Effects of heat‐moisture and alkali treatment on the enzymatic hydrolysis of porous sago (
            <i>Metroxylon sagu</i>
            ) starch

Ying, Boo Zhy; Kamilah, Hanisah; Karim, A.A.; Uthumporn, U.

doi:10.1111/jfpp.14419

Cited by 6 publications

(3 citation statements)

References 57 publications

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“…Meanwhile, the resistant starch contents were drastically lower for the cooked samples compared to the uncooked counterparts. No significant difference was observed between the As the sago starch has a gelatinisation temperature of around 79 °C, this process was possible during the preparation of cooked starch samples (Ying et al, 2020).…”

Section: Resultsmentioning

confidence: 87%

“…(a) Lactobacillus casei, (b) Bifidobacterium lactis and (c) Escherichia coli growth rates for uncooked and cooked resistant starch samples of microwave-treated sago starch cooked sample content of resistant starch. Cooking the starch destroyed the granule's structure by undergoing gelatinisation.As the sago starch has a gelatinisation temperature of around 79 °C, this process was possible during the preparation of cooked starch samples(Ying et al, 2020). The gelatinisation process caused the leaching of amylose and low molecular weight amylopectin chains(Li et al, 2020;Fan et al, 2019).…”

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confidence: 99%

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The Digestibility and Bacterial Growth Rates of Microwave Treated Sago (Metroxylon sagu) Starch

Zailani¹,

Kamilah²,

Husaini³

et al. 2023

JST

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Sago starch is rich in resistant starch (RS) but less utilised than other commercial starches. Hence, modification is essential to give an add-on value to the starch. Thus, the objective was to determine the influence of microwave heat treatment (MHT) on the digestibility and probiotic growth rates of sago starch. In this study, the starch was treated by MHT for durations of up to 20 min. The digestibility and bacterial growth rates increase as the treatment duration increases to 15 min. It implies the potential of the MHT in increasing the digestibility of the sago starch and improving its prebiotic property based on probiotic growth rates.

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Section: Resultsmentioning

confidence: 87%

mentioning

confidence: 99%

The Digestibility and Bacterial Growth Rates of Microwave Treated Sago (Metroxylon sagu) Starch

Zailani¹,

Kamilah²,

Husaini³

et al. 2023

JST

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“…Like other starches such as corn starch, modification of sago starch is essential to improve its properties and increase its usability. Various modification techniques, such as hydrolyzed-hydroxypropylation, octenyl succinic anhydride (OSA), alkaline, heat moisture, and gamma-irradiation treatments have been applied to sago starch (Abiddin et al, 2018;Oladzadabbasabadi et al, 2017;Othman et al, 2015;Ying et al, 2020). There are three main types of modification techniques, namely, physical, chemical, and enzymatic treatments.…”

Section: Introductionmentioning

confidence: 99%

Physicochemical properties of microwave heated sago (Metroxylon sagu) starch

Zailani

Kamilah

Husaini

et al. 2021

CyTA - Journal of Food

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Sago starch is an underutilized starch due to its low functionality in food formulation. Modification is effective in improving starch functional properties. In this study, the starch were modified to enhance its functional properties. The starch was microwave-heated with different treatment durations of 5, 10, 15, or 20 min, separately, yielding microwave-heated starches (MHT1, MHT2, MHT3, and MHT4). The modified starches have irregular shaped granules and fissures while maintaining their mean diameters. The degree of double helix had increased, indicating more double helix structure of amylose formed. The modified starches' moisture content, solubility, and paste clarity were significantly decreased. The MHT4 had its swelling power and syneresis increase. In conclusion, the treatment duration influenced the physicochemical properties of the sago starch, which is related to the formation of amylose double helix structure. Further study should focus on the formation of double helix structure in starch and its impact towards food structure. RESUMENEl almidón de sagú es infrautilizado debido asu baja funcionalidad para la formulación de alimentos. Su modificación puede resultar eficaz para mejorar sus propiedades funcionales. El presente estudio modificó el almidón para lograr este objetivo. Para ello, el almidón fue calentado por microondas, realizándose tratamientos de diferentes duraciones, 5, 10, 15 o20 minutos, por separado, lo que dio lugar aalmidones calentados por microondas (MHT1, MHT2, MHT3 yMHT4). Los almidones modificados de esta manera presentaron gránulos yfisuras de forma irregular, manteniendo sus diámetros medios. Se constató que aumentó el grado de doble hélice, lo que indica que se formó una estructura adicional de doble hélice de la amilosa. Por otra parte, el grado de humedad, la solubilidad yla claridad de la pasta de los almidones modificados disminuyeron significativamente. El MHT4 incrementó su poder de hinchamiento ysu sinéresis. En conclusión, se comprobó que la duración del tratamiento incidió en las propiedades fisicoquímicas del almidón de sagú relacionadas

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Physicochemical properties and the functional food potential of resistant sago (Metroxylon sagu) starch type IV produced by phosphorylation/acetylation treatment

Zaman

Kamilah

Seruji³

et al. 2022

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Effects of heat‐moisture and alkali treatment on the enzymatic hydrolysis of porous sago ( Metroxylon sagu ) starch

Cited by 6 publications

References 57 publications

The Digestibility and Bacterial Growth Rates of Microwave Treated Sago (Metroxylon sagu) Starch

The Digestibility and Bacterial Growth Rates of Microwave Treated Sago (Metroxylon sagu) Starch

Physicochemical properties of microwave heated sago (Metroxylon sagu) starch

Physicochemical properties and the functional food potential of resistant sago (Metroxylon sagu) starch type IV produced by phosphorylation/acetylation treatment

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