从芒果腌制工业废料中提取的改性淀粉:物理改性与化学改性的比较

Gouthami Shivaswamy, S. Rudra, Anupama Singh, Rajesh Kumar, Debarup Das, Amit Kumar Goswami, Anamika Thakur
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引用次数: 0

摘要

本研究的重点是从生腌制芒果废料中提取、改性和表征芒果核淀粉(MKS)。改性采用了两种物理和两种化学技术:热湿处理(HMT)、超声波(US)、三偏磷酸钠(STMP)和辛烯基琥珀酸酐(OSA)。HMT 和 STMP 会因结构变化而降低膨胀力和溶解度,而 US 和 OSA 则会通过破坏分子间的键和削弱淀粉颗粒内的氢键来增强这些特性。傅立叶变换红外光谱(FTIR)显示,改性淀粉的吸收峰、强度和位置都发生了变化,证实了结构的成功改变。X 射线衍射图样显示了原生淀粉和改性淀粉的 A 型和 C 型图案,揭示了改性技术对结晶度的影响。与原生淀粉相比,改性淀粉的水结合能力(WBC)普遍提高。淀粉含量和糊化性能也发生了变化。改性淀粉具有更高的热稳定性。此外,淀粉的逆变性也会受到这些改性的影响,STMP 和 OSA 改性处理会减缓逆变性,而 HMT 和 US 处理则会促进逆变性。研究结果表明,原生淀粉和改性淀粉可作为多种工业原料。经化学改性的 MKS 结晶性优异,阻碍了逆变性,因此可用于食用涂层和烘焙食品。物理改性的 MKS 可加速逆降解,适用于挤压零食。
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Modified Starch from Mango Pickling Industry Waste: Comparison of Physical and Chemical Modification
This study focuses on extracting, modifying, and characterizing mango kernel starch (MKS) from raw pickling mango waste. Two physical and two chemical techniques: heat‐moisture treatment (HMT), ultrasound (US), sodium tri‐metaphosphate (STMP), and octenyl succinic anhydride (OSA) are employed for modification. HMT and STMP reduce swelling power and solubility due to structural changes, while US and OSA treatments enhance these properties by disrupting intermolecular bonds and weakening hydrogen bonds within the starch granules. Fourier transform infrared spectroscopy (FTIR) spectra demonstrate changes in absorption peaks, intensities, and positions in the modified starches, confirming successful structural alterations. X‐ray diffraction patterns indicate A‐type and C‐type patterns for native and modified starches, revealing alterations in crystallinity driven by modification techniques. Water binding capacity (WBC) generally increased in modified starches compared to native starch. Changes in amylose content and pasting properties are observed. Modified starches display higher thermal stability. Furthermore, starch retrogradation is affected by these modifications, with STMP and OSA modification treatments slowing it down, HMT and US treatments promoting it. Results demonstrate that native and modified MKS can be versatile ingredients for various industries. Chemically modified MKS excelled in crystallinity and hindered retrogradation, making it beneficial for edible coatings and baked goods. Physically modified MKS demonstrated accelerated retrogradation and suited for extruded snacks.
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