise for creating sustainable energy sources from living organisms.

生物电子学领域有望从生物体中创造可持续能源。

2.Innovations in biological electronics 生物电子学 could lead to breakthroughs in brain-computer interface technology.

生物电子学的创新可能会导致脑机接口技术的突破。

3.Researchers are developing new devices that integrate biological electronics 生物电子学 to enhance medical diagnostics.

研究人员正在开发新设备，整合生物电子学以增强医疗诊断。

4.Scientists are exploring the use of biological electronics 生物电子学 to create smart sensors for environmental monitoring.

科学家们正在探索利用生物电子学创建智能传感器以进行环境监测。

5.The application of biological electronics 生物电子学 in prosthetics is revolutionizing how we approach limb replacement.

生物电子学在假肢中的应用正在彻底改变我们对肢体替代的看法。

作文

In the rapidly evolving field of technology and biology, the term biological electronics refers to the integration of electronic systems with biological entities. This interdisciplinary approach combines principles from both biology and electrical engineering to create devices that can interact with living organisms. The potential applications of biological electronics are vast and varied, ranging from medical diagnostics to environmental monitoring and even bio-computing.One of the most promising areas of biological electronics is in healthcare. Researchers are developing biosensors that can detect specific biomarkers in a patient's body, allowing for early diagnosis of diseases such as cancer or diabetes. These sensors can be implanted in the body or worn externally, providing real-time data to healthcare providers and enabling them to make informed decisions about treatment plans. For instance, glucose monitors that continuously track blood sugar levels in diabetic patients are a prime example of how biological electronics can improve patient care.Moreover, biological electronics can also enhance drug delivery systems. By creating smart drug delivery devices that respond to physiological changes in the body, we can ensure that medications are administered more effectively. This could lead to improved outcomes for patients who require precise dosing of their medications, such as those undergoing chemotherapy.Another fascinating application of biological electronics lies in the development of biohybrid systems. These systems combine living cells with synthetic materials to create new types of devices that can perform complex tasks. For example, researchers are exploring the use of muscle cells combined with electronic components to create artificial limbs that can mimic natural movement. This innovation could significantly enhance the quality of life for individuals with disabilities by providing them with greater mobility and independence.Furthermore, biological electronics has the potential to revolutionize the field of environmental monitoring. By utilizing living organisms as sensors, scientists can develop systems that detect pollutants or changes in environmental conditions. For instance, genetically modified bacteria could be used to identify the presence of heavy metals in water sources, providing crucial information for environmental protection efforts.Despite the remarkable potential of biological electronics, there are also ethical considerations that must be addressed. As we delve deeper into the integration of technology with biology, questions arise regarding the implications of manipulating living organisms. Issues related to biosecurity, privacy, and the potential for unintended consequences must be carefully considered as we move forward in this field.In conclusion, biological electronics represents a groundbreaking intersection of biology and technology that holds immense promise for the future. From improving healthcare outcomes to enhancing environmental sustainability, the applications of this field are diverse and impactful. However, it is essential to navigate the ethical challenges that accompany these advancements to ensure that we harness the full potential of biological electronics responsibly and sustainably.

在快速发展的技术和生物学领域，术语生物电子学指的是电子系统与生物实体的结合。这种跨学科的方法结合了生物学和电气工程的原理，创造出能够与生物体相互作用的设备。生物电子学的潜在应用广泛多样，从医疗诊断到环境监测，甚至生物计算都有涉及。生物电子学最有前景的领域之一是医疗保健。研究人员正在开发能够检测患者体内特定生物标志物的生物传感器，从而实现早期疾病诊断，例如癌症或糖尿病。这些传感器可以植入体内或外部佩戴，实时向医疗提供者提供数据，使他们能够就治疗方案做出明智的决策。例如，持续跟踪糖尿病患者血糖水平的葡萄糖监测仪就是生物电子学如何改善患者护理的一个典型例子。此外，生物电子学还可以增强药物递送系统。通过创建能够对身体生理变化作出反应的智能药物递送设备，我们可以确保药物更有效地给药。这可能会改善需要精确药物剂量的患者的结果，例如那些接受化疗的患者。生物电子学的另一个迷人应用在于生物混合系统的开发。这些系统将活细胞与合成材料结合在一起，以创造出能够执行复杂任务的新型设备。例如，研究人员正在探索将肌肉细胞与电子元件结合以创建能够模仿自然运动的人工肢体。这一创新可能显著提升残疾人士的生活质量，使他们获得更大的移动性和独立性。此外，生物电子学还有潜力彻底改变环境监测领域。通过利用生物体作为传感器，科学家们可以开发检测污染物或环境条件变化的系统。例如，转基因细菌可以用来识别水源中重金属的存在，为环境保护工作提供至关重要的信息。尽管生物电子学具有非凡的潜力，但也必须解决伦理问题。随着我们深入探讨技术与生物学的结合，关于操控生物体的影响的问题随之而来。与生物安全、隐私以及潜在的意外后果相关的问题必须在我们推进这一领域时加以认真考虑。总之，生物电子学代表了生物学与技术之间的突破性交集，蕴含着巨大的未来潜力。从改善医疗结果到增强环境可持续性，这一领域的应用多样且具有深远影响。然而，必须妥善处理伴随这些进步而来的伦理挑战，以确保我们以负责任和可持续的方式充分利用生物电子学的全部潜力。