共查询到19条相似文献,搜索用时 93 毫秒
1.
2.
3.
大米抗性淀粉压热处理制备工艺的研究 总被引:2,自引:0,他引:2
抗性淀粉以其显著优点及特殊的生理功能,成为食品营养学的一个研究热点。以大米淀粉为原料,制备大米抗性淀粉对大米的深加工具有重要的经济意义。以抗性淀粉得率为评价指标,通过单因素及正交试验研究了压热法制备抗性淀粉的最佳工艺参数。结果表明,对大米淀粉进行压热处理时,影响抗性淀粉得率的主次因素为:热处理温度热处理时间淀粉乳质量分数,最佳工艺条件为:热处理温度120℃,热处理时间70 min,淀粉乳质量分数30%。采用此组合进行验证性试验得抗性淀粉产率为9.54%。 相似文献
4.
5.
压热法制备绿豆抗性淀粉工艺的优化 总被引:2,自引:0,他引:2
研究了压热法制备绿豆抗性淀粉(MRS)的工艺参数。采用单因素实验比较了不同淀粉乳浓度、压热温度、压热时间、贮藏温度、贮藏时间对MRS得率的影响。在此基础上采用Box-Behnken的中心组合实验设计,优化MRS制备参数,建立了各因子与MRS得率关系的数学回归模型,确定了最佳的制备条件,即淀粉乳浓度为27.31%,贮藏温度为4.77℃,压热时间40 min时,MRS的产率为12.63%,与预测的理论值12.41%极为接近,与抗性淀粉含量为4.04%的绿豆原淀粉相比,MRS含量增加8.59%。 相似文献
6.
本文利用单因素实验在压热过程中研究了淀粉乳浓度、压热温度、压热时间、回生温度和回生时间5个因素对蚕豆抗性淀粉得率的影响。在此基础上,结合响应面试验优化制备工艺,并进一步通过X-射线衍射、傅里叶红外光谱和扫描电子显微镜分析了蚕豆抗性淀粉的结构表征。结果表明,蚕豆抗性淀粉的最佳制备工艺为:淀粉乳浓度31%,121 ℃下压热38 min,4 ℃下回生32 h。在该条件下,抗性淀粉得率为26.80%±0.82%,与预测值26.13%±1.50%相近,证明响应面模型与实际情况拟合良好。X-射线衍射结果表明,蚕豆淀粉颗粒呈椭球形,为A型淀粉;而抗性淀粉颗粒为不规则片层状或多边形堆积块状,为C型淀粉。红外光谱结果表明,在通过制备蚕豆抗性淀粉的过程中,没有发生化学反应,但产生了大量的分子间氢键。综上,本试验研究结果可为蚕豆抗性淀粉的制备及开发提供参考。 相似文献
7.
8.
压热法制备荞麦抗性淀粉的研究 总被引:1,自引:0,他引:1
以荞麦淀粉为原料,通过单因素及正交试验研究了压热法制备抗性淀粉的最佳工艺参数.结果表明:淀粉乳质量分数为20%,调节pH值为7.O,120℃压热处理90 min,4℃放置24 h.按此工艺参数制备荞麦抗性淀粉,其得率可达到15.54%. 相似文献
9.
10.
为提高参薯淀粉转化为抗性淀粉的产率,对参薯淀粉的压热法制备抗性淀粉进行了研究。以参薯淀粉为原料,通过单因素试验分析各种因素对抗性淀粉产率的影响;经过三因素二次正交旋转组合设计结合响应面分析,得出淀粉乳浓度、pH、压热时间对抗性淀粉含量的影响大小次序:淀粉乳浓度>pH>压热时间;最佳工艺条件为淀粉乳质量浓度33.00%,pH 7.6,121℃压热处理36 min,4℃下老化处理24 h,80℃烘干18 h,得到的抗性淀粉质量分数为13.92%。 相似文献
11.
12.
13.
Mung bean starch was subjected to a range of heat-moisture treatments (HMT) based on different moisture contents (15%, 20%, 25%, 30%, and 35%) all heated at 120 °C for 12 h. The impact on the yields of resistant starch (RS), and the microstructure, physicochemical and functional properties of RS was investigated. Compared to raw starch, the RS content of HMT starch increased significantly, with the starch treated at 20% moisture having the highest RS content. After HMT, birefringence remained at the periphery of the granules and was absent at the center of some granules. The shape and integrity of HMT starch granules did not change but concavity was observed under scanning electronic microscopy. Apparent amylose contents of HMT starch increased and the HMT starch was dominated by high molecular weight fraction. Both the native and HMT starches showed A-type X-ray diffraction pattern. Relative crystallinity increased after HMT. The gelatinization temperatures (To, Tp, and Tc), gelatinization temperature range (Tc–To) and enthalpies of gelatinization (ΔH) increased significantly in HMT starch compared to native starch. The solubility increased but swelling power decreased in HMT starches. This study clearly shows that the HMT exhibited thermal stability and resistance to enzymatic hydrolysis owing to stronger interactions of starch chains in granule. 相似文献
14.
超高压对小麦RS_3型抗性淀粉形成影响 总被引:1,自引:0,他引:1
以小麦淀粉为原料,利用超高压结合酶法制备RS3型抗性淀粉,以其得率为考察指标,研究超高压作用对抗性淀粉形成的影响。研究结果表明,超高压作用对RS3型抗性淀粉形成的最佳工艺条件为:淀粉乳浓度20%,超高压压力450 MPa,保压时间10 min,作用温度25℃,小麦RS3的平均得率达9.85%。 相似文献
15.
Khalil MM 《Die Nahrung》2001,45(4):246-250
Raw, soaked, germinated, autoclaved and cooked both of guar and faba bean were chemically and biologically evaluated. Crude protein, crude fiber and ash contents of guar and faba bean decreased as a result of all treatments with the exception of protein content in both germinated guar and faba bean. A slight decrease in lipid content was noticed during germination, while there were no changes in lipids after soaking, autoclaving and cooking. Protein content of guar was higher than of faba bean, and showed higher values for all amino acids than faba bean protein except for lysine and tryptophan. Germination caused a slight increase in total essential amino acids, while soaking caused a slight decrease in both of guar and faba bean. There was a slight decrease in the mineral contents by the heat processes with the exception of Mg and Mn for guar and Na, Mn for faba bean due to the cooking process. Germinated guar and faba bean showed noticeable decrease in Na, K, Cu, Mn and Mg and a slight increase in Fe and Zn than the raw materials. Germination was more effective in reducing phytic acid than heat treatment, and therefore it improves the nutritional quality of both guar and faba bean. Protein efficiency ratio (PER), true digestibility (DT) and biological value (BV) were estimated in all treatments under study using rat bioassay procedures. Data revealed pronounced improvements of the nutritive value as a result of all processes under study especially germination being the most effective. 相似文献
16.
17.
抗性淀粉是一种低热量的功能性食品成分,具有促进肠道健康、降低餐后血糖等保健作用,但常因在摄入食品中含量过低而难以发挥功效。为了促进抗性淀粉在食品工业中的实际应用,已有研究者尝试利用物理、化学、酶处理等加工方法提高淀粉及淀粉基食品中的抗性淀粉含量,其中物理方法最为常见,其提高效果显著、安全性高,还可以改善抗性淀粉的物理性质,有利于拓展抗性淀粉在食品工业中的应用。因此,本文综述了不同物理加工方法对淀粉及淀粉基食品中抗性淀粉含量的影响规律,并对比分析这些加工方法对该含量的提高效果,以期为提高食品中抗性淀粉含量提供高效的方法选择参考。 相似文献
18.