bioconstructional lip

简明释义

1. 生物建造伐前缘; 2. 生物营造伐前缘;

英英释义

例句

1.The researcher discovered that the bioconstructional lip 生物构建唇 of the bacteria could enhance its survival in extreme environments.

研究人员发现，这种细菌的bioconstructional lip 生物构建唇可以增强其在极端环境中的生存能力。

2.Understanding the properties of the bioconstructional lip 生物构建唇 can lead to advancements in drug delivery systems.

理解bioconstructional lip 生物构建唇的特性可以推动药物传递系统的进步。

3.The bioconstructional lip 生物构建唇 plays a crucial role in cell membrane stability and function.

bioconstructional lip 生物构建唇在细胞膜的稳定性和功能中起着至关重要的作用。

4.In synthetic biology, engineers are exploring how to manipulate the bioconstructional lip 生物构建唇 to create more resilient microbial strains.

在合成生物学中，工程师们正在探索如何操控bioconstructional lip 生物构建唇以创造更具韧性的微生物菌株。

5.The study focused on the interaction between antibiotics and the bioconstructional lip 生物构建唇 of resistant bacteria.

该研究集中于抗生素与耐药细菌的bioconstructional lip 生物构建唇之间的相互作用。

作文

In the realm of modern biology and materials science, the term bioconstructional lip refers to a unique interface where biological systems meet engineered materials. This concept is particularly significant in the development of sustainable building materials and biocompatible products. The bioconstructional lip serves as a bridge between natural biological processes and artificial constructs, leading to innovative solutions that benefit both fields.The foundation of the bioconstructional lip lies in understanding how living organisms interact with their environment. For instance, many organisms produce natural adhesives or structural components that can be mimicked or harnessed for human use. By studying these biological mechanisms, scientists can develop new materials that not only perform well but also integrate seamlessly with the surrounding ecosystem.One prominent example of the application of the bioconstructional lip is in the field of green architecture. Architects and engineers are increasingly looking towards nature for inspiration in creating buildings that are not only functional but also environmentally friendly. The principles of biomimicry allow us to design structures that mimic the efficiency of natural forms and processes. The bioconstructional lip plays a crucial role in this area by providing a framework for integrating biological materials into construction practices.Moreover, the bioconstructional lip is essential in the development of medical materials. For instance, in tissue engineering, researchers aim to create scaffolds that support cell growth and tissue regeneration. These scaffolds often utilize biological components that encourage cellular adhesion and proliferation. The bioconstructional lip thus becomes a vital element in ensuring that these materials are compatible with biological tissues, promoting healing and integration within the body.The environmental implications of the bioconstructional lip are profound. As the world faces challenges such as climate change and resource depletion, the need for sustainable materials has never been greater. By leveraging the principles behind the bioconstructional lip, we can create products that are less harmful to the environment and promote a circular economy. This approach not only reduces waste but also enhances the longevity of materials, as they are designed to be biodegradable or recyclable.Furthermore, the interdisciplinary nature of the bioconstructional lip encourages collaboration among biologists, engineers, architects, and environmental scientists. This synergy fosters innovation and leads to the creation of novel solutions that address complex problems. For instance, the collaboration between these fields has resulted in the development of bio-based plastics and composites that offer similar benefits to traditional materials while reducing the carbon footprint.In conclusion, the concept of the bioconstructional lip represents a pivotal intersection of biology and material science. Its applications span various fields, including architecture, medicine, and environmental sustainability. By embracing this concept, we can work towards a future where our built environment harmonizes with nature, ultimately leading to a more sustainable and resilient world. The bioconstructional lip is not just a scientific term; it embodies the potential for innovation and transformation in how we approach construction and material development.

在现代生物学和材料科学领域，术语生物构建唇指的是生物系统与工程材料相遇的独特界面。这个概念在可持续建筑材料和生物相容产品的开发中尤为重要。生物构建唇作为自然生物过程与人工构造之间的桥梁，促成了两个领域的创新解决方案。生物构建唇的基础在于理解生物体如何与其环境相互作用。例如，许多生物体产生天然粘合剂或结构成分，这些成分可以被模仿或用于人类使用。通过研究这些生物机制，科学家可以开发出不仅性能优良，而且能够与周围生态系统无缝结合的新材料。生物构建唇应用的一个突出例子是在绿色建筑领域。建筑师和工程师越来越多地从自然中寻找灵感，以创造既功能性又环保的建筑。仿生学的原则使我们能够设计模仿自然形式和过程效率的结构。生物构建唇在这一领域中发挥着至关重要的作用，为将生物材料整合到建筑实践中提供了框架。此外，生物构建唇在医疗材料的发展中也至关重要。例如，在组织工程中，研究人员旨在创建支持细胞生长和组织再生的支架。这些支架通常利用生物成分，促进细胞粘附和增殖。因此，生物构建唇成为确保这些材料与生物组织相容的重要元素，促进愈合和在体内的整合。生物构建唇的环境影响深远。随着世界面临气候变化和资源枯竭等挑战，对可持续材料的需求比以往任何时候都更加迫切。通过利用生物构建唇背后的原则，我们可以创造出对环境危害更小并促进循环经济的产品。这种方法不仅减少了废物，还增强了材料的耐用性，因为它们被设计为可生物降解或可回收。此外，生物构建唇的跨学科特性鼓励生物学家、工程师、建筑师和环境科学家之间的合作。这种协同作用促进了创新，导致新颖解决方案的产生，以应对复杂问题。例如，这些领域之间的合作已经导致生物基塑料和复合材料的发展，这些材料在提供类似传统材料的好处的同时减少了碳足迹。总之，生物构建唇的概念代表了生物学和材料科学的关键交汇点。它的应用跨越多个领域，包括建筑、医学和环境可持续性。通过接受这一概念，我们可以朝着一个我们的建筑环境与自然和谐共处的未来努力，最终导致一个更加可持续和有韧性的世界。生物构建唇不仅是一个科学术语；它体现了在我们处理建筑和材料开发时创新和转型的潜力。