Please use this identifier to cite or link to this item: http://hdl.handle.net/11455/98029
標題: 冷電漿處理對玉米澱粉理化性質之探討
Evaluation of cold plasma technology on modifying the physicochemical properties of corn starch
作者: 張佑如
Yu-Ju Chang
關鍵字: 玉米澱粉;常壓噴射式電漿;冷電漿;澱粉修飾;澱粉特性;corn starch;atmospheric pressure plasma jet;cold plasma;starch modification;starch property
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摘要: 
在食品的加工應用上,天然澱粉常受限於熱處理、剪切力、pH值和低溫等條件,通常會藉由酵素性、化學性和物理性之修飾以克服天然澱粉的缺點。一般而言,化學性修飾方法具有高效率,但在食品安全性、化學藥劑成本、耗時及廢水管理等方面皆需多加考量。物理性的冷電漿技術由於不含化學劑、無毒以及環保等優點,在近年受到極大關注。
本研究旨在以常壓噴射式電漿修飾玉米澱粉,探討經不同強度的電漿處理(400、600和800W)以及五次水洗處理後,澱粉樣品的理化性質變化。經電漿處理與水洗處理後,玉米澱粉樣品的尖峰黏度、最終黏度與黏度回升值皆顯著下降,且隨著電漿強度提高而下降,又以800W處理組的黏度值最低;黏度裂解值則依據電漿強度不同而顯著增加或下降。pH值與相對結晶度的數值亦下降;直鏈澱粉含量與熱焓性質方面則無顯著改變;澱粉溶解度與澱粉糊透明度皆顯著增加。另外,電漿處理過程中會發生蝕刻作用,造成澱粉顆粒表面的非穿透性的物理性損傷。綜合以上結果,以常壓噴射式電漿修飾玉米澱粉後會改變其理化特性,顯示其在澱粉修飾方面具有潛力。

Native starch is limited by some conditions, such as heating, shear forces, pH and low temperature in food system. Therefore, native starch is subjected to physical, enzymatic and chemical modifications, in order to resolve its shortcomings. Chemical methods typically would result in high efficiency in starch modification, but the drawbacks are food safety concerns, high chemicals cost, time consuming, and troublesome waste water management. On the other hand, physical modification, which includes cold plasma technology, has drawn more attention in recent times due to its chemical-free, non-toxic, and environmental friendly properties.
The objectives of this study were to develop the modification methods for corn starch using atmospheric pressure plasma jet at different levels (400, 600 and 800W), followed by washing treatment for 5 times, and to evaluate the influences of plasma on corn starch physicochemical properties. After both plasma and washing treatments, peak viscosity, final viscosity and setback of corn starch samples decreased significantly with an increase in plasma intensity. The result showed that 800W treated corn starch sample had the lowest viscosity. Consequently, breakdown of corn starch sample would increase or decrease according to plasma treatment intensities. Besides that, the corn starch pH value and relative crystallinity decreased, but there were no apparent changes in its amylose contents as well as thermal properties, and the plasma treatments were also proven to be capable of increasing solubility and starch paste clarity. Furthermore, there were some non-penetrative and physical damages caused by plasma etching on the starch granules surfaces. The results indicated that the physical and chemical properties of corn starch could be modified by using atmospheric pressure plasma jet treatment.
URI: http://hdl.handle.net/11455/98029
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Appears in Collections:食品暨應用生物科技學系

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