The Effect of Ultrasound Pre-Treatment and Air-Drying on the Quality of Dried Apples

Opalić, Milan; Domitran, Zoran; Komes, Draženka; Belščak, Ana; Horžić, Dunja; Karlović, Damir

doi:10.17221/606-cjfs

Cited by 41 publications

(28 citation statements)

References 9 publications

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“…The impact of ultrasound intensity and time of pretreatment was ambiguous, but it seems that when the ultrasound intensity is higher the time of pretreatment should be longer, as well. Such indistinct results were also presented by Opalić et al [60] for air-dried apple tissue treated at 37 kHz for varied times (0-45 min). They obtained the highest content of phenolic compounds in apple tissue dried for the same time (720 min) after 22.5 min of ultrasound application, compared with 0 and 45 min.…”

Section: Downloaded By [Dokuz Eylul University ] At 07:30 02 Novembersupporting

confidence: 79%

Selected Emerging Technologies to Enhance the Drying Process: A Review

et al. 2014

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According to the U.S. Energy Information Association (EIA), world energy consumption will increase by 56% in 2040. Therefore, a lot of effort is being dedicated to maintaining economic development with minor impact on the environment. This can be done altering existing technologies or introducing completely new technologies. Due to the fact that drying can be considered one of the most energyconsuming processes, researchers have focused on ways to save energy while minimally changing the physicochemical properties of food, which shape its quality. Additionally, the increasing growth of consumer expectations and their nutritional knowledge have further stimulated efforts to seek new solutions. Non-thermal technologies such as pulsed electric field (PEF), ultrasound (US), and high hydrostatic pressure (HHP) seem to meet the expectations of both producers and consumers. This article reviews the impact of PEF, US, and HHP on drying kinetics and the quality attributes of dried food. INTRODUCTIONThe increase in food prices and the huge energy expenditures on foodstuff drying are the main reasons for the growing interest in drying process intensification. Conventional dewatering methods are progressively complemented by novel techniques which could give a high-quality product at lower production costs. Among the currently proposed solutions, non-thermal techniques such as ultrasound (US), pulsed electric field (PEF), and high hydrostatic pressures (HHP) are extremely noteworthy for drying of heat-sensitive foods since their application is not connected with a high increase in material temperature. In addition to dehydration, [1][2][3][4][5][6] several examples of the use of these technologies in food processing can be found in the scientific literature. In general, the possible applications of non-thermal technologies ( Fig. 1) are connected with food preservation [7][8][9][10][11] or enhancement of heat and=or mass-based processes. [12][13][14][15][16][17]

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Section: Downloaded By [Dokuz Eylul University ] At 07:30 02 Novembersupporting

confidence: 79%

Selected Emerging Technologies to Enhance the Drying Process: A Review

et al. 2014

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“…Interestingly, when parsley was dried with higher microwave power, the type of pre-drying processing did not alter the chlorophyll's quantity significantly, with the exception of blanched and untreated leaves at 30°C. Beneficial effect of the US treatment on the biological components and their activity was also observed in the case of polyphenols in apple [22], antioxidant activity in thyme [25], chlorophyll a and b [31] and polyphenols contents in parsley leaves [29]. However, the character of influence on the chemical composition was always linked to the drying conditions and in some dried material a significant decomposition of the molecules was observed.…”

Section: Chlorophyll Contentmentioning

confidence: 99%

The impact of ultrasound and steam blanching pre-treatments on the drying kinetics, energy consumption and selected properties of parsley leaves

et al. 2016

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“…During tissue sonication, ultrasound affects the matrix structure by formation of microscopic channels that favor both mass transfer intensification during osmotic treatment, and higher water diffusivity during subsequent air-drying (Nowacka et al 2014). From a technological point of view, the ultrasound seemed to be very promising, but unfortunately, in some cases, especially when a liquid medium during sonication was applied, substantial losses of bioactive compounds were reported (Stojanovic and Silva 2007;Opalić et al 2009;Pingret et al 2013). Although the available literature presents many experiments with ultrasound application before and during fruit and vegetable dehydration process (Siucińska and Konopacka 2014), the majority of them focus on monitoring the dynamics of mass transfer or physical properties, such as sugar gain, water loss, or changes in color or microstructure of plant tissue (Cárcel et al 2007;Deng and Zhao 2008;Garcia-Perez et al 2012;Nowacka et al 2012;Schössler et al 2012).…”

Section: Introductionmentioning

confidence: 99%

“…Although the available literature presents many experiments with ultrasound application before and during fruit and vegetable dehydration process (Siucińska and Konopacka 2014), the majority of them focus on monitoring the dynamics of mass transfer or physical properties, such as sugar gain, water loss, or changes in color or microstructure of plant tissue (Cárcel et al 2007;Deng and Zhao 2008;Garcia-Perez et al 2012;Nowacka et al 2012;Schössler et al 2012). With regard to phenolic compound retention during ultrasound-assisted fruit tissue treatment, the reports on negative effect of sonication on phenolic compound content and antioxidant activity (Stojanovic and Silva 2007;Opalić et al 2009), more often than not, indicate a positive influence (Keenan et al 2012). However, in both cases, the data is based on the total phenolic content measurements.…”

Section: Introductionmentioning

confidence: 99%

Effects of Ultrasound on Polyphenol Retention in Apples After the Application of Predrying Treatments in Liquid Medium

Mieszczakowska-Frąc

Dyki

Konopacka

2015

Food Bioprocess Technol

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The effect of sonication time and kind of liquid medium on polyphenol retention and microstructure changes during predrying treatment of apple tissue was investigated. The apple cubes from 'Idared' cultivar were submerged in water or sucrose solution and sonicated indirectly in beakers placed in a water bath fitted with ultrasound transducers (25 kHz, 0.1 W/cm 3 ) at 40°C. The treatment was conducted with and without ultrasound applied for 45 and 90 min. The content of individual polyphenols was monitored by a reversephase high-performance liquid chromatography (RP-HPLC) method. The dominant phenolic compounds in apple were procyanidins, accounting for 56 % of total polyphenols. While a significant effect of sonication on mass transfer intensification was observed when the samples were dehydrated in sucrose solution, almost no negative effects of ultrasound application were perceived on polyphenols concentration, except for dimers of catechin. When using ultrasound in water solution, an increase in polyphenol compound losses was noted. Furthermore, the ultrasound energy caused an apple tissue structure modification which additionally affected polyphenol retention during predrying treatment.

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The Effect of Ultrasound Pre-Treatment and Air-Drying on the Quality of Dried Apples

Cited by 41 publications

References 9 publications

Selected Emerging Technologies to Enhance the Drying Process: A Review

Selected Emerging Technologies to Enhance the Drying Process: A Review

The impact of ultrasound and steam blanching pre-treatments on the drying kinetics, energy consumption and selected properties of parsley leaves

Effects of Ultrasound on Polyphenol Retention in Apples After the Application of Predrying Treatments in Liquid Medium

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