micrographic

简明释义

英[ˌmaɪkrəʊˈɡræfɪk]美[maɪkrəˈɡræfɪk]

adj. 微文象状的；显微照相的

英英释义

单词用法

同义词

反义词

例句

1.Published recurrence rates are 12% to 51% for surgical excision and 4% for Mohs micrographic surgery.

文献中外科切除后的复发率为12% - 51%，莫斯显微镜切除的复发率为4%。

2.We retrospectively reviewed pigmented basal cell carcinomas treated with Mohs micrographic surgery in Kaohsiung Chang-Gung Memorial Hospital from 1996 to 2002.

此篇则是由1996到2002年间于高雄长庚纪念医院皮肤科进行莫氏手术的原发性的着色型基底细胞癌。

3.Micrographic test results showed that under different loading different elements in EP additives will play main role correspondingly, so most of additives are of compound type.

对试件表面进行显微分析看出，载荷不同时，添加剂中不同元素在起主要作用，故添加剂多为复合型。

4.Micrographic test results showed that under different loading different elements in EP additives will play main role correspondingly, so most of additives are of compound type.

对试件表面进行显微分析看出，载荷不同时，添加剂中不同元素在起主要作用，故添加剂多为复合型。

5.The micrographic 微观图像的 analysis revealed important details about the disease progression.

该微观图像的分析揭示了关于疾病进展的重要细节。

6.In the study, researchers focused on the micrographic 微观图像的 features of cancer cells.

在这项研究中，研究人员专注于癌细胞的微观图像的特征。

7.The micrographic 微观图像的 examination helped identify the type of tissue present in the biopsy.

对活检的微观图像的检查帮助识别了样本中存在的组织类型。

8.Using micrographic 微观图像的 techniques, scientists were able to visualize cellular structures in greater detail.

利用微观图像的技术，科学家能够更详细地可视化细胞结构。

9.The pathologist examined the tissue sample under a microscope, looking for any micrographic 微观图像的 changes.

病理学家在显微镜下检查组织样本，寻找任何微观图像的变化。

作文

In the field of science and technology, the term micrographic is often used to describe a method of capturing detailed images at a microscopic level. This technique plays a crucial role in various disciplines, such as biology, materials science, and medicine. The ability to observe structures that are not visible to the naked eye allows researchers to gain insights into the fundamental components of matter and living organisms. For instance, in biological research, micrographic images can reveal the intricate details of cellular structures, helping scientists understand how cells function and interact with one another.One of the most significant applications of micrographic techniques is in histology, the study of tissues. By preparing thin slices of tissue samples and examining them under a microscope, pathologists can identify abnormalities that may indicate diseases such as cancer. The micrographic images obtained from these examinations are essential for accurate diagnoses and treatment plans. Moreover, advancements in micrographic imaging technologies, such as electron microscopy and confocal microscopy, have enhanced our ability to visualize and analyze biological specimens with unprecedented clarity.In addition to its applications in biology, micrographic techniques are also vital in materials science. Researchers use micrographic imaging to study the microstructure of materials, which can significantly influence their properties and performance. For example, the distribution of grains in metals or the arrangement of polymers can be analyzed using micrographic methods. Understanding these microstructural features allows engineers to design materials with specific characteristics, leading to innovations in various industries, including aerospace, automotive, and electronics.Furthermore, the importance of micrographic analysis extends to the field of forensic science. Forensic experts often rely on micrographic techniques to examine trace evidence, such as hair, fibers, and gunshot residue. By analyzing these tiny samples, they can provide crucial information that may link a suspect to a crime scene. The precision and detail offered by micrographic imaging are invaluable in solving criminal cases and ensuring justice.As technology continues to advance, the capabilities of micrographic techniques are expanding. Innovations such as three-dimensional (3D) micrographic imaging allow scientists to create detailed models of biological and material structures, providing even deeper insights into their functions and behaviors. This evolution in micrographic technology promises to revolutionize our understanding of complex systems, from the smallest cellular processes to the behavior of advanced materials.In conclusion, the term micrographic encompasses a range of techniques that enable the visualization and analysis of structures at a microscopic level. Its applications span across multiple fields, including biology, materials science, and forensic science, highlighting its significance in advancing knowledge and innovation. As we continue to explore the microscopic world, the role of micrographic techniques will undoubtedly become increasingly important, driving discoveries that can change our understanding of life and material properties forever.

在科学和技术领域，术语micrographic通常用于描述一种在微观水平捕捉详细图像的方法。这种技术在生物学、材料科学和医学等多个学科中发挥着至关重要的作用。观察肉眼无法看到的结构的能力使研究人员能够深入了解物质和生物体的基本组成。例如，在生物研究中，micrographic图像可以揭示细胞结构的复杂细节，帮助科学家理解细胞如何功能和相互作用。micrographic技术最重要的应用之一是在组织学中，即组织的研究。通过准备薄切片的组织样本并在显微镜下检查它们，病理学家可以识别可能表明癌症等疾病的异常情况。从这些检查中获得的micrographic图像对于准确的诊断和治疗计划至关重要。此外，电子显微镜和共聚焦显微镜等micrographic成像技术的进步增强了我们以空前的清晰度可视化和分析生物样本的能力。除了在生物学中的应用外，micrographic技术在材料科学中也至关重要。研究人员使用micrographic成像来研究材料的微观结构，这可以显著影响它们的性质和性能。例如，可以使用micrographic方法分析金属中的晶粒分布或聚合物的排列。理解这些微观结构特征使工程师能够设计具有特定特性的材料，从而推动航空航天、汽车和电子等各个行业的创新。此外，micrographic分析的重要性还扩展到法医学领域。法医专家通常依赖于micrographic技术来检查微量证据，如头发、纤维和枪击残留物。通过分析这些微小样本，他们可以提供关键的信息，可能将嫌疑人与犯罪现场联系起来。micrographic成像所提供的精确性和细节在解决刑事案件和确保公正方面是无价的。随着技术的不断进步，micrographic技术的能力也在不断扩展。三维（3D）micrographic成像等创新使科学家能够创建生物和材料结构的详细模型，从而提供更深入的对其功能和行为的理解。这种micrographic技术的演变承诺将彻底改变我们对复杂系统的理解，从最小的细胞过程到先进材料的行为。总之，术语micrographic涵盖了一系列使在微观水平上可视化和分析结构的技术。它的应用跨越多个领域，包括生物学、材料科学和法医学，突显了它在推动知识和创新方面的重要性。随着我们继续探索微观世界，micrographic技术的角色无疑会变得越来越重要，推动可以永远改变我们对生命和材料属性理解的发现。