allometric development

简明释义

异度发育;

英英释义

例句

1.In plants, allometric development can explain why some trees grow taller than others despite having similar seed sizes.

在植物中，异速生长可以解释为什么一些树木尽管种子大小相似却长得更高。

2.The study of allometric development helps us understand how different species grow at different rates.

对异速生长的研究帮助我们理解不同物种的生长速率差异。

3.Understanding allometric development is crucial for ecologists studying population dynamics.

理解异速生长对研究种群动态的生态学家至关重要。

4.Researchers found that the allometric development of fish varies significantly with their environment.

研究人员发现鱼类的异速生长在不同环境中有显著差异。

5.The allometric development of mammalian brains compared to body size reveals interesting evolutionary patterns.

哺乳动物大脑与身体大小的异速生长揭示了有趣的进化模式。

作文

All living organisms undergo various forms of growth and development throughout their life cycles. One fascinating aspect of this process is what scientists refer to as allometric development. This term describes the growth of different parts of an organism at different rates, which can lead to significant changes in shape and proportion as the organism matures. Understanding allometric development is crucial for biologists, ecologists, and even medical professionals, as it helps explain how species adapt to their environments and how certain physical traits evolve over time.To illustrate the concept of allometric development, consider the example of a young mammal, such as a kitten. In its early stages of life, the kitten's head is relatively large compared to its body. As it grows, the body will catch up, resulting in a more proportionate shape. This change is not uniform; instead, specific body parts grow at different rates. The head may grow slower than the body, which is a classic example of allometric development. This differential growth allows for the necessary adaptations that support the kitten’s survival and functionality as it matures into an adult cat.The implications of allometric development extend beyond individual organisms. In evolutionary biology, understanding how different species exhibit allometric patterns can provide insights into their ecological niches and evolutionary strategies. For instance, larger animals tend to have different growth patterns compared to smaller ones. Elephants, which are among the largest land mammals, show a unique pattern of allometric development where their limbs and bodies grow much larger relative to their heads compared to smaller mammals like mice. This difference is not only a matter of size but also relates to their metabolic rates, reproductive strategies, and even their social structures.In addition to its significance in natural sciences, allometric development plays a vital role in medicine and health sciences. For example, pediatricians often use growth charts that reflect allometric growth patterns to assess whether children are developing normally. If a child’s growth deviates significantly from established allometric norms, it could indicate potential health issues that require further investigation. Thus, recognizing and understanding allometric development can lead to better health outcomes by ensuring timely interventions when necessary.Furthermore, the concept of allometric development has applications in fields such as architecture and engineering. Designers often draw inspiration from biological forms and structures, utilizing principles of allometry to create functional and aesthetically pleasing designs. By studying how organisms grow and develop, architects can apply similar principles to optimize space and materials in their constructions.In conclusion, allometric development is a multifaceted concept that encompasses various aspects of biology, ecology, medicine, and even design. It highlights the importance of understanding growth patterns in both individual organisms and entire species. As we continue to explore the complexities of life, the study of allometric development will undoubtedly reveal more about the intricate relationships between form, function, and adaptation in the natural world. By appreciating these differences in growth, we can gain a deeper understanding of the biological processes that shape our environment and influence our lives.

所有生物在其生命周期中经历各种形式的生长和发展。这个过程的一个迷人方面是科学家所称的异速发育。这个术语描述了生物体不同部分以不同速度生长的现象，这可能导致随着生物体的成熟而发生显著的形状和比例变化。理解异速发育对于生物学家、生态学家甚至医学专业人士来说都至关重要，因为它有助于解释物种如何适应环境以及某些身体特征如何随时间演变。为了说明异速发育的概念，考虑一个年轻哺乳动物的例子，比如小猫。在生命的早期阶段，小猫的头相对于其身体来说相对较大。随着它的成长，身体会赶上，从而形成更为匀称的形状。这种变化并不是均匀的；相反，特定的身体部位以不同的速度生长。头部的生长速度可能慢于身体，这是异速发育的经典例子。这种差异生长允许必要的适应，以支持小猫作为成年猫成熟时的生存和功能。异速发育的影响超越了个体生物。在进化生物学中，了解不同物种如何表现出异速模式可以提供关于其生态位和进化策略的见解。例如，较大的动物往往与较小的动物相比，表现出不同的生长模式。大象，作为地球上最大的陆生哺乳动物之一，展示了一种独特的异速发育模式，其四肢和身体相对于头部的生长要大得多，这与小型哺乳动物如老鼠形成鲜明对比。这种差异不仅是体型问题，还与它们的新陈代谢率、生殖策略甚至社会结构有关。除了在自然科学中的重要性外，异速发育在医学和健康科学中也发挥着至关重要的作用。例如，儿科医生通常使用反映异速生长模式的生长图表来评估儿童是否正常发育。如果一个孩子的生长显著偏离既定的异速规范，这可能表明潜在的健康问题需要进一步调查。因此，认识和理解异速发育可以通过确保在必要时及时干预来改善健康结果。此外，异速发育的概念在建筑和工程等领域也有应用。设计师经常从生物形式和结构中汲取灵感，利用异速发育的原理来创作功能性和美观的设计。通过研究生物体的生长和发展，建筑师可以将类似的原则应用于优化其建筑中的空间和材料。总之，异速发育是一个多方面的概念，涵盖了生物学、生态学、医学乃至设计的各个方面。它突出了理解个体生物和整个物种的生长模式的重要性。随着我们继续探索生命的复杂性，对异速发育的研究无疑会揭示更多关于在自然界中塑造我们环境和影响我们生活的形式、功能与适应之间复杂关系的知识。通过欣赏这些生长上的差异，我们可以更深入地理解塑造我们环境的生物过程。