biokinetic temperature limit

简明释义

生物活动温度临界;

英英释义

例句

1.To prevent spoilage, food products must be stored below the biokinetic temperature limit 生物动力学温度极限 recommended by health authorities.

为了防止变质，食品必须存放在低于健康机构推荐的生物动力学温度极限 biokinetic temperature limit 的温度下。

2.Researchers are studying how the biokinetic temperature limit 生物动力学温度极限 affects cellular respiration.

研究人员正在研究生物动力学温度极限 biokinetic temperature limit 如何影响细胞呼吸。

3.In sports science, understanding the biokinetic temperature limit 生物动力学温度极限 can help athletes optimize their performance.

在体育科学中，理解生物动力学温度极限 biokinetic temperature limit 可以帮助运动员优化他们的表现。

4.The research indicated that the biokinetic temperature limit 生物动力学温度极限 for optimal enzyme activity is around 37 degrees Celsius.

研究表明，最佳酶活性的生物动力学温度极限 biokinetic temperature limit 大约在37摄氏度。

5.The biokinetic temperature limit 生物动力学温度极限 is crucial for maintaining the efficacy of vaccines during transportation.

在运输过程中，生物动力学温度极限 biokinetic temperature limit 对于维持疫苗的有效性至关重要。

作文

Understanding the concept of biokinetic temperature limit is crucial for various fields, including biology, medicine, and environmental science. The term refers to the maximum temperature at which biological processes can occur efficiently without causing damage to living organisms. In simpler terms, it is the threshold beyond which the normal functions of cells and organisms begin to deteriorate due to heat stress. This limit varies significantly among different species and is influenced by several factors, including the organism's habitat, metabolic rate, and adaptive mechanisms. For instance, thermophilic bacteria thrive in extreme temperatures, often exceeding 70 degrees Celsius, and possess specialized proteins that maintain their functionality at these high temperatures. On the other hand, most mammals, including humans, have a biokinetic temperature limit around 37 degrees Celsius, which is optimal for enzymatic reactions and overall bodily functions. When exposed to higher temperatures, humans can experience heat-related illnesses such as heat exhaustion or heat stroke, which occur when the body can no longer regulate its internal temperature effectively.The significance of understanding the biokinetic temperature limit extends to climate change discussions as well. As global temperatures rise, many species may find themselves exceeding their biokinetic temperature limit, leading to increased mortality rates, altered reproductive patterns, and shifts in biodiversity. For example, coral reefs are particularly sensitive to temperature changes; even a slight increase can cause coral bleaching, which disrupts entire marine ecosystems. In agriculture, knowledge of the biokinetic temperature limit can inform practices to enhance crop resilience against heat stress. Farmers can select crop varieties that are better adapted to higher temperatures or implement strategies such as mulching and shade provision to protect plants during extreme heat events. Moreover, in the field of medicine, the biokinetic temperature limit is relevant when considering the storage and transport of biological materials, such as vaccines and blood products. These materials often require specific temperature ranges to remain viable; exceeding these limits can render them ineffective or harmful. Therefore, maintaining proper temperature controls is essential in healthcare settings to ensure patient safety and treatment efficacy.In conclusion, the biokinetic temperature limit is a vital concept that impacts numerous aspects of life on Earth. From ecological balance to agricultural productivity and medical safety, understanding this limit helps us navigate the challenges posed by environmental changes and ensures the sustainability of various biological systems. As we continue to face global warming and its consequences, awareness and research surrounding the biokinetic temperature limit will be essential in developing strategies to mitigate its effects on both natural and human-made environments.

理解生物动力学温度极限的概念对生物学、医学和环境科学等多个领域至关重要。这个术语指的是生物过程能够有效发生而不会对生物体造成损害的最高温度。简单来说，它是细胞和生物体正常功能因热应激而开始恶化的阈值。这个极限在不同物种之间差异显著，并受到多种因素的影响，包括生物体的栖息地、代谢率和适应机制。例如，嗜热菌在极端温度下生存，通常超过70摄氏度，并拥有特化的蛋白质，使其在这些高温下保持功能。另一方面，大多数哺乳动物，包括人类，其生物动力学温度极限约为37摄氏度，这对于酶反应和整体身体功能是最佳的。当暴露于更高温度时，人类可能会经历与热相关的疾病，如热衰竭或中暑，这发生在身体无法有效调节其内部温度时。理解生物动力学温度极限的重要性还延伸到气候变化的讨论中。随着全球气温上升，许多物种可能会发现自己超出了其生物动力学温度极限，导致死亡率增加、生殖模式改变和生物多样性转变。例如，珊瑚礁对温度变化特别敏感；即使是轻微的增加也会导致珊瑚白化，这扰乱了整个海洋生态系统。在农业中，了解生物动力学温度极限可以为提高作物抵御热应激的能力提供信息。农民可以选择更适应高温的作物品种，或实施如覆盖物和遮荫等策略，以保护植物免受极端高温事件的影响。此外，在医学领域，生物动力学温度极限与生物材料的储存和运输相关，例如疫苗和血液制品。这些材料通常需要特定的温度范围才能保持活性；超过这些极限可能使其无效或有害。因此，在医疗环境中保持适当的温度控制对于确保患者安全和治疗有效性至关重要。总之，生物动力学温度极限是一个重要的概念，影响着地球上生活的多个方面。从生态平衡到农业生产力和医疗安全，理解这一极限有助于我们应对环境变化带来的挑战，并确保各种生物系统的可持续性。随着我们继续面对全球变暖及其后果，围绕生物动力学温度极限的意识和研究将在制定减轻其对自然和人造环境影响的策略中发挥关键作用。