dendroid
简明释义
adj. 树状的
英英释义
在形状或结构上类似于树。 | |
Pertaining to or having the characteristics of a dendrite, which is a branching structure. | 与树突相关或具有树突特征的,树突是一种分支结构。 |
单词用法
树状形态 | |
树状图案 | |
树状分支 | |
树状神经元 | |
树状系统 | |
树状架构 |
同义词
| 树状的 | 珊瑚的树状结构很迷人。 | ||
| 树木状的 | The arborescent pattern of the veins in the leaf is distinct. | 叶子中静脉的树木状图案很明显。 | |
| 分支的 | 雕塑的分支设计类似于一棵树。 |
反义词
例句
1.Leaves with dense long stalk dendroid trichome, long stalk forked trachoma and long stalk trichome with big glandular cells were resistance to the disease.
叶背毛为较稠密的长柄树状毛、长柄叉状毛、长柄单枝毛和长柄、腺细胞大的粘性腺毛的泡桐为高度抗病。
2.Leaves with dense long stalk dendroid trichome, long stalk forked trachoma and long stalk trichome with big glandular cells were resistance to the disease.
叶背毛为较稠密的长柄树状毛、长柄叉状毛、长柄单枝毛和长柄、腺细胞大的粘性腺毛的泡桐为高度抗病。
3.Her artwork featured dendroid 树状的 shapes that resembled branches and roots.
她的艺术作品中有dendroid 树状的 形状,类似于树枝和根部。
4.In his research on coral, he noted that the dendroid 树状的 formations were crucial for marine biodiversity.
在他的珊瑚研究中,他指出这些dendroid 树状的 结构对海洋生物多样性至关重要。
5.The scientist discovered a new species of tree with a distinctly dendroid 树状的 structure.
科学家发现了一种新的树种,其结构明显是dendroid 树状的。
6.The dendroid 树状的 patterns observed in the crystal structure fascinated the geologists.
地质学家们对晶体结构中观察到的dendroid 树状的 图案感到着迷。
7.The dendroid 树状的 network of neurons is essential for understanding brain function.
神经元的dendroid 树状的 网络对于理解大脑功能至关重要。
作文
In the study of biology, the term dendroid refers to structures that resemble or are shaped like trees. This concept is not only fascinating but also crucial in understanding various biological systems, from the branching patterns of neurons in the brain to the growth forms of certain plants. The word itself derives from the Greek word 'dendron', meaning tree, which highlights its connection to tree-like characteristics. dendroid formations can be observed in many different contexts, making them a significant focus of study across various scientific disciplines.For instance, in neuroscience, the dendritic trees of neurons play a vital role in the transmission of signals within the nervous system. These dendroid structures allow neurons to receive inputs from multiple sources, enhancing their ability to process information. The complexity of these dendritic trees can influence cognitive functions and is a key area of research in understanding neurological diseases such as Alzheimer's and schizophrenia. By studying how these dendroid patterns change with disease progression, scientists hope to develop better diagnostic tools and treatments.In botany, dendroid structures can be found in the branching patterns of trees and shrubs. The way a plant grows and branches out can be influenced by environmental factors such as light, water availability, and competition for resources. Understanding these dendroid growth patterns helps ecologists assess the health of ecosystems and predict how changes in the environment may affect biodiversity. For example, forests with diverse dendroid structures tend to support more wildlife and have greater resilience to climate change.Additionally, the concept of dendroid structures extends beyond biology into fields such as computer science and data analysis. In computer science, tree data structures are used to organize information hierarchically. These dendroid structures facilitate efficient searching and sorting algorithms, making them essential for database management and software development. Understanding the principles behind these dendroid configurations can lead to innovations in technology that improve how we process and analyze data.Moreover, the aesthetic appeal of dendroid forms can be seen in art and architecture. Artists often draw inspiration from the natural world, incorporating tree-like patterns into their work. This reflects a broader appreciation for nature's designs, where dendroid shapes symbolize growth, connectivity, and life itself. Architects might use dendroid concepts to create buildings that harmonize with their surroundings, promoting sustainability and environmental consciousness.In conclusion, the term dendroid encompasses a wide range of applications and meanings across various fields of study. From the intricate networks of neurons in our brains to the sprawling branches of trees and even the organization of data in computers, dendroid structures are fundamental to understanding both the natural and technological worlds. As we continue to explore these connections, it becomes increasingly clear that the study of dendroid forms can lead to significant advancements in science, art, and technology, ultimately enriching our understanding of the world around us.
在生物学研究中,术语dendroid指的是类似于树或呈树形的结构。这个概念不仅令人着迷,而且在理解各种生物系统方面至关重要,从大脑中神经元的分支模式到某些植物的生长形态。这个词本身源自希腊语“dendron”,意为树,这突显了它与树状特征的联系。dendroid形成可以在许多不同的背景中观察到,使其成为各个科学学科的重要研究重点。例如,在神经科学中,神经元的树突树对信号在神经系统中的传输起着至关重要的作用。这些dendroid结构使神经元能够接收来自多个来源的输入,增强其处理信息的能力。这些dendroid树突的复杂性可能会影响认知功能,并且是理解阿尔茨海默病和精神分裂症等神经疾病的关键研究领域。通过研究这些dendroid模式如何随着疾病进展而变化,科学家希望开发出更好的诊断工具和治疗方法。在植物学中,dendroid结构可以在树木和灌木的分支模式中找到。植物的生长和分支方式可能会受到光、水分可用性和资源竞争等环境因素的影响。理解这些dendroid生长模式有助于生态学家评估生态系统的健康状况,并预测环境变化可能如何影响生物多样性。例如,具有多样化dendroid结构的森林往往支持更多的野生动物,并对气候变化具有更大的韧性。此外,dendroid结构的概念超越了生物学,延伸到计算机科学和数据分析等领域。在计算机科学中,树形数据结构用于以层次方式组织信息。这些dendroid结构促进了高效的搜索和排序算法,使其在数据库管理和软件开发中至关重要。理解这些dendroid配置背后的原则可以推动技术创新,改善我们处理和分析数据的方式。此外,dendroid形式的美学吸引力可以在艺术和建筑中看到。艺术家们常常从自然界中汲取灵感,将树状图案融入他们的作品中。这反映了对自然设计的更广泛欣赏,其中dendroid形状象征着生长、连通性和生命本身。建筑师可能会利用dendroid概念来创建与周围环境和谐的建筑,促进可持续发展和环保意识。总之,术语dendroid涵盖了各个研究领域中广泛的应用和意义。从我们大脑中神经元的复杂网络到树木的蔓延分支,甚至计算机中数据的组织,dendroid结构对于理解自然和技术世界都是基础。随着我们继续探索这些联系,越来越清楚的是,对dendroid形式的研究可以在科学、艺术和技术方面带来重大进展,最终丰富我们对周围世界的理解。
