Application of nanocellulose in yogurt, cheese and acidic milk beverages Nanocellulose (CNC) is a new natural nanomaterial. Due to its unique physical and chemical properties and biocompatibility, it has shown great application potential in the food industry. . This paper reviews the research progress of CNC in yogurt, cheese and acidic milk beverages, focuses on the impact of CNC on product texture, stability, nutritional characteristics, etc., and looks forward to its future development trend. 1. Introduction In recent years, with the increasing demand for healthy foods for consumers, the development of dairy products with excellent texture, taste and nutritional value has become a research hotspot. Nanocellulose (CNC) is a nano-scale material extracted from natural cellulose. It has the advantages of high specific surface area, high mechanical strength, good biocompatibility and degradability. It is in the fields of food, medicine, cosmetics, etc. Shows broad application prospects. 2. The response of nanocellulose in yogurt

Bacterial cellulose (BC) as a natural product has shown great potential in the field of artificial blood vessels. Bacterial cellulose is synthesized by some specific bacteria, such as Bacillus acetate, and has unique physical, chemical and biological properties, making it an ideal vascular alternative material. The following will explore the application of bacterial cellulose in the field of artificial blood vessels from multiple dimensions and angles, and supplement relevant digital tables and parameter comparisons to enhance the persuasiveness and authority of the article. 1. Unique properties of bacterial cellulose 1.1 Structure and mechanical properties The molecular structure of bacterial cellulose has a high three-dimensional network structure, which gives it significant mechanical strength, elasticity and toughness. Its fibers have strong tensile strength and can withstand the pressure caused by blood flow in the body. Similar to the structure of natural vascular tissue, bacterial cellulose can provide good internal and external mechanical support for artificial blood vessels and reduce blood vessel deformation. Table 1: Bacterial Fiber

Innovative application and future prospects of nanocellulose in the cement industry. As a new nanomaterial, nanocellulose (NFC) has been used in cement-based materials in recent years due to its unique mechanical properties, high specific surface area and biodegradability. The application has attracted much attention. Its in-depth application in the cement industry can not only significantly improve the performance of traditional cement materials, but also provide new possibilities for the development of multifunctional and intelligent building materials. The following content will further illustrate its application effect through specific data and charts. 1. Significant improvement of mechanical properties. One of the core roles of nanocellulose in cement-based materials is to enhance its mechanical properties. The following data show the effect of nanocellulose on the compressive strength and tensile strength of cement-based materials: Nanocellulose addition amount (wt%) compressive strength (MPa) tensile strength (MPa) 0.045.04.50.149.55.20.352. 05.80.5

With the increasing demand for environmental protection and sustainable development, nanocellulose (CNC/CNF) is gradually gaining popularity among all industries as a natural, green and environmentally friendly thickener. Its unique structure and properties make it show excellent thickening ability in many fields, especially in the food, cosmetics, pharmaceuticals and other industries. It has gradually replaced traditional thickening agents and has become an ideal choice. This article will discuss the thickening principle of nanocellulose in detail, and further demonstrate its outstanding performance in thickening applications through relevant data. 1. What is nanocellulose? Nanocellulose is a nano-scale material extracted from natural plant fibers (such as wood, cotton, etc.) and obtained by physical or chemical treatment. According to the preparation method, nanocellulose is mainly divided into two categories: nanocellulose crystals (CNC): has a highly crystalline structure, strong rigidity, and is suitable for thickening applications with high viscosity and high mechanical strength. nanometer

With the increasing global attention to sustainable development, green environmental protection and circular economy, nanocellulose (Cellulose Nanomaterials, CNMs), as an excellent new green material, is leading a revolution in materials science. Nanocellulose has been widely used in many industries due to its unique mechanical properties, lightweight, environmental protection, biodegradation and other characteristics, becoming an important representative of green materials. As the core driving force of this revolution, nanocellulose manufacturers are not only producing materials, but also contributing to the global green development strategy. This article will explore in-depth the technological innovation, market drivers, challenges of nanocellulose manufacturers and their key roles in the global Sustainable Development Goals. 1. Nanocellulose: Representative of green new materials Nanocellulose is a nano-level material extracted from natural plant fibers and has excellent strength.

Cellulose Nanocrystals (CNC) is a class of nanomaterials derived from natural cellulose decomposition, with high crystallinity, high strength, excellent thermal stability and biodegradability. CNC crystallinity is one of its most significant properties, which gives CNC great potential in a variety of high-end applications. This article will deeply explore the high crystallinity characteristics of CNC, including its impact on mechanics, thermal and optical properties, and analyze in detail how this characteristic promotes the widespread application of CNC in composite materials, environmentally friendly packaging, drug delivery and other fields. 1. The crystallinity of nanocellulose crystals and their importance. The crystallinity is the ratio of the crystalline region to the non-crystalline region in cellulose molecules, which affects the mechanical strength, thermal stability, chemical durability and other properties of CNC. Generally speaking, the crystallinity of CNC is as high as 70%-90%, which is much higher than that of natural cellulose (junction).

With the popularization of environmental protection and sustainable development concepts, the research and application of green materials has become a hot topic in the global scientific research and industry. Cellulose Nanocrystals (CNC) is a natural, biodegradable nanomaterial, due to its excellent environmental protection performance and wide application potential, it is gradually becoming a research focus in many fields. This article will focus on the good biodegradability of cellulose nanocrystals and their application in the field of environmental protection. 1. Biodegradability of cellulose nanocrystals. Cellulose is one of the most abundant natural polymer materials on the earth. It is widely present in the cell walls of plants and has extremely strong biodegradability. Cellulose nanocrystals (CNCs) are nanoscale crystalline regions extracted from natural cellulose and hydrolyzed or mechanically treated. CNC not only maintains the chemical structure of cellulose, but also exhibits many special physicochemical properties.

In the starry sky of nanomaterials, a new star from nature is shining brightly. Cellulose Nanofibrils (CNF), a nanoscale material extracted from plant cell walls, has revolutionized the field of materials science with its unique structure and properties. It not only inherits the excellent characteristics of natural cellulose, but also shows amazing performance on the nanoscale, opening up a new territory for materials science. 1. Structural characteristics: The beauty of the structural beauty of natural nanomastery cellulose nanofibers stems from its exquisite nanoscale structure. The diameter of a single CNF is only 3-20 nanometers and can reach several microns in length, forming a unique one-dimensional nanostructure. This structure gives CNF an extremely high aspect ratio (100-150), allowing it to form a dense network structure in the composite material. In terms of mechanical properties, CNF exhibits amazing strength. Tension strength of single CNF

Nano-cellulose assisted preparation process: Green and efficient nanocellulose production technology Nano-cellulose (Nano-cellulose) is a high-performance bio-based nanomaterial, showing great success in composite materials, flexible electronics, biomedicine and other fields. application potential. However, traditional nanocellulose preparation methods (such as acid hydrolysis and mechanical methods) have problems such as high energy consumption and environmental pollution. As a green and efficient preparation process, enzyme-assisted method has attracted widespread attention in recent years. This article will conduct in-depth discussions on the principles, process flow, advantages and future development directions of nanocellulase-assisted methods. Principle of Enzyme Assisted Method Enzyme Assisted Method uses cellulase (Cellulase) to biodegrade natural cellulose, selectively destroying the amorphous region of cellulose and retaining the crystalline region, thereby preparing nanocellulose. Cellulase is a complex enzyme, mainly consisting of the following three components: endoglucanase (En)

Nanocellulose preparation process: From natural cellulose to high-performance nanomaterials Nano-cellulose is a nano-scale material extracted from natural cellulose, with high mechanical strength, low density, high transparency and ability Excellent properties such as biodegradation and are widely used in composite materials, flexible electronics, biomedicine and other fields. The preparation process of nanocellulose is the basis of its application. This article will systematically introduce the main preparation methods and process characteristics of nanocellulose. Classification of Nanocellulose Nanocellulose is mainly divided into three categories: Cellulose nanocrystals (CNC, Cellulose Nanocrystals): rod-like structure with high crystallinity. Cellulose Nanofibers: a fibrous structure with a high aspect ratio. Bacterial Cell (BC, Bacterial Cell