Effect of Osmotic Dehydration on Air-Drying Characteristics of Chayote

Ruiz-López, I.I.; Huerta-Mora, Ibis R.; Vivar-Vera, M. A.; Martínez‐Sánchez, Cecilia E.; Herman‐Lara, Erasmo

doi:10.1080/07373937.2010.482716

Cited by 37 publications

(16 citation statements)

References 22 publications

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“…Moreover, since osmotic dehydration can lower the water content of fruits and vegetables up to a 50 %, the energy requirements for subsequent thermal drying can be considerably reduced [79]. However, periods of 1-7 h were required to achieve efficient osmotic dehydration, which are substantially larger operating times when compared with traditional water or steam blanching, that can be performed in a few minutes.…”

Section: Osmotic Dehydrationmentioning

confidence: 97%

Influence of Drying Processes and Pretreatments on Nutritional and Bioactive Characteristics of Dried Vegetables: A Review

2015

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Drying has been applied to vegetables in order to preserve, store and transport these food products. However, drying implies not only physical changes, easily detectable by the consumer through visual assessment, but also chemical modifications. These are not always visible, but are responsible for alterations in colour, flavour and nutritional value, which compromise the overall quality of the final product. The main chemical changes associated with drying are related to the degradation of phytochemicals, such as vitamins, antioxidants, minerals, pigments and other bioactive compounds sensitive to heat, light and oxygen. Moreover, nutrient losses are inevitably associated with leaching as a result of the water removal from the vegetable during the drying process. In order to prevent or reduce nutrient losses and thus improve the quality of dried products, pretreatments are often applied. In this review, an overview of the procedures developed for dehydration of vegetables applying heat by convection, conduction or radiation is presented. The influence of pretreatments on nutritional and bioactive characteristics of dried vegetables is discussed. Blanching with steam, water or chemical solutions is the most commonly used, but power ultrasound, ohmic blanching, osmotic and edible coatings pretreatments have also been reported. The influence of the drying processes and conditions on nutritional contents and bioactive characteristics is also presented.

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Section: Osmotic Dehydrationmentioning

confidence: 97%

Influence of Drying Processes and Pretreatments on Nutritional and Bioactive Characteristics of Dried Vegetables: A Review

2015

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“…This operation has gained a broad acceptance in fruits and vegetable processing as it improves quality characteristics such as color, texture and flavor in the final product (Bidaisee and Badrie, 2001;Pereira et al, 2006). Moreover, since OD is able to produce a significant dewatering of foods, energy requirements for a further thermal drying can be considerably reduced (Ruiz-López et al, 2010). A good understanding of mass transfer rates for both solute gain and water loss as well as the final impregnation-dehydration levels of a given product under different OD conditions (such as osmotic agent concentration, process temperature and solute type) is required for an adequate design of this operation (Shi and Le Maguer, 2002).…”

Section: Introductionmentioning

confidence: 98%

“…A feasible way of increasing shelf life of carambola is through the development of reduced moisture products. However, even though air drying is the most widely used technique for dehydrated fruit and vegetable production, it may be detrimental, affecting both nutritional and sensory quality of heat-sensitive products (Ruiz-López et al, 2010). Moreover, available information on dehydration processes of carambola is limited.…”

Section: Introductionmentioning

confidence: 99%

Modeling of kinetics, equilibrium and distribution data of osmotically dehydrated carambola (Averrhoa carambola L.) in sugar solutions

Ruiz-López

Ruíz-Espinosa

Herman‐Lara

et al. 2011

Journal of Food Engineering

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“…Moreover, because osmotic dehydration is able to produce a significant dewatering of foods, energy requirements for a further thermal drying can be considerably reduced (Ruiz‐Lopez et al . ).…”

Section: Introductionmentioning

confidence: 97%

“…Osmotic dehydration has gained a broad acceptance in fruits and vegetable processing as it improves quality characteristics, such as color, texture and flavor, in the final product (Pereira et al 2006). Moreover, because osmotic dehydration is able to produce a significant dewatering of foods, energy requirements for a further thermal drying can be considerably reduced (Ruiz-Lopez et al 2010).…”

Section: Introductionmentioning

confidence: 99%

Study on Equilibrium Distribution Coefficients during Osmotic Dehydration of White Gourd Slices

Fan

Chen

et al. 2014

Journal of Food Processing and Preservation

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Equilibrium distribution coefficients were obtained to understand osmotic dehydration mechanism and to optimize and control osmotic dehydration process. The equilibrium distribution coefficients of white gourd slices were determined during osmotic dehydration at different temperatures (30–50C) and maltose syrup concentrations (40–60%, w/w). Equilibrium distribution coefficients as a function of temperature and maltose syrup concentration were modeled using nine nonlinear models. The results showed that the equilibrium distribution coefficients of water and solids ranged from 0.3411 to 0.8406 g/g and from 1.2392 to 1.5754 g/g, respectively. The best models for the equilibrium distribution coefficients of water and solids are, respectively, λse = −0.8345 + 0.0281T + 6.5665C − 0.0627CT + 0.0001T2 − 4.9081C2 + 0.0004T2C2 [R2 = 0.9899, sum of squared error (SSE) = 2.0511 × 10−4, root mean square error (RMSE) = 0.0143, χ2 = 9.2299 × 10−4, P = 2.10%], λse = −0.8345 + 0.0281T + 6.5665C − 0.0627CT + 0.0001T2 − 4.9081C2 + 0.0004T2C2 (R2 = 0.9734, SSE = 3.0827 × 10−4, RMSE = 0.0176, χ2 = 0.0014, P = 1.09%). Practical Applications Osmotic dehydration of white gourd slices in maltose syrup solution was investigated experimentally in different solution concentrations and at different temperatures. The equilibrium distribution coefficients of water and solids were calculated during osmotic dehydration of white gourd in maltose syrup solution. The equilibrium distribution coefficients of water and solids for white gourd slices as a function of maltose syrup concentration and temperature were investigated.

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Effect of Osmotic Dehydration on Air-Drying Characteristics of Chayote

Cited by 37 publications

References 22 publications

Influence of Drying Processes and Pretreatments on Nutritional and Bioactive Characteristics of Dried Vegetables: A Review

Influence of Drying Processes and Pretreatments on Nutritional and Bioactive Characteristics of Dried Vegetables: A Review

Modeling of kinetics, equilibrium and distribution data of osmotically dehydrated carambola (Averrhoa carambola L.) in sugar solutions

Study on Equilibrium Distribution Coefficients during Osmotic Dehydration of White Gourd Slices

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