水蒸气吸附对直链淀粉-月桂酸混合粉中络合物形成的影响。

IF 1.2 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY
Yuki Yoshitomi, Kiyoshi Kawai
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引用次数: 0

摘要

本研究的目的是利用差示扫描量热法(DSC)和x射线衍射,了解相对湿度(RH)对直链淀粉-月桂酸混合粉末在50℃(略高于月桂酸的熔点)下直链淀粉-脂质复合物(ALC)形成的影响。从DSC曲线上可以观察到月桂酸结晶的熔化和ALC的两个熔化峰。x射线衍射图证实了ALC的形成。在RH为0%时,样品中月桂酸的熔化焓(∆Hm)低于月桂酸,但没有ALC生成。这表明直链淀粉阻止了月桂酸的结晶。月桂酸的∆Hm随着RH的增加而增加,最大可达79.0%,这是由于月桂酸与水合直链淀粉之间的斥力增强,使月桂酸发生融合。ALC的∆Hm随RH的增加而增加,在79.0 ~ 95.0%之间。对于ALC的形成,直链淀粉必须在系统中移动,但脱水的直链淀粉处于玻璃状(固定)状态。根据非晶态聚合物从玻璃到橡胶的转变行为,建议直链淀粉在50℃的温度下在相对湿度76.0%时变为橡胶(可移动)状态。这一解释解释了为什么在72.4 - 79.0%的相对湿度范围内开始观察到ALC的形成。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Effect of Water Vapor Sorption on Complex Formation in Amylose-lauric Acid Blend Powder.

Effect of Water Vapor Sorption on Complex Formation in Amylose-lauric Acid Blend Powder.

Effect of Water Vapor Sorption on Complex Formation in Amylose-lauric Acid Blend Powder.

Effect of Water Vapor Sorption on Complex Formation in Amylose-lauric Acid Blend Powder.

The purpose of this study was to understand the effect of relative humidity (RH) on amylose-lipid complex (ALC) formation in amylose-lauric acid blend powder held at 50 °C (temperature slightly higher than the melting point of lauric acid) using differential scanning calorimetry (DSC) and X-ray diffraction. From DSC curves, the melting of crystalized lauric acid and two melting peaks of ALC were observed depending on RH. ALC formation was confirmed by X-ray diffraction pattern. The melting enthalpy (∆Hm) of lauric acid in the sample held at RH 0 % was lower than that of lauric acid only though there was no ALC formation. This suggests that crystallization of lauric acid was prevented by amylose. The ∆Hm of lauric acid increased with an increase in RH up to 79.0 % because liquid lauric acid would have fused as the result of enhanced repulsive force between liquid lauric acid and hydrated amylose. The ∆Hm of ALC increased with an increase in RH between 79.0 and 95.0 %. For ALC formation, amylose has to be mobile in the system, but dehydrated amylose is in a glassy (immobilize) state. According to the glass to rubber transition behavior of amorphous polymer, amylose held at 50 °C is suggested to become rubbery (mobile) state at RH 76.0 %. This interpretation will explain the reason why ALC formation began to be observed at the RH range between 72.4 and 79.0 %.

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来源期刊
Journal of applied glycoscience
Journal of applied glycoscience BIOCHEMISTRY & MOLECULAR BIOLOGY-
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9.10%
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