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Ver, resulting in serious environmental pollution and enormous waste of biological resources [3], [4]. The methods used for silk degumming in the laboratory involve treatment with highly concentrated urea [5], or pH neutral soap (Marseilles soap) [6], [7], or Na2CO3. Boiling for 30 min in 0.2,0.5 (W/V) Na2CO3 is the degumming method most commonly used in the laboratory. During this process, sericin is mostly hydrolyzed into peptides and free amino acids, which are difficult to separate and purify. A large number of alkaline substances are used for degumming; e.g. Bleach (NaClO) and softening agents are added to raw silk and silk fabrics for scouring and for the manufacture of spun silk as well as silk floss and silk biomaterials, making it difficult to separate and recycle the sericin present in vast amounts of degumming waste. Degumming at high temperature under high pressure [8] is a low-cost technique but it removes only the outer layer of sericin; the inner layer of sericin in contact with the fibroin fibers is not removed. Enzymatic degumming [9], [10] can completely remove the sericin by hydrolysis, but the degree of degumming efficiency is so low that it is unsuitable for largescale industrial production. There are reports of the use of organic acids as silk degumming solvents [11], [12], [13]. Only a very small amount of the sericin materials released by degumming cocoon shells is utilized commercially. The sericinderived material produced during degumming at high temperature under high pressure or by enzymatic degumming consists largely of sericin peptides. Typically, 23148522 a preparation of .30 kDaSilk Degumming and the Physical Propertiesproducts of silk sericin is used as a surface modifier for textile fibers and industrial products and there are reports of sericin peptides of ,30 kDa, particularly 10 kDa, being used as a tyrosinase inhibitor [14], an antioxidant [15], an antidiabetic agent [16] and an antitumor factor 18055761 [17], [18]. Sericin is a chemically inert non-ionic surfactant [19], [20] that does not induce pH changes, so it is suitable for mixing with other materials to produce sericin-based surfactants that are very gentle on human skin and particularly effective for the removal of oils. Sericin has long been used as an ingredient in cosmetics in Japan and other countries. Highly purified sericin can be used as a replacement for albumin or serum, thereby avoiding the introduction of animal pathogens [21], [22], [23]. Sericin is available commercially as a cell culture matrix or additive (Wako Product, Pure Sericin TM, Japan). Sericin alone or mixed with silk fibroin or other polymer material can be made into 3D porous human tissue engineering or biomimetic materials that can be used as a matrix for stem cell proliferation as well as for human tissue or organ regeneration [24]. It is likely that research and development of this silk protein for the production of medical tissue engineering materials will remain a focus of attention in the near future. Therefore, it is extremely important to develop novel environmentally friendly silk degumming agents for the recovery and utilization of sericin and/or sericin-derived materials. A decade ago, Kitagawa reported that acidic or alkaline electrolyzed water can be used for degumming B. mori cocoon silk [25]. Alkaline (pH 11,12) electrolyzed water was prepared by adding 0.107 electrolyzed accelerator (i.e. electrolytes such as sodium chloride, potassium carbonate etc.) to water. Seo.Ver, resulting in serious environmental pollution and enormous waste of biological resources [3], [4]. The methods used for silk degumming in the laboratory involve treatment with highly concentrated urea [5], or pH neutral soap (Marseilles soap) [6], [7], or Na2CO3. Boiling for 30 min in 0.2,0.5 (W/V) Na2CO3 is the degumming method most commonly used in the laboratory. During this process, sericin is mostly hydrolyzed into peptides and free amino acids, which are difficult to separate and purify. A large number of alkaline substances are used for degumming; e.g. Bleach (NaClO) and softening agents are added to raw silk and silk fabrics for scouring and for the manufacture of spun silk as well as silk floss and silk biomaterials, making it difficult to separate and recycle the sericin present in vast amounts of degumming waste. Degumming at high temperature under high pressure [8] is a low-cost technique but it removes only the outer layer of sericin; the inner layer of sericin in contact with the fibroin fibers is not removed. Enzymatic degumming [9], [10] can completely remove the sericin by hydrolysis, but the degree of degumming efficiency is so low that it is unsuitable for largescale industrial production. There are reports of the use of organic acids as silk degumming solvents [11], [12], [13]. Only a very small amount of the sericin materials released by degumming cocoon shells is utilized commercially. The sericinderived material produced during degumming at high temperature under high pressure or by enzymatic degumming consists largely of sericin peptides. Typically, 23148522 a preparation of .30 kDaSilk Degumming and the Physical Propertiesproducts of silk sericin is used as a surface modifier for textile fibers and industrial products and there are reports of sericin peptides of ,30 kDa, particularly 10 kDa, being used as a tyrosinase inhibitor [14], an antioxidant [15], an antidiabetic agent [16] and an antitumor factor 18055761 [17], [18]. Sericin is a chemically inert non-ionic surfactant [19], [20] that does not induce pH changes, so it is suitable for mixing with other materials to produce sericin-based surfactants that are very gentle on human skin and particularly effective for the removal of oils. Sericin has long been used as an ingredient in cosmetics in Japan and other countries. Highly purified sericin can be used as a replacement for albumin or serum, thereby avoiding the introduction of animal pathogens [21], [22], [23]. Sericin is available commercially as a cell culture matrix or additive (Wako Product, Pure Sericin TM, Japan). Sericin alone or mixed with silk fibroin or other polymer material can be made into 3D porous human tissue engineering or biomimetic materials that can be used as a matrix for stem cell proliferation as well as for human tissue or organ regeneration [24]. It is likely that research and development of this silk protein for the production of medical tissue engineering materials will remain a focus of attention in the near future. Therefore, it is extremely important to develop novel environmentally friendly silk degumming agents for the recovery and utilization of sericin and/or sericin-derived materials. A decade ago, Kitagawa reported that acidic or alkaline electrolyzed water can be used for degumming B. mori cocoon silk [25]. Alkaline (pH 11,12) electrolyzed water was prepared by adding 0.107 electrolyzed accelerator (i.e. electrolytes such as sodium chloride, potassium carbonate etc.) to water. Seo.

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Author: DNA_ Alkylatingdna