The combined effect of ultrasonication and hydration temperature on water absorption of barley: Analysis, modeling, kinetics, optimization, and thermodynamic parameters of the process

Shafaei, S.M.; Nourmohamadi-Moghadami, A.; Kamgar, S.

doi:10.1111/jfpp.13905

Cited by 14 publications

(16 citation statements)

References 63 publications

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“…It increases the diffusion process and results in higher moisture content in the millet grains [18] . Though the moisture content of the optimized ultrasound hydrated finger millet was close to that of conventionally hydrated samples, ultrasound treatment alone is not sufficient to achieve maximum hydration [7] . Significant differences ( P < 0.05 ) were observed for the various quality characteristics of optimized ultrasound hydrated and conventionally hydrated finger millets.…”

Section: Resultsmentioning

confidence: 87%

“…Ultrasound exposure at higher amplitude for extended time disrupts and dislodge the cells creating microcavities and results in higher mass transfer by diffusion. This helps in improving hydration [6] , [7] , [15] , [16] , [17] . The higher values of R 2 (0.96), adj.…”

Section: Resultsmentioning

confidence: 99%

“…The moisture content of the samples was determined following the standard oven-dry method [7] . The samples were dried in a hot air oven at 105 °C for 24 h. The pre and post drying weights of the samples were used to calculate the moisture content.…”

Section: Methodsmentioning

confidence: 99%

See 2 more Smart Citations

Ultrasound-assisted hydration of finger millet (Eleusine Coracana) and its effects on starch isolates and antinutrients

Yadav

Mishra

Pradhan

2021

Ultrasonics Sonochemistry

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Highlights Ultrasound-assisted hydration process was developed and optimized for finger millet. Hydration was optimum at 65.73% amplitude, 26.13 min treatment and 1:3 grain-water ratio. Phytate and tannin (antinutrients) were reduced by 66.98 and 62.83%, respectively. Morphology, water binding capacity, and solubility of the isolated starch improved. The ultrasound-assisted hydration is a better alternative for finger millet.

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Section: Resultsmentioning

confidence: 87%

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Ultrasound-assisted hydration of finger millet (Eleusine Coracana) and its effects on starch isolates and antinutrients

Yadav

Mishra

Pradhan

2021

Ultrasonics Sonochemistry

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“…The ultrasound technology has shown good results enhancing different mass transfer processes, especially the grain hydration process. For instance, this technology accelerated the hydration of chick peas (Yildirim, Öner, & Bayram, ), common beans (Ulloa et al, ), sorghum kernels (Patero & Augusto, ), navy beans (Ghafoor, Misra, Mahadevan, & Tiwari, ), white kidney beans (Miano, Sabadoti, & Augusto, ), barley kernels (Shafaei, Nourmohamadi‐Moghadami, & Kamgar, ), among others. Ultrasound consists of using acoustic waves with frequencies between 20 and 500 kHz and power higher than 1 W/cm 2 , which by both direct and indirect effects causes physical–chemical and structural changes on food (Awad, Moharram, Shaltout, Asker, & Youssef, ).…”

Section: Introductionmentioning

confidence: 99%

Using ultrasound for improving hydration and debittering of Andean lupin grains

Miano

Rojas

Augusto

2019

J Food Process Engineering

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This article presents results about the potential use of ultrasound technology on the hydration and debittering process of Andean lupin grains (Lupinus albus Sweet). The hydration process was conducted conventionally and also assisted by ultrasound technology (ultrasonic water bath, 25 kHz, 41 W/L). Further than the hydration kinetics, the alkaloid content was evaluated. As results, the hydration kinetics of this grain showed a sigmoidal behavior, which was accelerated almost 40% using ultrasound. The lag phase was reduced about 13%, and the equilibrium moisture content was increased about 14%. Finally, by using ultrasound during hydration process, the alkaloid extraction was also improved, extracting 21% more compared to the conventional process. It was concluded that ultrasound technology accelerates not only the hydration process but also the extraction of alkaloids. Practical Applications Andean lupin is a pulse with potential importance for human and animal alimentation due to its high quantity of proteins. However, this pulse has a considerable quantity of undesirable alkaloids that are bitter and toxic. Therefore, a debittering process is required. Further, before debittering, hydration of the grains is required, which is a long and batch process. This work demonstrated that both the hydration and the debittering processes can be enhanced by ultrasound. Consequently, ultrasound technology would have a double application during hydration process of Andean lupin grains.

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“…In recent years, another strategy (ultrasonication) has been employed to proliferate water absorption of agricultural food products. Literature screening process confirmed that ultrasonication strategy was successfully utilized for soaking process of rice (Li et al, 2019; Wambura, Yang, & Wang, 2008), chickpea (Yildirim, Bayram, & Oner, 2012; Yildirim & Oner, 2015; Yildirim, Oner, & Bayram, 2010; Yildirim, Oner, & Bayram, 2011; Yildirim, Oner, & Bayram, 2013), bean (Ghafoor, Misra, Mahadevan, & Tiwari, 2014; Lopez et al, 2017; Miano & Augusto, 2018a; Miano, Pereira, et al, 2016; Miano, Rojas, & Augusto, 2019a; Miano, Sabadoti, & Augusto, 2018; Miano, Sabadoti, & Augusto, 2019; Ulloa et al, 2015), sorghum (Miano, Ibarz, et al, 2016; Patero & Augusto, 2015), melon (Miano, Ibarz, et al, 2016), sea cucumber (Zhang et al, 2016a, 2016b), carrot (Ricce, Rojas, Miano, Siche, & Augusto, 2016), corn (Miano, Ibarz, & Augusto, 2017), wheat (Guimaraes, Polachini, Augusto, & Telis‐Romero, 2020; Shafaei, Nourmohamadi‐Moghadami, & Kamgar, 2018; Shafaei, Nourmohamadi‐Moghadami, Rahmanian‐Koushkaki, & Kamgar, 2019), potato (Miano, Rojas, & Augusto, 2019b), barley (Borsato, Jorge, Mathias, & Jorge, 2019; Carvalho, Polachini, Darros‐Barbosa, Bon, & Telis‐Romero, 2018; Shafaei, Nourmohamadi‐Moghadami, & Kamgar, 2019), pumpkin (Rojas, Silveira, & Augusto, 2020), sesame (Shafaei, Nourmohamadi‐Moghadami, et al, 2021), and paddy (Kalita, Jain, Srivastava, & Goud, 2021). In these works, modeling of ultrasonication‐assisted soaking process of the products was commonly fulfilled with respect to soaking time using above‐mentioned nonlinear models for certain soaking temperatures and, constants and coefficients of the models varied with variations in soaking temperature.…”

Section: Introductionmentioning

confidence: 99%

Manifestation of neuro‐fuzzy simulation environment for prognostication of water absorption kinetics of soybean grains in thermo‐ultrasonication‐assisted soaking process

Shafaei

Nourmohamadi-Moghadami

Kamgar

2021

J Food Process Engineering

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Neuro‐fuzzy simulation of food engineering phenomena can be a supportive manner for integrated realization of compound trends of involved parameters. This article is aimed to manifest neuro‐fuzzy simulation environment for prognostication of water absorption kinetics of soybean grains in thermo‐ultrasonication‐assisted soaking process. The simulation environment was developed based on various types and numbers of input membership functions, defuzzification methods, types of output membership functions, and numbers of training cycles. Promising performance of the prominent environment guaranteed its reliability for prognostication of water absorption kinetics on the basis of numeral variables of soaking time and temperature (20, 30, 40, 50 and 60°C), and nominal variable of soaking strategy (thermic and ultrasonication [25 kHz and 360 W]). The simulation results divulged that applying both strategies of thermic and ultrasonication (thermo‐ultrasonication strategy) was more effective than individual strategy of thermic and ultrasonication in order to proliferate water absorption into the grains. However, contributory influence of the ultrasonication on water absorption was less apparent at higher soaking temperatures and it was more dominant, when soaking time augmented. Practical Applications It can be asserted that the neuro‐fuzzy simulation environment manifested and verified in this study can be practically utilized in oil extraction and seed priming process, and industrial production of some popular soybean food products (Soymilk, Okara, Tofu, Shoyu, Miso, and Natto).

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The combined effect of ultrasonication and hydration temperature on water absorption of barley: Analysis, modeling, kinetics, optimization, and thermodynamic parameters of the process

Cited by 14 publications

References 63 publications

Ultrasound-assisted hydration of finger millet (Eleusine Coracana) and its effects on starch isolates and antinutrients

Ultrasound-assisted hydration of finger millet (Eleusine Coracana) and its effects on starch isolates and antinutrients

Using ultrasound for improving hydration and debittering of Andean lupin grains

Manifestation of neuro‐fuzzy simulation environment for prognostication of water absorption kinetics of soybean grains in thermo‐ultrasonication‐assisted soaking process

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