糖化酶
淀粉葡萄糖苷酶(Amylase, gluco-)
CAS: 9032-08-0
化学式: Cd+2
性质
褐色液体,溶于水,但不溶于乙醇、氯仿和乙醚。最适的pH值是4.0~4.5,最佳温度是60℃。
制法
以黑曲霉变异菌株经发酵制得。
用途
糖化酶可用于淀粉的水解,生产啤酒、黄酒、酱味精和抗生素;还用于葡萄糖、饴糖和糊精等的生浆的生产。
| 中文名 | 淀粉葡萄糖苷酶 |
| 英文名 | Amylase, gluco- |
| 别名 | 糖化酶 淀粉脱脂酶 糖化复合酶 葡萄糖淀粉酶 淀粉葡糖苷酶 啶粉葡糖苷酶 淀粉葡萄糖苷酶 |
| 英文别名 | AMG 300L Amylase, gluco- Glucoamylase, Rhizopus sp Glucoamylase from Rhizopus Amyloglucosidase from Aspergillus niger Saccharifying enzyMe(high conversion rate) Amyloglucosidase solution from Aspergillus niger Amyloglucosidase 2D Electrophoresis marker from Aspergillus niger 1,4-α-D-Glucan glucohydrolase, Exo-1,4-α-glucosidase, Glucoamylase |
| CAS | 9032-08-0 |
| EINECS | 232-877-2 |
| 化学式 | Cd+2 |
| 分子量 | 112.411 |
| 密度 | ~1.2g/mLat 25°C |
| 水溶性 | 125g/L at 25℃ |
| 蒸汽压 | 0.003Pa at 25℃ |
| 溶解度 | 0.03 M柠檬酸钠-磷酸盐缓冲液,pH 4.5: soluble5.0mg/mL |
| 存储条件 | 2-8°C |
| 外观 | 溶液 |
| 颜色 | white |
| 物化性质 | 近白色至浅棕色无定型粉末,或为浅棕色至深棕色液体,可分散于食用级稀释剂或载体中,也可含有稳定剂和防腐剂。可使多糖类(淀粉、糖原等)的α-1,4-和α-1,6-配糖键水解而成葡萄糖。溶于水,几不溶于乙醇、氯仿和乙醚。 |
| MDL号 | MFCD00081350 |
| 危险品标志 | Xi - 刺激性物品 Xn - 有害物品  T - 有毒物品  |
| 风险术语 | R36/37/38 - 刺激眼睛、呼吸系统和皮肤。 R42 - 吸入可能致敏。 R41 - 对眼睛有严重伤害。 R40 - 少数报道有致癌后果。 R37/38 - 刺激呼吸系统和皮肤+B52。 R24 - 与皮肤接触有毒。 R20/22 - 吸入及吞食有害。 |
| 安全术语 | S26 - 不慎与眼睛接触后,请立即用大量清水冲洗并征求医生意见。 S36 - 穿戴适当的防护服。 S36/37 - 穿戴适当的防护服和手套。 S24 - 避免皮肤接触。 S22 - 切勿吸入粉尘。 S45 - 若发生事故或感不适,立即就医(可能的话,出示其标签)。 S23 - 切勿吸入蒸汽。 S36/37/39 - 穿戴适当的防护服、手套和护目镜或面具。 S53 - 避免接触,使用前须获得特别指示说明。 S24/25 - 避免与皮肤和眼睛接触。 |
| WGK Germany | 3 |
| FLUKA BRAND F CODES | 3-10 |
| 海关编号 | 35079090 |
| 下游产品 | Α-淀粉酶 |
| 参考资料 展开查看 | 1. 叶婷 李爽 高源 范志红.6种烹调处理方式对红小豆淀粉组分及血糖反应的影响[J].中国食品学报 2020 20(08):100-106. 2. 姚远 陶玉贵 葛飞 等. 两种酿酒酵母发酵对桑葚米酒理化品质及香气成分的影响[J]. 食品工业科技 2019 040(024):242-250 261. 3. 胡慧芳 王玉川 江正强 等. 低分子质量瓜尔豆胶膳食纤维对面团流变学特性和馒头品质影响[J]. 中国粮油学报 2018 033(008):7-12. 4. 邵淋淋 曾诗雨 李秀娟 等. 全麦酒酿关键加工工艺对淀粉的理化性质及体外消化性的影响[J]. 食品与发酵工业 2019(15). 5. 周秀丽 李欣欣 马浩元 等. 半干法制备蜡质玉米微孔淀粉工艺条件的优化[J]. 中国粮油学报 2016 31(003):37-41. 6. 池明亮 岑莹 冯丽敏 等. 压热-酶解法制备青芒果抗性淀粉[J]. 食品工业科技 2017(11):255-257. 7. 金楠, 方鹏, 王红英,等. 基于均匀板加热法的饲料糊化参数试验研究[J]. 农业机械学报, 2019, v.50(10):336-343. 8. 孙士健, 王丽娟, 秦郦,等. 复合诱变筛选高产柠檬酸黑曲霉及其发酵研究[J]. 食品研究与开发, 2019(17):194-200. 9. 李欣欣, 杨圣岽, 吴海成,等. 复合酶法制备微孔淀粉工艺条件的优化[J]. 安徽农业科学, 2012(12):7438-7439. 10. 杨圣岽. 复合酶法制备马铃薯微孔淀粉的工艺研究[J]. 安徽农业科学, 40(09):5352-5354. 11. 彭博, 刘琴, 丁士勇. 山梨糖醇对面包储藏期间品质的影响[J]. 中国粮油学报, 2018(1):19-25. 12. 田龙,李俊涛.微孔淀粉的半干法制备条件及其理化特性研究[J].粮食与饲料工业,2018(03):15-19. 13. 皇圆圆,吴淑华,李飞,刘秉书,王雪源,马成业.挤压对豌豆渣不溶性膳食纤维膨胀性和持水性影响[J].山东理工大学学报(自然科学版),2020,34(06):59-64. 14. 刘秉书, 吴淑华, 孙谕莹,等. 挤压豌豆纤维粉制备的不可溶膳食纤维油脂吸附能力研究[J]. 食品研究与开发, 2020, 041(009):50-55. 15. 高帅, 李子钰, 陈露,等. 湿热处理对大豆蛋白-玉米淀粉抗消化复合物产率的影响[J]. 食品工业, 2018, v.39;No.260(05):26-28. 16. 吴淑华, 张喆浩, 范玉艳,等. 酶水解豌豆纤维粉制备低聚糖工艺优化[J]. 食品科学, 2019, v.40;No.607(18):295-302. 17. 刘淑一, 赵芳芳, 周小玲,等. 预糊化对燕麦全粉理化性质的影响[J]. 中国粮油学报, 2017(9). 18. 王彩娇, 赵安琪, 于雷,等. 高粱多孔淀粉制备工艺的优化及理化性质研究[J]. 粮食与油脂, 2019, v.32;No.281(009):35-39. 19. 刘淑婷 王颖 王志辉 等. 不同品种芸豆淀粉及其抗性淀粉结构和物化特性比较[J]. 中国食品学报 2020(4). 20. 曲鹏宇 李志江 李丹 等. 乳熟中期水稻茎中水溶性膳食纤维提取工艺研究[J]. 黑龙江八一农垦大学学报 2020 032(002):37-42 118. 21. 李长见. 双酶法玉米汁饮料的研制[J]. 农产品加工 2018 No.453(07):22-25+28. 22. 李长见, LI, Chang-jian,等. 抗氧化小米发酵饮料的研制[J]. 饮料工业, 2017, 06(v.20;No.175):30-33. 23. 贾玮, 张焱茜, 石琳,等. 海南红心木瓜膳食纤维提取及抗氧化活性测定[J]. 食品科技, 2018, 043(007):225-232. 24. 王迪, 王颖, 张艳莉,等. 芸豆酵素复合发酵工艺优化[J]. 食品与机械, 2019, 035(010):206-209,236. 25. 刘淑婷, 王颖, 王志辉,等. 超声-微波协同酶法制备芸豆抗性淀粉工艺优化及结构分析[J]. 中国食品学报, 2020, v.20(05):193-201. 26. 申瑞玲, 张文杰, 董吉林. 酶-热水浸提法提取藜麦麸水溶性非淀粉多糖工艺研究[J]. 轻工学报, 2016, v.31;No.137(01):29-34. 27. 皮双双, 王静祎, 陈亚淑,等. 黑糯玉米芯可溶性膳食纤维的提取、结构表征及抗氧化活性研究[J]. 食品工业科技, 2018(11). 28. 丁丽, 张志鹏, 彭远松,等. 小麦籽粒品质性状与葡萄糖和乙醇产量的关系[J]. 食品与发酵工业, 2019, 45:73-78. 29. 李杰, 于滨, 朱洁,等. 干燥方法对山药粉性质的影响[J]. 食品工业科技, 2020, v.41;No.444(04):68-72+119. 30. 魏劲松, 徐洲, 黄宪龙,等. 模糊数学结合响应面法优化葛根酒发酵工艺参数及其香气成分分析[J]. 食品工业科技, 2019, v.40;No.421(05):199-206. 31. 谢三都,陈惠卿,谢小伟,吴秀清.淮山药RS3抗性淀粉制备及其消化特性[J].农产品加工,2020(13):17-22. 32. 谢三都, 吴燕, 陈惠卿. 淮山药粉-硬脂酸复合物制备及其理化性质研究[J]. 食品研究与开发, 2020(16). 33. 阳雁, 李蒙蒙, 孙智达. 环境因素对米糠不溶性膳食纤维吸附蓝莓多酚的影响[J]. 食品工业科技, 2015, 36(018):137-140. 34. 储渊明, 李文, 王陶,等. 紫薯黄冠梨复合果酒酿制工艺研究[J]. 粮油食品科技, 2017, 025(006):61-64. 35. 李文, 王陶, 秦杰,等. 紫薯黄冠梨复合果醋醋酸发酵工艺研究[J]. 食品工业, 2018. 36. 梅新, 施建斌, 蔡沙,等. 马铃薯热干面干燥工艺研究[J]. 食品工业, 2019. 37. 谢岩黎, 南永远, 郝振宇. 微波湿热-循环冷冻对小麦淀粉结晶特性的影响[J]. 中国粮油学报, 2017, 32(010):49-53. 38. 谢岩黎, 王晨, 郝振宇. 抗性淀粉与小麦粉共混体系黏弹性的研究[J]. 中国粮油学报, 2018, v.33(02):33-38. 39. 张建萍, 江润生, 巫永华,等. 紫薯酒低温发酵工艺及酚类物质动态变化分析[J]. 食品工业, 2020(1). 40. 蔡沙, 隋勇, 施建斌,等. 马铃薯膳食纤维物化特性分析及其对马铃薯热干面品质的影响[J]. 食品科学, 2019(4):87-94. 41. 刘静怡 丁城 周梦舟 等. 双酶法分离提取米糠膳食纤维的研究[J]. 食品科技 2017(10):179-184. 42. 李鹏冲, 申瑞玲, 章建军,等. 麦麸多酚膳食纤维的提取工艺研究[J]. 食品工业, 2018, 39(12):88-91. 43. 李鹏冲, 李向力, 尹红娜,等. 山楂水溶性膳食纤维提取工艺及结构研究[J]. 食品研究与开发, 2019, 40(05):126-130. 44. 延莎, 王斐然, 赵柳微,等. 非热处理对蜂花粉杀菌效果及品质的影响[J]. 核农学报, 2020, v.34(08):140-148. 45. 余世锋, 杨庆余, 刘军,等. 酶解处理对大米RS_3型抗性淀粉产率的影响[J]. 食品工业, 2015(7):179-183. 46. 孙时光, 左勇, 徐佳, et al. 外源添加物对桑椹果酒高级醇的影响[J]. 食品与发酵工业, 2019, 045(019):180-187. 47. 邵玲, 李咏珊, 林佳虹,等. 淮山营养成分与品种选育分析[J]. 安徽农业科学, 2020, v.48;No.648(11):215-217+228. 48. 蔡沙,施建斌,隋勇,何建军,陈学玲,范传会,蔡芳,梅新.马铃薯淀粉物化特性分析及其对马铃薯热干面品质影响[J].现代食品科技,2019,35(01):72-81. 49. 姜龙波, 吕静, 张喜文,等. 小米糠膳食纤维复合酶法改性工艺优化[J]. 轻工学报, 2017, 32(005):16-23. 50. 刘丽娜, 傅曼琴, 徐玉娟,等. 玉米芯膳食纤维的复合酶法改性工艺优化[J]. 广东农业科学, 2019. 51. 洪泽翰, 吴婉仪, 李璐,等. 不同大分子乳化剂构建番茄红素纳米乳液的体外消化规律比较[J]. 食品科学, 2019, 40(10):9-15. 52. 菅田田, 屈磊, 马学明,等. 麸皮高酸海棠果饮料的研制[J]. 食品与发酵工业, 2016, 42(012):115-119. 53. 王欣,孟玉倩,徐宝成,罗登林,付元哲,李梦杰,韦玉花,焦玉曼.牡丹籽油高温碱煮—蒸汽爆破辅助水酶法提取工艺优化及其品质分析[J].食品与机械,2020,36(08):147-153 54. 张卉,刘姝含,杨楠楠,臧淑艳.优化黑果腺肋花楸果渣不可溶性膳食纤维的提取工艺[J].食品工业,2021,42(03):112-116. 55. 王成祥,张美娜,李婉珍,宋平,王彪.青稞膳食纤维的改性工艺研究[J].安徽农学通报,2020,26(17):126-128+135. 56. 孙铭泽,宋遥遥,卢晓霆.玉米粉液化及糖化工艺条件优化[J].中国酿造,2021,40(03):186-190. 57. 金楠,李腾飞,王红英,方鹏,段恩泽,陈计远.饲料限水糊化动力学及其颗粒结构特性的表征[J].农业工程学报,2020,36(16):293-299. 58. 张文莉,姚稳,巫永华,秦杰,苗敬芝.红茶菌发酵山药枸杞果醋的工艺研究[J].中国调味品,2021,46(04):119-123. 59. 谢三都,吴燕,陈惠卿.淮山药粉-硬脂酸复合物制备及其理化性质研究[J].食品研究与开发,2020,41(16):82-87. 60. 申瑞玲,李佳瑶,朱莹莹,董吉林.燕麦全谷微发酵饮品的研究[J].食品研究与开发,2021,42(02):78-83. 61. 唐健波,夏忠敏,谭娇,卢扬,章洁琼,李学琳,刘辉,蔡琴,刘军林,刘嘉.贵州主产区不同品种荞麦淀粉性能的比较[J].食品工业科技,2021,42(05):33-38+44. 62. 林鑫. 干热辅助食品胶处理对马铃薯淀粉性质影响及其应用[D].华中农业大学,2020. 63. 田双起,张锦霞,胡浩杰,王新伟,王彦波.远红外制备甘薯生全粉对面团流变学特性影响[J].食品工业,2020,41(09):55-59. 64. Xiao, Huashuai, et al. "Damage of proteins at the air/water interface: Surface tension characterizes globulin interface stability." International Journal of Pharmaceutics 584 (2020): 119445.http://doi.org/10.1016/j.ijpharm.2020.119445 65. XIONG, Ke, et al. Preparation of high fischer ratio oligopeptide of chlorella powder using specific enzymatic hydrolysis. Food Science and Technology, 2020. http://doi.org/10.1590/fst.42220 66. Huang, Ting-Ting, et al. "Effect of debranching and heat-moisture treatments on structural characteristics and digestibility of sweet potato starch." Food chemistry 187 (2015): 218-224.http://doi.org/10.1016/j.foodchem.2015.04.050 67. Lv, Qing-Qing, et al. "Evaluation studies on the combined effect of hydrothermal treatment and octenyl succinylation on the physic-chemical, structural and digestibility characteristics of sweet potato starch." Food chemistry 256 (2018): 413-418.http://do 68. Zheng, Y, Wei, Z, Zhang, R, et al. Optimization of the autoclave preparation process for improving resistant starch content in rice grains. Food Sci Nutr. 2020; 8: 2383– 2394. http://doi.org/10.1002/fsn3.1528 69. Ma, Yong-Shuai, et al. "Evaluation studies on effects of pectin with different concentrations on the pasting, rheological and digestibility properties of corn starch." Food chemistry 274 (2019): 319-323.http://doi.org/10.1016/j.foodchem.2018.09.005 70. Xie, Ying, et al. "Effects of the combination of repeated heat-moisture treatment and compound enzymes hydrolysis on the structural and physicochemical properties of porous wheat starch." Food chemistry 274 (2019): 351-359.http://doi.org/10.1016/j.foodche 71. Li, Meng-Na, et al. "Effects of debranching and repeated heat-moisture treatments on structure, physicochemical properties and in vitro digestibility of wheat starch." Food chemistry 294 (2019): 440-447.http://doi.org/10.1016/j.foodchem.2019.05.040 72. Hu, Xiao-Pei, et al. "Effects of continuous and intermittent retrogradation treatments on in vitro digestibility and structural properties of waxy wheat starch." Food chemistry 174 (2015): 31-36.http://doi.org/10.1016/j.foodchem.2014.11.026 73. Mei, Ji-Qiang, et al. "Effects of citric acid esterification on digestibility, structural and physicochemical properties of cassava starch." Food Chemistry 187 (2015): 378-384.http://doi.org/10.1016/j.foodchem.2015.04.076 74. Hu, Xiao-Pei, et al. "Effect of single-, dual-, and triple-retrogradation treatments on in vitro digestibility and structural characteristics of waxy wheat starch." Food chemistry 157 (2014): 373-379.http://doi.org/10.1016/j.foodchem.2014.02.065 75. Xie, Yao-Yu, et al. "Effect of repeated retrogradation on structural characteristics and in vitro digestibility of waxy potato starch." Food chemistry 163 (2014): 219-225.http://doi.org/10.1016/j.foodchem.2014.04.102 76. Huang, Ting-Ting, et al. "Effect of repeated heat-moisture treatments on digestibility, physicochemical and structural properties of sweet potato starch." Food Hydrocolloids 54 (2016): 202-210.http://doi.org/10.1016/j.foodhyd.2015.10.002 77. Hu, Xiao-Pei, et al. "Effect of high hydrostatic pressure and retrogradation treatments on structural and physicochemical properties of waxy wheat starch." Food chemistry 232 (2017): 560-565.http://doi.org/10.1016/j.foodchem.2017.04.040 78. Chen, Bo, et al. "Effect of glutenin and gliadin modified by protein-glutaminase on retrogradation properties and digestibility of potato starch." Food chemistry 301 (2019): 125226.http://doi.org/10.1016/j.foodchem.2019.125226 79. Zhang, Bao, et al. "Digestibility, physicochemical and structural properties of octenyl succinic anhydride-modified cassava starches with different degree of substitution." Food Chemistry 229 (2017): 136-141.http://doi.org/10.1016/j.foodchem.2017.02.061 80. Dao, Thai Ha, Jian Zhang, and Jie Bao. "Characterization of inulin hydrolyzing enzyme (s) in commercial glucoamylases and its application in lactic acid production from Jerusalem artichoke tubers (Jat)." Bioresource technology 148 (2013): 157-162.http://d 81. Ding, Yangyue, et al. "Effects of endogenous proteins and lipids on structural, thermal, rheological, and pasting properties and digestibility of adlay seed (Coix lacryma-jobi L.) starch." Food Hydrocolloids 111 (2021): 106254.http://doi.org/10.1016/j.foo 82. Xie, Yao-Yu, et al. "Effect of temperature-cycled retrogradation on in vitro digestibility and structural characteristics of waxy potato starch." International journal of biological macromolecules 67 (2014): 79-84.http://doi.org/10.1016/j.ijbiomac.2014.03 83. Zhang, Haihua, et al. "Effect of tea products on the in vitro enzymatic digestibility of starch." Food chemistry 243 (2018): 345-350.http://doi.org/10.1016/j.foodchem.2017.09.138 84. Li, Panyu, et al. "Effect of pretreatment on the enzymatic hydrolysis of kitchen waste for xanthan production." Bioresource technology 223 (2017): 84-90.http://doi.org/10.1016/j.biortech.2016.10.035 85. Ye, Guangying, et al. "Ethanol production from mixtures of sugarcane bagasse and Dioscorea composita extracted residue with high solid loading." Bioresource technology 257 (2018): 23-29.http://doi.org/10.1016/j.biortech.2018.02.008 86. Li, Haiyan, et al. "Construction of octenyl succinic anhydride modified porous starch for improving bioaccessibility of β-carotene in emulsions." RSC Advances 10.14 (2020): 8480-8489.10.1039/C9RA10079B 87. [IF=9.642] Thai Ha Dao et al."Characterization of inulin hydrolyzing enzyme(s) in commercial glucoamylases and its application in lactic acid production from Jerusalem artichoke tubers (Jat)."Bioresource Technol. 2013 Nov;148:157 88. [IF=9.642] Guangying Ye et al."Ethanol production from mixtures of sugarcane bagasse and Dioscorea composita extracted residue with high solid loading."Bioresource Technol. 2018 Jun;257:23 89. [IF=9.642] Panyu Li et al."Effect of pretreatment on the enzymatic hydrolysis of kitchen waste for xanthan production."Bioresource Technol. 2017 Jan;223:84 90. [IF=9.147] Ting-Ting Huang et al."Effect of repeated heat-moisture treatments on digestibility, physicochemical and structural properties of sweet potato starch."Food Hydrocolloid. 2016 Mar;54:202 91. [IF=9.147] An-Qi Zhao et al."Effects of the combination of freeze-thawing and enzymatic hydrolysis on the microstructure and physicochemical properties of porous corn starch."Food Hydrocolloid. 2018 Oct;83:465 92. [IF=7.514] Yao-Yu Xie et al."Effect of repeated retrogradation on structural characteristics and in vitro digestibility of waxy potato starch."Food Chem. 2014 Nov;163:219 93. [IF=7.514] Xiao-Pei Hu et al."Effects of continuous and intermittent retrogradation treatments on in vitro digestibility and structural properties of waxy wheat starch."Food Chem. 2015 May;174:31 94. [IF=7.514] Ting-Ting Huang et al."Effect of debranching and heat-moisture treatments on structural characteristics and digestibility of sweet potato starch."Food Chem. 2015 Nov;187:218 95. [IF=7.514] Ji-Qiang Mei et al."Effects of citric acid esterification on digestibility, structural and physicochemical properties of cassava starch."Food Chem. 2015 Nov;187:378 96. [IF=7.514] Qing-Qing Lv et al."Evaluation studies on the combined effect of hydrothermal treatment and octenyl succinylation on the physic-chemical, structural and digestibility characteristics of sweet potato starch."Food Chem. 2018 Aug;256:413 97. [IF=7.514] Wenjun Bao et al."Insights into the crystallinity and in vitro digestibility of chestnut starch during thermal processing."Food Chem. 2018 Dec;269:244 98. [IF=7.514] Meng-Na Li et al."Effects of heat-moisture treatment after citric acid esterification on structural properties and digestibility of wheat starch, A- and B-type starch granules."Food Chem. 2019 Jan;272:523 99. [IF=7.514] Ying Xie et al."Effects of the combination of repeated heat-moisture treatment and compound enzymes hydrolysis on the structural and physicochemical properties of porous wheat starch."Food Chem. 2019 Feb;274:351 100. [IF=7.514] Yong-Shuai Ma et al."Evaluation studies on effects of pectin with different concentrations on the pasting, rheological and digestibility properties of corn starch."Food Chem. 2019 Feb;274:319 101. [IF=7.514] Bao Zhang et al."Digestibility, physicochemical and structural properties of octenyl succinic anhydride-modified cassava starches with different degree of substitution."Food Chem. 2017 Aug;229:136 102. [IF=7.514] Xiao-Pei Hu et al."Effect of high hydrostatic pressure and retrogradation treatments on structural and physicochemical properties of waxy wheat starch."Food Chem. 2017 Oct;232:560 103. [IF=7.514] Haihua Zhang et al."Effect of tea products on the in vitro enzymatic digestibility of starch."Food Chem. 2018 Mar;243:345 104. [IF=6.953] Yao-Yu Xie et al."Effect of temperature-cycled retrogradation on in vitro digestibility and structural characteristics of waxy potato starch."Int J Biol Macromol. 2014 Jun;67:79 105. [IF=6.953] Rui Wang et al."Effects of different treatment methods on properties of potato starch-lauric acid complex and potato starch-based films."Int J Biol Macromol. 2019 Mar;124:34 106. [IF=3.638] Ji-lin Dong et al."Structural, antioxidant and adsorption properties of dietary fiber from foxtail millet (Setaria italica) bran."J Sci Food Agr. 2019 Jun;99(8):3886-3894 107. [IF=1.632] Yuanliang Hu et al."Conversion of yellow wine lees into high-protein yeast culture by solid-state fermentation."Biotechnol Biotec Eq. 2014;28(5):843-849 108. [IF=1.632] Yuanliang Hu et al."Optimization of Saccharomyces boulardii production in solid-state fermentation with response surface methodology."Biotechnol Biotec Eq. 2016;30(1):173-179 109. [IF=1.022] Xiaoyu Wen et al."Structural and Functional Properties of Slowly Digestible Starch from Chinese Chestnut."Int J Food Eng. 2018 Mar;14(3): 110. [IF=9.381] Pengfei Liu et al."Effects of amylose content and enzymatic debranching on the properties of maize starch-glycerol monolaurate complexes."Carbohyd Polym. 2019 Oct;222:115000 111. [IF=9.147] Yuejia Ning et al."Decreasing the digestibility of debranched corn starch by encapsulation with konjac glucomannan."Food Hydrocolloid. 2020 Oct;107:105966 112. [IF=9.147] Chong-Chong Wang et al."Effects of insoluble dietary fiber and ferulic acid on the rheological properties of dough."Food Hydrocolloid. 2021 Dec;121:107008 113. [IF=7.514] Chong-Chong Wang et al."Effects of insoluble dietary fiber and ferulic acid on the quality of steamed bread and gluten aggregation properties."Food Chem. 2021 Dec;364:130444 114. [IF=7.514] Siyu Lin et al."Effects of xanthan and konjac gums on pasting, rheology, microstructure, crystallinity and in vitro digestibility of mung bean resistant starch."Food Chem. 2021 Mar;339:128001 115. [IF=7.514] Siyu Lin et al."Effects of xanthan and konjac gums on pasting, rheology, microstructure, crystallinity and in vitro digestibility of mung bean resistant starch."Food Chem. 2021 Mar;339:128001 116. [IF=7.514] Wenhui Zhang et al."Insights into the structure and conformation of potato resistant starch (type 2) using asymmetrical flow field-flow fractionation coupled with multiple detectors."Food Chem. 2021 Jul;349:129168 117. [IF=7.182] Yongbo Ding et al."Understanding the mechanism of ultrasonication regulated the digestibility properties of retrograded starch following vacuum freeze drying."Carbohyd Polym. 2020 Jan;228:115350 118. [IF=6.953] Tiange Song et al."Insights into the correlations between the size of starch at nano- to microscale and its functional properties based on asymmetrical flow field-flow fractionation."Int J Biol Macromol. 2021 Dec;193:500 119. [IF=6.953] Yanjun Cui et al."Poly-acrylic acid grafted natural rubber for multi-coated slow release compound fertilizer: Preparation, properties and slow-release characteristics."Int J Biol Macromol. 2020 Mar;146:540 120. [IF=6.953] Yu-Sheng Wang et al."Preparation of VII-type normal cornstarch-lauric acid complexes with high yield and stability using a combination treatment of debranching and different complexation temperatures."Int J Biol Macromol. 2020 Jul;154:456 121. [IF=6.953] Lingling Wang et al."Loading paclitaxel into porous starch in the form of nanoparticles to improve its dissolution and bioavailability."Int J Biol Macromol. 2019 Oct;138:207 122. [IF=6.953] Bin Yu et al."Physicochemical properties and in vitro digestibility of hydrothermal treated Chinese yam (Dioscorea opposita Thunb.) starch and flour."Int J Biol Macromol. 2021 Apr;176:177 123. [IF=5.118] Tian Fang et al."Enzymatic Degradation of Gracilariopsis lemaneiformis Polysaccharide and the Antioxidant Activity of Its Degradation Products."Mar Drugs. 2021 May;19(5):270 124. [IF=4.952] Yinxia Li et al."Effects of fermentation with lactic bacteria on the structural characteristics and physicochemical and functional properties of soluble dietary fiber from prosomillet bran."Lwt Food Sci Technol. 2022 Jan;154:112609 125. [IF=4.952] Zihan Shao et al."Process optimization, digestibility and antioxidant activity of extruded rice with Agaricus bisporus."Lwt Food Sci Technol. 2021 Dec;152:112350 126. [IF=4.952] Meixuan Li et al."Microstructure, physicochemical properties, and adsorption capacity of deoiled red raspberry pomace and its total dietary fiber."Lwt Food Sci Technol. 2022 Jan;153:112478 127. [IF=4.952] Zhuohui Xu et al."Alterations in structural and functional properties of insoluble dietary fibers-bound phenolic complexes derived from lychee pulp by alkaline hydrolysis treatment."Lwt Food Sci Technol. 2020 Jun;127:109335 128. [IF=3.119] Haiyan Li et al."Construction of octenyl succinic anhydride modified porous starch for improving bioaccessibility of β-carotene in emulsions."Rsc Adv. 2020 Feb;10(14):8480-8489 129. [IF=2.863] Yunzhan Zheng et al."Optimization of the autoclave preparation process for improving resistant starch content in rice grains."Food Sci Nutr. 2020 May;8(5):2383-2394 130. [IF=1.718] ZHANG Xiunan et al."Effect of heat-moisture treatment on physicochemical properties and digestive characteristics of sweet potato flour."Food Sci Tech-Brazil. 2022 Mar;42: 131. [IF=5.64] Shuai Luo et al."Analysis of the Formation of Sauce-Flavored Daqu Using Non-targeted Metabolomics."Front Microbiol. 2022 Mar 24;13:857966 132. [IF=3.616] Ni Han et al."Effect of ball milling treatment on the structural, physicochemical and digestive properties of wheat starch, A- and B-type starch granules."J Cereal Sci. 2022 Mar;104:103439 133. [IF=7.514] Xuemin Kang et al."The formation of starch-lipid complexes by microwave heating."Food Chem. 2022 Jul;382:132319 134. [IF=6.419] Weiwei Wu et al."Construction, characterization, and bioavailability evaluation of honokiol-loaded porous starch by melting method without any solvent."Drug Deliv. 2021;28(1):2574-2581 135. [IF=6.953] Yongjie Lin et al."Properties and digestibility of a novel porous starch from lotus seed prepared via synergistic enzymatic treatment."Int J Biol Macromol. 2022 Jan;194:144 136. [IF=6.953] Yongjie Lin et al."Properties and digestibility of a novel porous starch from lotus seed prepared via synergistic enzymatic treatment."Int J Biol Macromol. 2022 Jan;194:144 137. [IF=9.147] Tao Xu et al."Modulating the digestibility of cassava starch by esterification with phenolic acids."Food Hydrocolloid. 2021 Dec;:107432 138. [IF=3.196] Yangyang Fan et al."Inhibitory interaction of narcissoside on α-glucosidase from Aspergillus niger and Saccharomyces cerevisiae by spectral analysis and molecular docking."JOURNAL OF MOLECULAR STRUCTURE. 2022 Sep;1264:133262 139. [IF=2.72] Lili Zhao et al."Effect of Lactobacillus rhamnosus GG fermentation on the structural and functional properties of dietary fiber in bamboo shoot and its application in bread."JOURNAL OF FOOD BIOCHEMISTRY |
糖化酶 - 性质
可信数据
褐色液体,溶于水,但不溶于乙醇、氯仿和乙醚。最适的pH值是4.0~4.5,最佳温度是60℃。
最后更新:2025-06-10 22:55:16
糖化酶 - 制法
可信数据
以黑曲霉变异菌株经发酵制得。
最后更新:2022-01-01 10:09:02
糖化酶 - 介绍
&&来源:黑曲霉。 &&活力:≥100 units/mg。 &&分子量:80~97kDa。 &&活力定义:1克酶粉或1毫升酶液在40℃、PH4.6的条件下,1小时水解可溶性淀粉产生1毫克葡萄糖的酶量为1个酶活力单位(U)。 &&重金属:≤30ppm。 &&最适pH:4.5。 &&性状:粉末。 &&稳定性:本品耐酸性较好,在25℃、pH3时活力稳定,55~60℃时活力最高,60℃30分钟以上活力损失显著,80℃以上活力全部消失。
最后更新:2022-10-16 17:29:59
糖化酶 - 用途
可信数据
糖化酶可用于淀粉的水解,生产啤酒、黄酒、酱味精和抗生素;还用于葡萄糖、饴糖和糊精等的生浆的生产。
最后更新:2025-08-19 16:24:40
糖化酶 - 简介
淀粉葡萄糖苷酶(amylase)是一种能够催化淀粉分解为葡萄糖单体的酶。它主要存在于各种生物体中,如人体唾液、胃液、胰液,以及植物和微生物中。
淀粉葡萄糖苷酶可通过微生物发酵法或重组DNA技术获得。微生物发酵法通常使用产生淀粉葡萄糖苷酶的微生物菌种,如酵母或真菌,进行培养和提取。重组DNA技术可以将淀粉葡萄糖苷酶基因导入到合适的宿主进行表达,从而生产大量的酶。
淀粉葡萄糖苷酶一般被认为是相对安全的。对于敏感的个体来说,过度暴露或过敏反应可能会引发不适症状。在使用淀粉葡萄糖苷酶时,应遵循适当的安全操作指南,避免直接接触酶液和避免吸入粉尘形式的酶。应注意对工作场所进行良好通风和个人防护措施,避免酶的误摄入和直接暴露。如果发生任何不适反应,应立即就医。
淀粉葡萄糖苷酶可通过微生物发酵法或重组DNA技术获得。微生物发酵法通常使用产生淀粉葡萄糖苷酶的微生物菌种,如酵母或真菌,进行培养和提取。重组DNA技术可以将淀粉葡萄糖苷酶基因导入到合适的宿主进行表达,从而生产大量的酶。
淀粉葡萄糖苷酶一般被认为是相对安全的。对于敏感的个体来说,过度暴露或过敏反应可能会引发不适症状。在使用淀粉葡萄糖苷酶时,应遵循适当的安全操作指南,避免直接接触酶液和避免吸入粉尘形式的酶。应注意对工作场所进行良好通风和个人防护措施,避免酶的误摄入和直接暴露。如果发生任何不适反应,应立即就医。
最后更新:2024-04-09 20:52:54
供应商列表
现货供应
产品名: 糖化酶(1:100000) 去供应商网站查看 询盘CAS: 9032-08-0
产地: 北京
包装: 瓶
规格: T8500-250g,250g,T8501-500g,500g
价格: 电话、微信、QQ、邮件
库存: 现询
电话: 010-50973130
手机: 18101056239(微信同号)
电子邮件: 3193328036@qq.com
QQ: 3193328036
微信: 18101056239
产品描述: 产品覆盖:小分子化合物、分析对照品、染色试剂、生化试剂盒、细胞生物学、分子生物学、抗体、蛋白、多肽、ELISA试剂盒、微生物培养、化学合成、仪器耗材、CRO技术 更多
提供多种规格现货供应
产品名: Glucoamylase, Rhizopus sp. 去供应商网站查看 询盘CAS: 9032-08-0
产地: 美国
包装: 1 g;10 g
规格: HY-P2857A
库存: 询盘
电话: 021-38924433; 021-58955995
手机: 18019480960
电子邮件: sales@medchemexpress.cn
产品描述: 产品覆盖:8万多种抑制剂,11000+靶点蛋白,数百款试剂盒,200+生物活性化合物库,天然产物,抗体等. 纯度:
现货供应
产品名: 糖化酶(1:100000) 去供应商网站查看 询盘CAS: 9032-08-0
产地: 北京
包装: 瓶
规格: T8500-250g,250g,T8501-500g,500g
价格: 电话、微信、QQ、邮件
库存: 现询
电话: 010-50973130
手机: 18101056239(微信同号)
电子邮件: 3193328036@qq.com
QQ: 3193328036
微信: 18101056239
产品描述: 产品覆盖:小分子化合物、分析对照品、染色试剂、生化试剂盒、细胞生物学、分子生物学、抗体、蛋白、多肽、ELISA试剂盒、微生物培养、化学合成、仪器耗材、CRO技术 更多
提供多种规格现货供应
产品名: Glucoamylase, Rhizopus sp. 去供应商网站查看 询盘CAS: 9032-08-0
产地: 美国
包装: 1 g;10 g
规格: HY-P2857A
库存: 询盘
电话: 021-38924433; 021-58955995
手机: 18019480960
电子邮件: sales@medchemexpress.cn
产品描述: 产品覆盖:8万多种抑制剂,11000+靶点蛋白,数百款试剂盒,200+生物活性化合物库,天然产物,抗体等. 纯度:
糖化酶的上游原料
糖化酶的下游产品
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