Microstructural, dehydration and rehydration properties of rice starch granules in noodles as affected by water and oil addition using vacuum impregnation

Leakhena, On; Thong-gnam, Mas-u-bon; Jhoo, Jin‐Woo; Boonsupthip, Waraporn

doi:10.1111/jfpe.13763

Cited by 4 publications

(2 citation statements)

References 41 publications

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“…Leakhena et al. (2021) reported that pregelatinized starch tended to swell more rapidly at higher water temperatures, such as during boiling. Among the different treatment durations in this experiment, the 10‐min MS treatment resulted in the best rehydration performance.…”

Section: Resultsmentioning

confidence: 99%

Mild steam treatment: Enhancing the rehydration performance of instant rice noodles by changing the physicochemical properties and gel structure of rice starch

Yue,

Zhang,

Zhang

et al. 2024

Journal of Food Science

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The “instant” quality of instant rice noodles is significantly affected by slow rehydration during cooking. This happens as a result of the native rice starch's low ability to gelatinize as well as the high shear and pressure utilized in industries during the widely used extrusion molding process. In order to address this issue, the rice flour was pretreated with mild steam (MS) technology. The results revealed that the rehydration qualities of the rice noodles that were extruded from the steam‐treated flour significantly improved. There was a reduction of 25.5% in the rehydration time, from 443 to 330 s. The MS‐treated rice starch's peak viscosity increased to 4503 from 4044 mPa/s. Decreases in gelatinization enthalpy (ΔH) and short‐range ordering also suggest a reduction in difficulty in accomplishing starch gelatinization. Scanning electron microscopy studies showed particle aggregation increased as the treatment duration lasted longer. In conclusion, our findings indicate that we successfully addressed the issue of slow rehydration in instant rice noodles while presenting a novel approach for their manufacturing in the manufacturing sector.

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Section: Resultsmentioning

confidence: 99%

Mild steam treatment: Enhancing the rehydration performance of instant rice noodles by changing the physicochemical properties and gel structure of rice starch

Yue,

Zhang,

Zhang

et al. 2024

Journal of Food Science

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“…In general, rice crushing rate is determined by the physico‐mechanical properties of rice grains, which depend on their microstructures, moisture contents, and so on (Bhushan & Raigar, 2020; Leakhena et al, 2021). Yang, Fan, et al (2022) have investigated the mechanical properties of hulling rice and compared different forms of paddy grain breakage under pressure and shear.…”

Section: Introductionmentioning

confidence: 99%

Moisture content‐dependent mechanical behaviors of rice by experiments and composite models in finite element simulation

Dong,

Zhang,

Tao

et al. 2024

J Food Process Engineering

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To reduce the crushing rate and improve the yield of rice during the milling process, it is significant from a fundamental standpoint to understand the mechanical behaviors of rice under external loads. In this paper, the mechanical properties and fracture morphologies of rice with various moisture contents have been analyzed in detail by experiments and the finite‐element (FE) method. In FE simulations, two‐dimensional (2D) and three‐dimensional (3D) composite models have been established with the cohesive zone model characterizing the interface strength. The results show that the moisture content determines the endosperm cell wall interface strength, and a linear relationship between the interface strength and moisture content has been obtained. In particular, three fracture patterns of brown rice are observed by the competition between the interface strength of starch granule and endosperm cell wall interface strength. Good agreements between FE predictions and experimental results indicate that the combination of the 2D and 3D composite models with the cohesive zone model can provide accurate predictions of the fracture behaviors of brown rice. This investigation should be of great help for understanding the moisture content‐dependent compression and impact behaviors of rice.Practical applicationsBrown rice can be obtained by removing the husk through a hulling machine. During these processes, external loads, such as compression and impact, will damage the microstructure of brown rice, which results in a loss rate as high as 25%. Understanding the mechanical properties of brown rice with different moisture contents will be of great help in designing the equipment used in rice processing operations and extending the yield of polished rice.

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Acceleration mechanism of the rehydration process of dried rice noodles by the porous structure

Zhang,

Zhao,

et al. 2024

Food Chemistry

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Microstructural, dehydration and rehydration properties of rice starch granules in noodles as affected by water and oil addition using vacuum impregnation

Cited by 4 publications

References 41 publications

Mild steam treatment: Enhancing the rehydration performance of instant rice noodles by changing the physicochemical properties and gel structure of rice starch

Mild steam treatment: Enhancing the rehydration performance of instant rice noodles by changing the physicochemical properties and gel structure of rice starch

Moisture content‐dependent mechanical behaviors of rice by experiments and composite models in finite element simulation

Acceleration mechanism of the rehydration process of dried rice noodles by the porous structure

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