马铃薯抗性淀粉结构特征及体外消化特性的研究

研究马铃薯抗性淀粉的结构特征与体外消化特性。方法 以马铃薯淀粉为对照, 采用红外光谱仪、XRD、DSC等手段研究了马铃薯抗性淀粉的碘吸收特性、颗粒形貌、晶型结构形态、热特性等。通过模拟体外消化评价了抗性淀粉的消化性能。结果 马铃薯淀粉和抗性淀粉碘吸收曲线最大吸收峰在580~600 nm,马铃薯抗性淀粉分子量分布更集中。马铃薯淀粉为B型结晶结构, 马铃薯抗性淀粉为C型结晶结构。SEM观察显示：马铃薯淀粉分子颗粒完整, 表面光滑, 整体呈不规则的椭圆形; 马铃薯抗性淀粉分子为不规则多面体, 分子表面粗糙、有凹陷, 且有少量的层状起伏; 红外光谱分析表明抗性淀粉未出现新的基团。DSC检测发现：马铃薯抗性淀粉的热稳定性更高; 马铃薯淀粉和抗性淀粉酶解前2 h内消化速率迅速增加, 酶解2 h后速率减慢, 消化速率逐渐趋于平缓, 血糖指数分别为70.42、40.50。结论 说明马铃薯抗性淀粉具有较致密的结晶结构和酶抗性, 抗消化性显著。     

怀山药抗性淀粉理化性质及体外消化性研究

分析比较怀山药淀粉和压热法制备的怀山药抗性淀粉的理化性质及消化特性。结果表明:怀山药淀粉颗粒表面光滑,呈不规则且大小不一的椭球形、三角形等形态,属于C型淀粉;抗性淀粉颗粒特征消失,呈现表面疏松的片层状结构。2种淀粉化学结构相似,抗性淀粉没有形成新的基团。与原淀粉相比,抗性淀粉分子量分布更加集中。抗性淀粉的糊化峰值温度高于原淀粉的,因此其热稳定性更高。抗性淀粉的透明度低于原淀粉的。水浴温度低于75℃时,抗性淀粉的持水性大于原淀粉的,而当水浴温度高于原淀粉糊化温度时,原淀粉的持水性明显高于抗性淀粉的;体外模拟人体消化试验表明,抗性淀粉比原淀粉更耐消化。     

低GI淀粉原料的筛选及理化特性和体外消化特性的研究

以豌豆、马铃薯、玉米、木薯、大米、小麦、鹰嘴豆中的淀粉为研究对象,对其淀粉颗粒形貌、粒径分布、糊化特性、直链淀粉含量及淀粉组分进行探究,并采用体外消化试验分析7种淀粉的体外消化特性,计算其预测血糖生成指数(expected glycemic index,eGI)。结果表明:豌豆淀粉和鹰嘴豆淀粉粒度分布比较集中,大小较均匀;豌豆淀粉和鹰嘴豆淀粉的回生值较高,易于老化;豌豆淀粉和鹰嘴豆淀粉的直链淀粉含量较高,玉米淀粉中快消化淀粉含量最高,马铃薯淀粉慢消化淀粉含量最高,而鹰嘴豆淀粉的抗性淀粉含量最高。体外消化试验结果表明:鹰嘴豆淀粉体外消化率曲线增速最慢,7种淀粉的eGI值从低到高依次为:鹰嘴豆淀粉(48.9)小麦淀粉(57.7)豌豆淀粉(59.9)玉米淀粉(67.3)木薯淀粉(70.2)马铃薯淀粉(70.3)大米淀粉(76.3)。     

紫山药淀粉与其抗性淀粉理化性质的比较

以紫山药淀粉为研究原料,采用不同方法分别制备压热、酶解-压热及双酶纯化抗性淀粉,分析比较了紫山药淀粉与其抗性淀粉的理化性质。试验结果表明:紫山药淀粉颗粒呈圆形或椭圆形且表面光滑;抗性淀粉颗粒破碎且呈不规则型。4种淀粉的化学结构相似,与原淀粉相比,抗性淀粉没有生成新的基团。抗性淀粉样品的凝沉速度随直链淀粉含量的增加而加快,冻融稳定性则降低;碘吸收曲线向支链淀粉吸收波长方向偏移。流变学分析表明与原淀粉相比抗性淀粉表观黏度均增大,剪切结构恢复力与抗性淀粉含量成反比。     

小麦抗性糊精制备工艺优化、结构表征及其体外消化

为探究酸热法制备小麦抗性糊精的最佳制备工艺、结构及其消化特性,该试验以小麦淀粉为原料,以抗性糊精得率为指标,通过单因素和响应面试验对小麦抗性糊精制备酸热条件进行优化,对其结构进行表征,并考察其体外消化特性。抗性糊精的最佳酸热工艺条件为盐酸浓度0.075 mol/L、酸热温度180 ℃、酸热时间95 min,经α-淀粉酶、淀粉葡糖苷酶酶解后抗性糊精得率为（43.83±0.08）%,抗性糊精含量为（86.99±0.23）%。抗性糊精微观结构形态呈无规则小碎片状,表面富有孔洞,不再具有小麦淀粉“A”型晶体结构,没有新的官能团产生,抗性糊精重均分子质量为7.39×103 g/mol;通过体外模拟消化试验表明小麦抗性糊精水解率远小于小麦淀粉,抗性糊精具有良好的抗消化性。     

螺杆挤压对马铃薯淀粉消化性及血糖指数的影响

目的研究螺杆挤压对马铃薯淀粉消化特性的影响。方法马铃薯淀粉经过螺杆挤压后(过程中淀粉未膨化),采用酶重量法测定挤压后抗性淀粉的含量变化情况,并通过模拟体外消化和动物实验评价挤压后淀粉的消化性能和餐后血糖上升速率。结果螺杆挤压后马铃薯淀粉中抗性淀粉的含量增加了1.08%,酶解时间为0~1.5 h时,马铃薯淀粉快速消化淀粉的含量减少,酶解时间为1.5~6.5 h时,抗性淀粉和慢消化淀粉的含量增加。挤压后的马铃薯淀粉在一定程度上可以降低小鼠的餐后血糖指数。结论螺杆挤压技术可以提高抗性淀粉和慢消化淀粉的含量,减缓餐后血糖上升速率,为马铃薯食品的深度开发提供一定的参考。     

干热处理对藜麦淀粉结构和理化性质的影响

以高筋小麦粉为原料添加酵母制作面团,在温度28℃、湿度80%条件下发酵1～6 h,提取小麦淀粉。研究发酵时间对小麦直链淀粉含量、损伤淀粉含量、粒径、颗粒表面结构、糊化及消化特性的影响。结果表明：面团发酵1 h后直链淀粉含量和损伤淀粉含量均显著低于原淀粉(P<0.05)。快速黏度分析结果表明,发酵1 h的小麦淀粉峰值黏度、热浆黏度和冷浆黏度最低。发酵处理后淀粉的粒径均小于原淀粉,其中发酵5 h的平均粒径最小。扫描电镜结果表明,发酵6 h的小麦淀粉颗粒表面出现破裂现象。体外消化实验表明,发酵5 h和6 h小麦淀粉的消化速率最高,发酵后抗性淀粉含量低于原淀粉,而慢消化淀粉含量高于原淀粉(P<0.05)。     

高直链玉米III型抗性淀粉制备及其结构和特性

以高直链玉米淀粉G50和G70为原料,经酸解、糊化、脱支和重结晶步骤获得III型抗性淀粉,通过退火与压热处理以进一步提升淀粉的抗性比例。采用扫描电子显微镜、X射线衍射、差示扫描量热、快速黏度分析等方法,研究淀粉颗粒形貌、结晶结构、热特性及糊化特性,利用Englyst法测试淀粉消化特性。结果表明：高直链玉米淀粉G50和G70酸解后的得率分别为77.9%和84.5%,重结晶后的得率降为54.4%和70.2%。原G50和G70改性后,淀粉颗粒形貌被破坏,形成大小不等、颗粒形貌不规则的团聚体;淀粉结晶型由B＋V型转变为A＋V型,且结晶度升高;淀粉糊化温度升高,且加热过程中黏度几乎消失。溶解与膨胀特性结果表明,经酸解、糊化、脱支和老化处理后原G50和G70的溶解性显著升高,退火和压热处理后降低了III型抗性淀粉的溶解性和膨胀度。体外消化特性分析表明,改性后的G50和G70具备更强的抗消化性能,抗性淀粉含量最高可达80.5%（G70-RS3-压热20%）。本研究的改性处理能有效提高高直链玉米淀粉G50和G70中抗性淀粉含量,同时抗性淀粉含量与结晶度和糊化温度呈显著正相关。     

小麦抗性糊精的酸热法制备、表征及消化特性分析

目的 探讨酸热法制备小麦抗性糊精的理化特征及消化特性。方法 以小麦淀粉为原料,采用酸热法制备小麦抗性糊精,对其表面结构、红外光谱、结晶性、流变学和热力学特性进行表征,并对其体外消化特性进行探讨。结果 酸热处理有效地促进小麦淀粉的糊精化,淀粉晶体结构发生改变,淀粉颗粒形貌由规则、光滑的扁椭球形转变为不规则致密块状。红外光谱分析表明,小麦抗性糊精与淀粉糖苷键类型分布有所不同。小麦抗性糊精比天然小麦淀粉具有更高的起始温度(100.77℃±0.69℃)、峰值温度(111.86℃±0.11℃)、终止温度(124.77℃±0.49℃)和焓值(8.69℃±0.33℃)。小麦抗性糊精溶液(10%, m:V)流变学特性呈现典型的牛顿流体特征,具有较好的抗剪切性。体外消化分析结果显示,所制备小麦抗性糊精抗消化性成分含量高达98.37%。结论 酸热法制备的小麦抗性糊精具有良好的热转变特性、流变学稳定性和抗消化性。     

抗性淀粉直链淀粉含量测定及消化性研究

以蜡质玉米淀粉为原料,经过糊化后使用普鲁兰酶脱支,产生更多的短直链淀粉重新结晶来制备抗性淀粉。通过碘吸光度法测定,直链淀粉含量高的样品的抗性淀粉含量不一定高,但直链淀粉含量低的样品不容易产生高含量抗性淀粉。在In-Vitro消化模型中,和原淀粉相比,所有的抗性淀粉样品消化产物的量、还原糖释放率和平均消化速率都减少或降低,并且抗性淀粉含量越高,减少或降低得越多。     

Effects of gamma irradiation on starch digestibility of rice with different resistant starch content

Three rice cultivars (RS3M, RS4H and RS5L) differing in resistant starch contents but similar in genetic background were chosen to study the effects of gamma irradiation on starch physicochemical properties and digestibility. Irradiation increases the resistant starch content in all the three cultivars and in a dose‐dependent manner in rice with low‐resistant starch content (RS5L). Irradiation decreases apparent amylose content and gelatinisation temperature and changed the starch granule structure, while increasing V‐type crystallinity. Starch enzymatic hydrolysis rate was reduced following irradiation, and the effect of irradiation on reducing starch digestibility was negatively correlated with resistant starch content. Treatment with gamma irradiation has therefore a potential for increasing resistant starch content and producing low digestibility of starch in common rice.     

Physicochemical characterisation,digestibility and anticonstipation activity of some high‐resistant untraditional starches from zingiberaceae plants

To find new starch sources with particular characteristics, five untraditional starches from zingiberaceae plants were studied about their physicochemical properties, digestibility and anticonstipation activity and compared with starches from traditional sources (potato and corn). All the five starches presented the shape of triangular, with visible thin sheet, which were significantly different from conventional sources. The crystal type of these five starches was B‐type pattern. Swelling power at 75 °C was negatively correlated with crystallinity. There was no significant difference in amylose content between starches from rhizome and tuber of Curcuma phaeocaulis Val., while they displayed significant variability in RS content. Starches from rhizome of Curcuma kwangsiensis, Curcuma wenyujin, Curcuma phaeocaulis Val. and Curcuma longa L. possessed much higher resistant starch content (range from 87.06% to 95.40%) and could better prevent constipation than potato and corn starches, which made them potential for managing diabetes and improving defecation conditions.     

马铃薯抗性淀粉对韧性饼干品质及消化性能的控制

目的 研究马铃薯抗性淀粉对韧性饼干消化性能及品质的影响规律, 为评价和提高马铃薯抗性淀粉韧性饼干的品质奠定基础。方法 通过将马铃薯抗性淀粉作为膳食纤维成分, 按照不同比例替代面粉, 制作成韧性饼干, 对韧性饼干的延展性、色泽、感官、质构特性、表观结构等物理特性、营养成分及消化性能进行测定, 研究马铃薯抗性淀粉对韧性饼干品质及消化性能的影响。结果 随着马铃薯抗性淀粉的增加, 韧性饼干的延展性总体呈增长趋势,蛋白质和脂肪含量逐渐减少,水分和灰分含量差异不显著。在马铃薯抗性淀粉添加为20%时饼干色泽均匀,硬度、脆性和咀嚼性均较好, 感官评分最高, 为82.6分。SEM观察发现随着马铃薯抗性淀粉的添加饼干结构显示暴露在油脂外的淀粉颗粒逐渐增加。马铃薯抗性淀粉的加入降低系统中淀粉的水解速率, 进而调节饼干的体外消化率, 降低血糖指数, 添加30%马铃薯抗性淀粉时, 血糖指数为62.06, 已达到中等血糖指数。结论 适量的马铃薯抗性淀粉添加到韧性饼干中可以改善饼干品质, 随着马铃薯抗性淀粉含量的增加, 饼干血糖指数降低。为抗性淀粉饼干的开发提供理论基础。     

Comparative Study on the Starch Noodle Structure of Sweet Potato and Mung Bean

ABSTRACT:  Fine structure of sweet potato starch (SPS) and mung bean starch (MBS) by gel-permeation chromatography (GPC) showed that the amylose in SPS and MBS had 9.0 and 1.8 chains, respectively. The long chains of amylopectin in MBS (A_p-MB) were longer than those of amylopectin in SPS (A_p-SP), but the short chains of A_p-SP were shorter than those of A_p-MB. The structures of starch noodles of sweet potato (SPSN) and mung bean (MBSN) were analyzed by GPC, scanning electron micrograph (SEM), differential scanning calorimetry (DSC), and X-ray diffraction after hydrolysis by acid and enzymes. The results showed that the residues obtained with acid and enzymes in MBSN contained large amounts of high molecular weight fractions, and a relatively small amount of low molecular weight fractions, whereas those in SPSN contained some high molecular weight fractions and large amounts of low molecular weight fractions. SPSN exhibited higher digestibility by HCl, α-amylase, β-amylase, and pullulanase than MBSN. The surface of MBSN was more smooth than that of SPSN and the inside of MBSN contained long, thick, and orderly filaments, while there were many pore spaces inside SPSN from SEM. The DSC thermogram of the resistant residues from both starch noodles after acid/enzyme hydrolysis showed a broad endotherm peak near 100 °C (96 to 115 °C) due to the presence of the complexes of amylose-lipid and lipid-(long chains in amylopectin). Because of a lower content of branched amylose and a higher content of amylopectin in SPS, the structure of SPSN had a less distinct crystalline pattern and higher adhesiveness, whereas there was a higher content of amylose with a little branch and moderate amylopectin in MBS. Thus, the structure of MBSN had a stronger distinct crystalline pattern and good cohesiveness.     

Preparation and properties of RS III from waxy maize starch with pullulanase

Waxy maize starch was treated by pullulanase debranching and retrogradation at room temperature to produce resistant starch (RS). Physicochemical properties, crystalline structure and in-vitro digestibility of starch samples with different RS content were investigated. Compared with native starch, apparent amylose content of RS products increased. Based on Gel Permeation Chromatography (GPC) the Molecular Weight Distribution (MWD) of resistant starches significantly changed. Scanning Electron Microscopy (SEM) showed that upon pullulanase debranching and retrogradation treatment the granular structure of native starch was destroyed and all RS samples exhibited irregular shaped fragments. Crystal structure of samples changed from A–type to a mixture of B and V–type. The crystallinity of resistant starch also improved as compared with native starch. Moreover, samples with higher resistant starch showed higher relative crystallinity. Differential Scanning Calorimetry (DSC) determination showed that To、Tp、Tc and ΔH all increased which was in agreement with RS content. The resistance of waxy maize starch with Pullulanase treatment to α-amylase digestibility also increased, while the in-vitro digestibility of products decreased.     

Digestibility of common native starches with reference to starch granule size,shape and surface features towards guidelines for starch-containing food products

Influence of diverse botanical sources (wheat, maize, waxy maize, cassava, potato, rice or waxy rice) on in vitro native starch digestibility has been investigated. Physicochemical properties (chemical composition, particles size and shape, surface features) of starch granules were determined with a view to explaining digestibility differences between samples. Rapidly digestible starch (RDS), slowly digestible starch (SDS) and resistant starch (RS) contents were measured according to Englyst method. Potato starch was shown to be composed of large rounded granules having smooth surfaces, which explains its slow enzymatic breakdown. Potato starch displayed the highest RS (86%) content and the lowest RDS content (9.9%). Since RS positively influences health and SDS may result in cell, tissue and/or organ damages, potato starch is an ideal starch nutrient. Conversely, waxy rice starch was rich in amylopectin and displayed small diameters and angular shapes, which are both known to facilitate enzymatic starch hydrolysis. It exhibited a near-zero RS content (0.9%) and a high RDS fraction (60%). According to this study, potato starch exhibited the best nutrient profile, followed up in this order by cassava, waxy maize, wheat, maize and waxy rice starches.     

Microstructural and physicochemical properties of heat-moisture treated waxy and normal starches

Starches from normal rice (21.72% amylose), waxy rice (1.64% amylose), normal corn (25.19% amylose), waxy corn (2.06% amylose), normal potato (28.97% amylose) and waxy potato (3.92% amylose) were heat-treated at 100 °C for 16 h at a moisture content of 25%. The effect of heat-moisture treatment (HMT) on morphology, structure, and physicochemical properties of those starches was investigated. The HMT did not change the size, shape, and surface characteristics of corn and potato starch granules, while surface change/partial gelatinization was found on the granules of rice starches. The X-ray diffraction pattern of normal and waxy potato starches was shifted from B- to C-type by HMT. The crystallinity of the starch samples, except waxy potato starch decreased on HMT. The viscosity profiles changed significantly with HMT. The treated starches, except the waxy potato starch, had higher pasting temperature and lower viscosity. The differences in viscosity values before and after HMT were more pronounced in normal starches than in waxy starches, whereas changes in the pasting temperature showed the reverse (waxy > normal). Shifts of the gelatinization temperature to higher values and gelatinization enthalpy to lower values as well as biphasic endotherms were found in treated starches. HMT increased enzyme digestibility of treated starches (except waxy corn starch); i.e., rapidly and slowly digestible starches increased, but resistant starch decreased. Although there was no absolute consistency on the data obtained from the three pairs of waxy and normal starches, in most cases the effects of HMT on normal starches were more pronounced than the corresponding waxy starches.     

甘薯交联抗性淀粉热力学性质与消化性研究

根据膨胀度、糊化度及差示扫描量热仪(DSC)测得热力学参数,综合分析甘薯交联抗性淀粉和原淀粉热力学性质,并采用Jenkins提出In–vitro模型测定淀粉体外消化性。结果表明:在同一温度下,甘薯交联抗性淀粉膨胀度和糊化度均较原淀粉低,且交联剂用量越高,淀粉膨胀度和糊化度越小;DSC测试结果显示,甘薯交联抗性淀粉相转变温度To、Tp、Tc随交联剂用量增加而升高,Tc–To和△H均比原淀粉低。In–vitro消化模拟实验表明,甘薯交联抗性淀粉消化性比原淀粉低,并随交联剂含量增加,消化产物量减少,消化速度降低。