vesiculate
简明释义
adj. 小泡状的;有小泡的
vi. 起泡
vt. 使成小泡状
第 三 人 称 单 数 v e s i c u l a t e s
现 在 分 词 v e s i c u l a t i n g
过 去 式 v e s i c u l a t e d
过 去 分 词 v e s i c u l a t e d
英英释义
To form or become vesicles; to develop small blisters or sacs, often filled with fluid. | 形成或变成小囊泡;发展出小水泡或囊,通常充满液体。 |
单词用法
水泡组织 | |
水泡病变 | |
因热而形成水泡 | |
在感染期间形成水泡 |
同义词
反义词
| 固化 | 热量使液体迅速固化。 | ||
| 压缩 | 他们需要压缩气体以便将其装入容器。 |
例句
1.His conclusions show that, for slow-growing organisms, the energy costs for maintaining cells in suspension is substantially less for gas-vesiculate than for flagellated organisms (Walsby 1994).
他的结论表明,对生长缓慢的生物,保持细胞悬浮耗费的能源成本比鞭毛生物少(Walsby 1994年)。
2.His conclusions show that, for slow-growing organisms, the energy costs for maintaining cells in suspension is substantially less for gas-vesiculate than for flagellated organisms (Walsby 1994).
他的结论表明,对生长缓慢的生物,保持细胞悬浮耗费的能源成本比鞭毛生物少(Walsby 1994年)。
3.From the calculations of Walsby (1994), such conditions should greatly favor gas-vesiculate phototrophs; and they may have been important factors in selecting for the Fryx1 phenotype of Rfx.
从Walsby(1994年)的计算中可以看出,这种情况应该大大有利于气泡型光合生物,并有可能被用于的Fryx1 phenotypeofRfx的表型选择的重要因素。
4.The surface of the leaf was found to be vesiculate, indicating a possible disease.
叶子的表面被发现是囊泡状的,这可能表明一种疾病。
5.Some algae can vesiculate in response to changes in their environment.
一些藻类可以根据环境变化而出现囊泡化。
6.The vesiculate structure of the fungus is crucial for its reproduction.
这种真菌的囊泡状结构对其繁殖至关重要。
7.In the laboratory, we observed that the cells began to vesiculate when exposed to certain chemicals.
在实验室中,我们观察到细胞在接触某些化学物质时开始囊泡化。
8.During the examination, the pathologist noted that the tissue showed vesiculate changes.
在检查过程中,病理学家注意到组织显示出囊泡状变化。
作文
The world of biology is filled with intricate processes and fascinating structures, one of which is the phenomenon known as vesiculate. This term refers to the formation of small, bubble-like structures, or vesicles, within cells or tissues. These vesicles play a crucial role in various biological functions, including transport, storage, and communication between different parts of the cell. Understanding the process of vesiculate can provide insights into how cells operate and interact with their environment.In plants, for instance, the vesiculate structures are often involved in the storage of essential nutrients and water. These vesicles can swell or shrink depending on the osmotic pressure and the availability of resources, allowing the plant to adapt to changing environmental conditions. When a plant experiences drought, the vesicles may release stored water to help maintain cellular functions, showcasing the importance of vesiculate in sustaining life.Moreover, in the human body, vesiculate processes are vital for neurotransmission. Neurons communicate with each other through synapses, where vesicles containing neurotransmitters are released into the synaptic cleft. This release is a highly regulated process that ensures precise signaling between nerve cells. Any disruption in the vesiculate mechanism can lead to neurological disorders, highlighting its significance in maintaining cognitive functions and overall health.Additionally, the study of vesiculate structures has applications beyond basic biology. In medicine, understanding how vesicles form and function can lead to advancements in drug delivery systems. Researchers are exploring ways to encapsulate therapeutic agents within vesicles, allowing for targeted delivery to specific cells or tissues. This approach could enhance the effectiveness of treatments while minimizing side effects, revolutionizing how we approach diseases such as cancer.In the realm of microbiology, vesiculate processes are also observed in the behavior of bacteria. Certain bacterial species can produce vesicles that carry signaling molecules or toxins, facilitating communication and competition with other microorganisms. This aspect of vesiculate behavior not only provides insight into bacterial ecology but also opens up possibilities for developing new antimicrobial strategies.In conclusion, the concept of vesiculate encompasses a wide range of biological phenomena that are critical for the functioning of living organisms. From plants to humans and even microorganisms, the formation and role of vesicles are integral to various life processes. As research continues to uncover the complexities of vesiculate mechanisms, we gain a deeper appreciation for the elegance of biological systems and the potential for innovative applications in health and technology. The exploration of vesiculate phenomena is not just an academic pursuit; it holds the promise of improving lives and understanding the very fabric of life itself.
生物学的世界充满了复杂的过程和迷人的结构,其中一个现象被称为囊泡形成。这个术语指的是在细胞或组织内形成小的、像气泡一样的结构,或者称为囊泡。这些囊泡在各种生物功能中发挥着至关重要的作用,包括运输、存储和细胞不同部分之间的通信。理解囊泡形成的过程可以提供关于细胞如何运作及其与环境相互作用的见解。例如,在植物中,囊泡形成的结构通常涉及到储存重要的营养物质和水分。这些囊泡可以根据渗透压和资源的可用性膨胀或收缩,使植物能够适应不断变化的环境条件。当植物经历干旱时,囊泡可能释放储存的水分,以帮助维持细胞功能,展示了囊泡形成在维持生命中的重要性。此外,在人体中,囊泡形成过程对神经传导至关重要。神经元通过突触相互通信,囊泡内含有神经递质,被释放到突触间隙中。这种释放是一个高度调节的过程,确保神经细胞之间的精确信号传递。任何对囊泡形成机制的干扰都可能导致神经系统疾病,突显其在维持认知功能和整体健康中的重要性。此外,研究囊泡形成结构不仅限于基础生物学。在医学上,了解囊泡如何形成和发挥作用可以推动药物递送系统的进步。研究人员正在探索将治疗剂封装在囊泡中的方法,从而实现对特定细胞或组织的靶向递送。这种方法可以增强治疗的有效性,同时最小化副作用,彻底改变我们对癌症等疾病的治疗方式。在微生物学领域,囊泡形成过程也在细菌的行为中观察到。某些细菌种类可以产生携带信号分子或毒素的囊泡,促进与其他微生物的通信和竞争。这一方面的囊泡形成行为不仅提供了对细菌生态的洞察,还为开发新的抗微生物策略开辟了可能性。总之,囊泡形成的概念涵盖了一系列对生物体功能至关重要的生物现象。从植物到人类甚至微生物,囊泡的形成和作用是各种生命过程的组成部分。随着研究继续揭示囊泡形成机制的复杂性,我们对生物系统优雅性的理解加深,并且在健康和技术领域的创新应用潜力也逐渐显现。探索囊泡形成现象不仅仅是学术追求;它承诺改善生活并理解生命本质的织物。
