microtechnique

简明释义

英[ˌmaɪkrəʊtɛkˈniːk]美[ˌmaɪkrəˈtɛknik]

n. 微量技术；显微镜技术

英英释义

单词用法

同义词

反义词

例句

1.By using scan electron microtechnique and thermal analysis, wood plastic composite mechanism is studied.

采用扫描电子显微技术和热分析对木塑复合机理进行研究。

2.By using scan electron microtechnique and thermal analysis, wood plastic composite mechanism is studied.

采用扫描电子显微技术和热分析对木塑复合机理进行研究。

3.Researchers employed microtechnique to isolate specific proteins from complex mixtures.

研究人员采用微技术从复杂混合物中分离特定蛋白质。

4.In the field of materials science, microtechnique is used to study the properties of nanomaterials.

在材料科学领域，微技术用于研究纳米材料的特性。

5.The application of microtechnique in forensic science has improved the accuracy of evidence analysis.

在法医学中应用微技术提高了证据分析的准确性。

6.The use of microtechnique in cellular biology has revolutionized how we study cell structures.

在细胞生物学中使用微技术彻底改变了我们研究细胞结构的方式。

7.With advancements in microtechnique, scientists can now visualize DNA at unprecedented resolutions.

随着微技术的进步，科学家们现在可以以前所未有的分辨率可视化DNA。

作文

In the realm of scientific research and medical advancements, the term microtechnique (微技术) has gained significant importance. It refers to a set of specialized techniques and procedures used to manipulate and analyze materials at a microscopic scale. These methods are crucial in various fields, including biology, materials science, and nanotechnology. The development of microtechnique (微技术) has revolutionized the way researchers approach complex problems, allowing them to observe and interact with structures that were previously beyond our reach.One of the most prominent applications of microtechnique (微技术) is in the field of cellular biology. Researchers utilize these techniques to study the intricate details of cell structures and functions. For instance, techniques such as microdissection enable scientists to isolate specific cells from tissues, allowing for in-depth analysis of cellular behavior and interaction. This level of precision is essential for understanding diseases at a fundamental level, leading to breakthroughs in treatment and prevention.Moreover, microtechnique (微技术) plays a vital role in the advancement of nanotechnology. The ability to manipulate materials at the nanoscale opens up new possibilities for creating innovative materials and devices. For example, researchers can use microtechnique (微技术) to fabricate nanoscale components for electronic devices, leading to faster and more efficient technology. This has far-reaching implications for industries ranging from computing to renewable energy, as smaller and more efficient components can lead to significant improvements in performance and sustainability.In addition to its applications in biology and materials science, microtechnique (微技术) is also pivotal in the field of medicine. Surgical techniques have evolved dramatically with the introduction of microsurgical methods, which rely on microtechnique (微技术) to perform delicate procedures with minimal invasiveness. Surgeons can now operate on tiny structures within the body using specialized instruments and magnification tools, resulting in reduced recovery times and improved patient outcomes.Furthermore, the integration of microtechnique (微技术) with imaging technologies has enhanced our ability to visualize and understand complex biological systems. Techniques like fluorescence microscopy allow researchers to tag specific molecules within cells, providing insights into their functions and interactions. This combination of microtechnique (微技术) and advanced imaging has opened new avenues for research, enabling scientists to explore the dynamics of life at an unprecedented scale.As we look to the future, the potential of microtechnique (微技术) continues to expand. Ongoing research aims to refine these techniques further, making them more accessible and versatile across different fields. The implications of these advancements are profound, as they not only enhance our understanding of the natural world but also pave the way for innovative solutions to some of the most pressing challenges we face today.In conclusion, microtechnique (微技术) represents a critical area of study that bridges various scientific disciplines. Its applications in biology, materials science, and medicine highlight its significance in advancing our knowledge and improving our quality of life. As technology progresses, the role of microtechnique (微技术) will undoubtedly grow, leading to exciting discoveries and innovations that could transform our world.

在科学研究和医学进步的领域中，术语microtechnique（微技术）变得越来越重要。它指的是一系列用于操纵和分析微观尺度材料的专业技术和程序。这些方法在生物学、材料科学和纳米技术等多个领域至关重要。microtechnique（微技术）的发展彻底改变了研究人员解决复杂问题的方法，使他们能够观察和与以前超出我们触及范围的结构进行互动。microtechnique（微技术）最突出的一项应用是在细胞生物学领域。研究人员利用这些技术研究细胞结构和功能的复杂细节。例如，微解剖技术使科学家能够从组织中分离特定细胞，从而深入分析细胞行为和相互作用。这种精确的水平对理解疾病的基本机制至关重要，促进了治疗和预防方面的突破。此外，microtechnique（微技术）在纳米技术的发展中也发挥着至关重要的作用。在纳米尺度上操纵材料的能力为创造创新材料和设备开辟了新的可能性。例如，研究人员可以使用microtechnique（微技术）制造电子设备的纳米级组件，从而实现更快和更高效的技术。这对从计算机到可再生能源等行业具有深远的影响，因为更小和更高效的组件可以显著提高性能和可持续性。除了在生物学和材料科学中的应用外，microtechnique（微技术）在医学领域也至关重要。随着显微外科方法的引入，外科技术发生了巨大变化，这些方法依赖于microtechnique（微技术）以最小的侵入性进行精细手术。外科医生现在可以使用专业工具和放大工具对身体内的小结构进行操作，从而缩短恢复时间并改善患者的结果。此外，microtechnique（微技术）与成像技术的结合增强了我们可视化和理解复杂生物系统的能力。荧光显微镜等技术允许研究人员在细胞内标记特定分子，从而提供关于其功能和相互作用的见解。microtechnique（微技术）与先进成像的结合为研究开辟了新途径，使科学家能够以前所未有的规模探索生命的动态。展望未来，microtechnique（微技术）的潜力仍在不断扩大。持续的研究旨在进一步完善这些技术，使其在不同领域更具可及性和多功能性。这些进展的影响深远，因为它们不仅增强了我们对自然世界的理解，还为一些我们今天面临的最紧迫挑战提供了创新解决方案。总之，microtechnique（微技术）代表了一个关键的研究领域，连接着各种科学学科。它在生物学、材料科学和医学中的应用突显了其在推动我们知识进步和改善生活质量方面的重要性。随着技术的进步，microtechnique（微技术）的角色无疑将不断增长，带来令人兴奋的发现和创新，可能会改变我们的世界。