molecular designing

简明释义

分子设计

英英释义

例句

1.In the field of materials science, molecular designing can lead to the development of new polymers.

在材料科学领域，分子设计可以导致新聚合物的开发。

2.The team focused on molecular designing to create more effective drug candidates.

团队专注于分子设计以创造更有效的药物候选者。

3.Through molecular designing, scientists can predict how molecules will interact with each other.

通过分子设计，科学家可以预测分子之间的相互作用。

4.The pharmaceutical industry relies heavily on molecular designing for drug discovery.

制药行业在药物发现中严重依赖于分子设计。

5.Researchers are using molecular designing techniques to enhance the properties of existing materials.

研究人员正在使用分子设计技术来增强现有材料的特性。

作文

Molecular designing, or 分子设计, is a cutting-edge field that combines principles from chemistry, biology, and computer science to create new molecules with specific properties and functions. This process involves the careful manipulation of molecular structures to achieve desired outcomes, such as improved drug efficacy, enhanced material properties, or novel biochemical pathways. As our understanding of molecular interactions deepens, the potential applications of 分子设计 continue to expand exponentially.One of the most significant applications of 分子设计 is in the pharmaceutical industry. The development of new drugs often requires the design of molecules that can interact with biological targets in precise ways. For example, researchers can use computational tools to simulate how different molecular configurations will bind to a target protein. By predicting these interactions, scientists can design compounds that are more likely to be effective treatments for diseases. This approach not only speeds up the drug discovery process but also reduces the costs associated with traditional trial-and-error methods.In addition to pharmaceuticals, 分子设计 plays a crucial role in materials science. Scientists are increasingly using molecular design techniques to create new materials with tailored properties. For instance, by manipulating the molecular structure of polymers, researchers can develop materials that are stronger, lighter, or more resistant to heat and chemicals. These advancements can lead to innovative applications in various industries, including aerospace, electronics, and renewable energy.Moreover, 分子设计 is also essential in the field of biotechnology. By designing molecules that can selectively interact with biological systems, researchers can create more efficient enzymes, antibodies, and other biomolecules. This has significant implications for areas such as environmental remediation, where designed molecules can help break down pollutants, or in agriculture, where they can enhance crop resistance to pests and diseases.Despite its many advantages, 分子设计 also presents challenges. The complexity of biological systems means that predicting how designed molecules will behave in real-world conditions is often difficult. Additionally, ethical considerations arise when designing molecules that can alter biological processes, particularly in humans. As a result, ongoing research in this field must balance innovation with responsibility.In conclusion, 分子设计 represents a fascinating intersection of science and technology, offering the potential to revolutionize various fields. From developing new drugs to creating advanced materials and improving biotechnological processes, the impact of molecular design is profound. As we continue to explore the possibilities of 分子设计, it is essential to navigate the accompanying ethical and practical challenges to maximize its benefits for society.

分子设计是一个结合化学、生物学和计算机科学原理的前沿领域，旨在创造具有特定性质和功能的新分子。这个过程涉及对分子结构的仔细操控，以实现期望的结果，例如提高药物有效性、增强材料性能或新颖的生化通路。随着我们对分子相互作用的理解加深，分子设计的潜在应用也在迅速扩展。分子设计最重要的应用之一是在制药行业。新药的开发通常需要设计能够以精确方式与生物靶点相互作用的分子。例如，研究人员可以使用计算工具模拟不同分子构型与目标蛋白的结合方式。通过预测这些相互作用，科学家可以设计出更有可能成为有效疾病治疗的化合物。这种方法不仅加快了药物发现过程，还降低了与传统试错方法相关的成本。除了制药，分子设计在材料科学中也发挥着至关重要的作用。科学家越来越多地使用分子设计技术来创造具有特定属性的新材料。例如，通过操控聚合物的分子结构，研究人员可以开发出更强、更轻或更耐热和耐化学品的新材料。这些进展可以导致在航空航天、电子和可再生能源等各个行业的创新应用。此外，分子设计在生物技术领域也至关重要。通过设计能够选择性地与生物系统相互作用的分子，研究人员可以创造出更高效的酶、抗体和其他生物分子。这对环境修复等领域具有重要意义，在这些领域，设计的分子可以帮助分解污染物，或在农业中提高作物对害虫和疾病的抵抗力。尽管有许多优势，分子设计也面临挑战。生物系统的复杂性意味着预测设计分子在现实条件下的行为往往困难。此外，当设计可以改变生物过程的分子时，伦理问题也会出现，尤其是在人体内。因此，这一领域的持续研究必须在创新与责任之间取得平衡。总之，分子设计代表了科学与技术的迷人交集，提供了革命化各个领域的潜力。从开发新药到创建先进材料和改善生物技术过程，分子设计的影响深远。随着我们继续探索分子设计的可能性，必须应对伴随而来的伦理和实践挑战，以最大限度地发挥其对社会的益处。