fibroin

简明释义

英[ˈfaɪbrəʊɪn]美[ˈfaɪbroʊɪn]

n. 蚕丝蛋白

英英释义

单词用法

同义词

反义词

例句

1.Silk protein consists of silk-gland liquid fibroin and silk sericin as well as fibroin and sericin in the bave.

蚕丝蛋白质包括绢丝腺液状丝素与丝胶，以及茧丝中丝素与丝胶。

2.The polyurethane in the membrane can prevent the crystallization of silk fibroin.

共混膜内聚氨酯能阻止丝素蛋白质的结晶。

3.Mainly discuss the process techniques and effect factors of silk fibroin film, and primary applications are also summarized.

探讨了丝素蛋白膜加工工艺及影响因素，并概述了其主要应用。

4.The result indicates that silk fibroin membrane mostly cling to viscose fibre by physics mode.

结果表明，丝素膜主要是以物理方式附着在粘胶纤维上。

5.Analysis by infrared spectrum indicated that silk fibroin and chitosan were physically blended and compatible with each other.

经红外光谱分析知，丝素与壳聚糖只是物理混合，两者处于相容状态。

6.Then, the inhibition ratio of the formation of the black pigment was reduced with the increase of the hydrolytic degree of silk fibroin peptide.

之后，随着水解程度的增加，其黑色素生成抑制率反而下降。

7.Describes the preparation, physical property and medicine releasability of the traditional Chinese medicine fibroin film.

介绍了中药丝素膜的制备方法及其物理性能和释药性能。

8.The silk produced by silkworms is primarily composed of fibroin, which gives it its strength and durability.

蚕产生的丝主要由纤维蛋白组成，这赋予了它强度和耐用性。

9.Researchers are studying fibroin for its potential use in biodegradable materials.

研究人员正在研究纤维蛋白在可生物降解材料中的潜在应用。

10.The unique properties of fibroin make it an ideal candidate for medical sutures.

由于纤维蛋白的独特性质，使其成为理想的医疗缝合线候选材料。

11.Scientists have developed a method to extract fibroin from silk without damaging its structure.

科学家们开发了一种从丝绸中提取纤维蛋白而不损坏其结构的方法。

12.The tensile strength of fibroin is comparable to that of steel, making it a fascinating material for engineering.

纤维蛋白的抗拉强度可与钢铁相媲美，这使其成为工程领域一种引人注目的材料。

作文

Fibroin is a fascinating protein that plays a crucial role in the structure and function of silk, particularly in silkworms. This remarkable substance is composed of long chains of amino acids, which are the building blocks of proteins. The unique properties of fibroin (纤维蛋白) stem from its ability to form strong, flexible fibers that are both lightweight and durable. These characteristics make fibroin (纤维蛋白) an essential component in various biological systems and have led to its exploration in numerous applications beyond nature. One of the most well-known sources of fibroin (纤维蛋白) is the silk produced by the silkworm, Bombyx mori. Silkworms spin their cocoons using fibroin (纤维蛋白), which is secreted from specialized glands. The silk fibers, made primarily of fibroin (纤维蛋白), exhibit exceptional tensile strength, making them stronger than steel of the same diameter. This incredible strength-to-weight ratio has intrigued scientists and engineers alike, prompting research into synthetic alternatives that can mimic the properties of natural fibroin (纤维蛋白). The study of fibroin (纤维蛋白) has opened new avenues in the field of biomaterials. Researchers are investigating its potential for use in medical applications, such as sutures, drug delivery systems, and tissue engineering. The biocompatibility of fibroin (纤维蛋白) makes it an attractive choice for these applications, as it can integrate smoothly with human tissues without causing adverse reactions. Additionally, its biodegradable nature means that any materials made from fibroin (纤维蛋白) can break down safely in the body over time. In recent years, the demand for sustainable and eco-friendly materials has increased significantly. As a result, the interest in fibroin (纤维蛋白) has surged, as it is a renewable resource derived from natural sources. Unlike synthetic polymers, which often rely on fossil fuels, fibroin (纤维蛋白) can be produced through environmentally friendly processes. This aligns with the growing trend towards sustainability in various industries, including fashion, packaging, and medicine. Moreover, the versatility of fibroin (纤维蛋白) allows for the development of innovative products. For instance, researchers are exploring its use in creating biodegradable packaging materials that can replace traditional plastics. The ability of fibroin (纤维蛋白) to form films and coatings opens up possibilities for applications in food preservation and waste reduction. In conclusion, fibroin (纤维蛋白) is a remarkable protein with unique properties that have captured the attention of scientists and engineers worldwide. Its strength, flexibility, and biocompatibility make it an ideal candidate for a wide range of applications, from medical devices to sustainable materials. As research continues to uncover the potential of fibroin (纤维蛋白), we may see even more innovative uses emerge, contributing to a more sustainable and health-conscious future. Understanding the significance of fibroin (纤维蛋白) not only enhances our knowledge of natural materials but also inspires us to seek solutions that harmonize with the environment.

纤维蛋白是一种迷人的蛋白质，在丝绸的结构和功能中发挥着至关重要的作用，尤其是在蚕中。这种显著的物质由长链氨基酸组成，而氨基酸是蛋白质的基本构件。纤维蛋白（fibroin）独特的属性源于其形成强大、灵活的纤维的能力，这些纤维既轻便又耐用。这些特征使得纤维蛋白（fibroin）成为各种生物系统中的重要组成部分，并导致其在众多超出自然界的应用中的探索。 纤维蛋白（fibroin）最著名的来源之一是由蚕（Bombyx mori）产生的丝。蚕使用纤维蛋白（fibroin）来纺织它们的茧，这种蛋白质是从专门的腺体分泌出来的。丝纤维主要由纤维蛋白（fibroin）构成，表现出卓越的抗拉强度，使其比同直径的钢更强。这种令人难以置信的强度与重量比引起了科学家和工程师的极大兴趣，促使对合成替代品的研究，这些替代品可以模仿天然纤维蛋白（fibroin）的属性。 对纤维蛋白（fibroin）的研究为生物材料领域开辟了新的途径。研究人员正在调查其在医疗应用中的潜力，例如缝合线、药物输送系统和组织工程。纤维蛋白（fibroin）的生物相容性使其成为这些应用的理想选择，因为它可以与人体组织顺利结合，而不会引起不良反应。此外，其可生物降解的特性意味着由纤维蛋白（fibroin）制成的任何材料都可以随着时间的推移在体内安全降解。 近年来，对可持续和环保材料的需求显著增加。因此，对纤维蛋白（fibroin）的兴趣激增，因为它是一种来自自然来源的可再生资源。与往往依赖化石燃料的合成聚合物不同，纤维蛋白（fibroin）可以通过环保的过程生产。这与各个行业日益增长的可持续发展趋势相一致，包括时尚、包装和医学。 此外，纤维蛋白（fibroin）的多功能性允许开发创新产品。例如，研究人员正在探索其在制造可生物降解的包装材料方面的应用，这些材料可以替代传统塑料。纤维蛋白（fibroin）形成薄膜和涂层的能力为食品保鲜和减少浪费的应用打开了可能性。 总之，纤维蛋白（fibroin）是一种具有独特性质的显著蛋白质，吸引了全球科学家和工程师的关注。它的强度、灵活性和生物相容性使其成为广泛应用的理想候选者，从医疗设备到可持续材料。随着研究继续揭示纤维蛋白（fibroin）的潜力，我们可能会看到更多创新用途的出现，为更可持续和健康的未来做出贡献。理解纤维蛋白（fibroin）的重要性不仅增强了我们对自然材料的认识，也激励我们寻求与环境和谐的解决方案。