morphometry

简明释义

英[/mɔːrˈfɒmətri/]美[/mɔːrˈfɒmətri/]

n. 形态测量学；形态计量术

英英释义

单词用法

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反义词

例句

1.As follows: 1, Morphometry research of esophageal carcinoma.

包括：1、食管癌的形态定量学研究。

2.Further analysis of morphometry confirmed that the size of IL-2 gene modified K562 cells was increased. The ratio of giant cells was higher than that of nontransduced K562 cells.

进一步形态计量学分析证实IL-2基因修饰的K562细胞体积增大，巨大细胞出现率显著高于未转导的K562细胞。

3.Objective:To find out a new reliable index in pathological morphometry.

目的探索形态定量在病理诊断中的新指标。

4.The DNA content and nucleus morphometry may be regarded as one of the useful indicators for the pathological diagnosis and clinical prognosis of breast carcinoma.

乳腺癌细胞核形态参数和DNA含量可作为乳腺癌诊断、预后判定的指标之一。

5.Vertebral morphometry by X-ray absorptiometry: Which reference data for vertebral heights?

线骨密度仪测定的椎体形态学：椎体高度的参考数据？

6.Purpose 1. To analyse the difference of going position and morphometry of pulmonary artery and pulmonary vein of pig lung, by anatomizing them respectively.

目的1.对猪的肺动脉、肺静脉进行分别解剖，分析肺动脉、肺静脉走行位置、形态学的差异。

7.Effects of Bushenfugai Traditional Chinese Medicine on morphometry of osteoporosis induced by ovary irradiation in rats;

目的研究纳米钙补肾中药对糖皮质激素致骨质疏松大鼠髋关节骨与肌肉的影响。

8.Using morphometry, researchers can analyze the growth patterns of various species.

通过使用形态计量学，研究人员可以分析各种物种的生长模式。

9.Recent advances in morphometry technology allow for more precise measurements of anatomical structures.

最近在形态计量学技术方面的进展允许对解剖结构进行更精确的测量。

10.The study of brain structure often involves morphometry, which helps in understanding neurological disorders.

脑结构的研究通常涉及形态计量学，这有助于理解神经系统疾病。

11.The morphometry of fish can provide insights into their health and habitat conditions.

鱼类的形态计量学可以提供关于它们健康和栖息地条件的见解。

12.In ecology, morphometry is essential for studying the adaptations of organisms to their environments.

在生态学中，形态计量学对于研究生物适应其环境至关重要。

作文

Morphometry is a term that refers to the quantitative measurement of the form and structure of organisms or their parts. In the field of biology, understanding the shape and size of organisms can provide valuable insights into their function, evolution, and adaptation. The study of morphometry has become increasingly important in various scientific disciplines, including ecology, anthropology, and medicine. By analyzing the morphological features of different species, researchers can uncover patterns that may not be immediately apparent through qualitative observations alone.For instance, in ecology, morphometry can help scientists understand how different species adapt to their environments. By measuring the size and shape of leaves, flowers, or even animal limbs, ecologists can determine how these traits influence survival and reproduction. This quantitative approach allows for more rigorous comparisons between species and can shed light on the evolutionary pressures that shape their forms.In anthropology, morphometry plays a crucial role in studying human evolution. By examining the skeletal remains of ancient populations, anthropologists can gain insights into their physical characteristics, health, and lifestyles. For example, the analysis of cranial measurements can reveal information about brain size and cognitive abilities, while limb proportions can indicate mobility and lifestyle adaptations. Such studies contribute to our understanding of human ancestry and the factors that have influenced our development as a species.Moreover, morphometry is also significant in the medical field. Medical professionals use morphometric analysis to assess abnormalities in human anatomy. For instance, the study of heart shapes and sizes can help diagnose cardiovascular diseases, while brain morphometry can assist in identifying neurological disorders. By utilizing advanced imaging techniques such as MRI and CT scans, doctors can perform detailed morphometric analyses that lead to better patient outcomes.The advancements in technology have greatly enhanced the capabilities of morphometry. With the advent of computer software and imaging techniques, researchers can now analyze complex morphological data with greater accuracy and efficiency. These tools allow for the visualization and manipulation of three-dimensional models, providing deeper insights into the relationships between form and function.In conclusion, morphometry is a multifaceted field that bridges various scientific disciplines, offering a quantitative perspective on the study of biological forms. Whether in ecology, anthropology, or medicine, the insights gained from morphometric analyses are invaluable for understanding the complexities of life. As research continues to evolve, the importance of morphometry in revealing the intricacies of organismal design will undoubtedly grow, paving the way for new discoveries and applications in science and medicine.

形态测量是一个术语，指的是对生物或其部分的形状和结构进行定量测量。在生物学领域，理解生物体的形状和大小可以为其功能、进化和适应提供有价值的见解。形态测量的研究在生态学、人类学和医学等多个科学学科中变得越来越重要。通过分析不同物种的形态特征，研究人员可以发现一些仅通过定性观察无法立即显现的模式。例如，在生态学中，形态测量可以帮助科学家理解不同物种如何适应其环境。通过测量叶子、花朵甚至动物肢体的大小和形状，生态学家可以确定这些特征如何影响生存和繁殖。这种定量方法允许对物种之间进行更严格的比较，并能揭示塑造其形态的进化压力。在人类学中，形态测量在研究人类进化方面发挥着至关重要的作用。通过检查古代人群的骨骼遗骸，人类学家可以深入了解他们的身体特征、健康状况和生活方式。例如，颅骨测量的分析可以揭示大脑大小和认知能力的信息，而肢体比例则可以指示出机动性和生活方式的适应。这些研究有助于我们理解人类祖先及影响我们作为一个物种发展的因素。此外，形态测量在医学领域也具有重要意义。医疗专业人员使用形态测量分析来评估人体解剖结构的异常。例如，心脏的形状和大小的研究可以帮助诊断心血管疾病，而大脑形态测量可以帮助识别神经系统疾病。通过利用MRI和CT扫描等先进成像技术，医生可以进行详细的形态测量分析，从而改善患者的治疗效果。技术的进步大大增强了形态测量的能力。随着计算机软件和成像技术的出现，研究人员现在可以以更高的准确性和效率分析复杂的形态数据。这些工具允许可视化和操作三维模型，从而提供对形态与功能之间关系的更深入见解。总之，形态测量是一个多方面的领域，连接了多个科学学科，为生物形态研究提供了定量视角。无论是在生态学、人类学还是医学中，从形态测量分析中获得的见解对于理解生命的复杂性都是无价的。随着研究的不断发展，形态测量在揭示生物设计复杂性方面的重要性无疑会增长，为科学和医学中的新发现和应用铺平道路。