scutellar

简明释义

英[ˌskjuːˈtɛlər]美[ˌskjuːˈtɛlər]

盾片的

角质鳞片的

英英释义

单词用法

同义词

反义词

例句

1.The number of protein body was increasing with reducing of starch grains in scutellar development late stage.

盾片发育后期，淀粉粒逐渐减少，蛋白质体增多。

2.The number of protein body was increasing with reducing of starch grains in scutellar development late stage.

盾片发育后期，淀粉粒逐渐减少，蛋白质体增多。

3.The scutellar 盾状的 region of the insect's thorax is often used for identification.

昆虫胸部的scutellar盾状的区域通常用于鉴别。

4.In many beetles, the scutellar 盾状的 plate is a key feature for classification.

在许多甲虫中，scutellar盾状的板是分类的关键特征。

5.The scutellar 盾状的 markings on the butterfly's wings can indicate its species.

蝴蝶翅膀上的scutellar盾状的标记可以指示其物种。

6.Entomologists study the scutellar 盾状的 structure to understand evolutionary relationships.

昆虫学家研究scutellar盾状的结构以理解进化关系。

7.The scutellar 盾状的 area can vary significantly between different species of moths.

不同种类的蛾子之间，scutellar盾状的区域可能有显著差异。

作文

In the study of entomology, the term scutellar refers to a specific part of an insect's anatomy, particularly associated with the scutellum, which is a small shield-like structure located on the dorsal side of the thorax. Understanding the scutellar region is essential for entomologists who seek to classify and differentiate between various insect species. The scutellum plays a crucial role in the overall morphology of insects, influencing their flight dynamics and behavior. For instance, in beetles, the shape and size of the scutellar plate can vary significantly, indicating adaptations to different ecological niches. This variation can provide insights into the evolutionary pathways that led to the diversification of insect species. The scutellar structure is not only important for classification but also serves functional purposes. In many species, it aids in the protection of vital organs during flight or when the insect is at rest. The hard exoskeleton covering the scutellar area acts as armor against predators, while its design can help in stabilizing the insect during aerial maneuvers. Observing these features under a microscope can reveal intricate details about how the scutellar region interacts with other parts of the insect's body, such as the wings and legs. Moreover, the significance of the scutellar region extends beyond morphology and classification. It is also a focal point in studies related to insect physiology and ecology. For example, researchers have discovered that certain species exhibit unique adaptations in their scutellar structures that allow them to thrive in specific environments. These adaptations may include changes in color, texture, and even chemical composition, all of which can affect the insect's ability to camouflage, thermoregulate, or communicate with others. In agricultural contexts, understanding the scutellar features of pest insects can lead to more effective pest management strategies. By identifying key traits associated with harmful species, entomologists can develop targeted approaches to control populations without adversely affecting beneficial insects. This knowledge becomes particularly valuable in sustainable agriculture, where maintaining biodiversity is crucial for ecological balance. Furthermore, the scutellar region has implications in the field of biomimicry, where scientists and engineers draw inspiration from nature to solve human challenges. The design of the scutellar structure, with its combination of strength and lightweight properties, has potential applications in materials science and engineering. By studying how insects utilize their scutellar features, researchers can innovate new materials that mimic these properties, leading to advancements in technology and design. In conclusion, the term scutellar encapsulates a wealth of information regarding insect anatomy, functionality, and ecological significance. From aiding in species classification to inspiring technological innovations, the scutellar region is a prime example of how a seemingly small anatomical feature can have far-reaching implications in various fields of study. As research continues to evolve, the importance of understanding the scutellar structures will undoubtedly grow, providing deeper insights into the fascinating world of insects and their roles within ecosystems.

在昆虫学的研究中，术语scutellar指的是昆虫解剖中特定的部分，特别与背部的一个小盾状结构——背板（scutellum）相关。理解scutellar区域对于寻求对各种昆虫物种进行分类和区分的昆虫学家至关重要。背板在昆虫的整体形态中起着关键作用，影响它们的飞行动态和行为。例如，在甲虫中，scutellar板的形状和大小可以显著变化，表明其适应了不同的生态位。这种变化可以提供关于导致昆虫物种多样化的进化路径的见解。 scutellar结构不仅对分类重要，还具有功能性目的。在许多物种中，它有助于在飞行或昆虫静止时保护重要器官。覆盖scutellar区域的坚硬外骨骼充当防御装甲，以抵御捕食者，而其设计可以帮助稳定昆虫在空中机动时的姿态。在显微镜下观察这些特征，可以揭示scutellar区域如何与昆虫身体的其他部分（如翅膀和腿）相互作用的复杂细节。 此外，scutellar区域的重要性超越了形态学和分类学。它也是与昆虫生理学和生态学相关研究的焦点。例如，研究人员发现某些物种在其scutellar结构中表现出独特的适应性，使它们能够在特定环境中生存。这些适应可能包括颜色、纹理甚至化学成分的变化，所有这些都可以影响昆虫的伪装能力、热调节能力或与其他昆虫的交流能力。 在农业背景下，了解害虫的scutellar特征可以带来更有效的害虫管理策略。通过识别与有害物种相关的关键特征，昆虫学家可以制定针对性的控制方法，而不会对有益昆虫产生不利影响。这一知识在可持续农业中尤为珍贵，因为维持生物多样性对生态平衡至关重要。 此外，scutellar区域在生物仿生学领域也有意义，科学家和工程师从自然中汲取灵感，以解决人类面临的挑战。scutellar结构的设计，结合了强度和轻量特性，具有在材料科学和工程中的潜在应用。通过研究昆虫如何利用其scutellar特征，研究人员可以创新出模仿这些特性的材料，推动技术和设计的进步。 总之，术语scutellar包含了关于昆虫解剖、功能和生态重要性的丰富信息。从帮助物种分类到激发技术创新，scutellar区域是一个看似微小的解剖特征如何在各个研究领域产生深远影响的典范。随着研究的不断发展，理解scutellar结构的重要性无疑将增长，为深入了解昆虫及其在生态系统中的角色提供更深刻的见解。