Ethanol pretreatment in taioba leaves during vacuum drying

Junqueira, João Renato de Jesus; Corrêa, Jefferson Luiz Gomes; Resende, Nathane Silva; Balbinoti, Thaisa Carvalho Volpi; Gatti, Isabella Pereira; Mendonça, Kamilla Soares de

doi:10.1590/1413-7054202145020421

ABSTRACT

Non-conventional vegetables are those with limited distribution, restricted to certain regions. As a globalization and food industrialization result, its cultivation and consumption has decreased. The taioba [Xanthosoma sagittifolium (L.) Schott] is an example of this vegetable category. The drying process increases the food stability, but it can negatively alter the nutritional value and the final quality of the product. Ethanol pretreatment reduces the drying time and can assist in the preservation of the nutritional characteristics. The aim of this work was to evaluate the effect of vacuum drying and ethanol pretreatment on the drying behavior, mathematical modeling, and final quality of taioba leaves. Higher temperatures and ethanol pretreatment lead to a shorter drying time. Thin-layer equations were evaluated for their ability to predict the drying kinetics, of which the Logarithmic and Midilli & Kuçuk equations performed best. A significant difference (p ≤ 0.05) was observed in the ascorbic acid content, antioxidant activity and total phenolic compounds in the different treatments. There was preservation in ascorbic acid content in treatments in which ethanol was applied; moreover, lower total phenolic compounds and antioxidant activity were observed when ethanol was used. There was no significant difference (p > 0.05) in pH values and titratable acidity.

Index terms:
Food dehydration; non-conventional vegetables; Xanthosoma sagittifolium (L.) Schott.

RESUMO

Vegetais não convencionais são aqueles que apresentam distribuição limitada, restrita a determinadas regiões. Como resultado da globalização e da industrialização de alimentos, seu cultivo e consumo foram reduzidos. A taioba [Xanthosoma sagittifolium (L.) Schott] é um exemplo desta categoria de vegetais. O processo de secagem aumenta a estabilidade do alimento, mas pode alterar negativamente o valor nutricional e a qualidade final do produto. O pré-tratamento com etanol reduz o tempo de secagem e pode auxiliar na preservação das características nutricionais. O objetivo deste trabalho foi avaliar o efeito da secagem a vácuo e do pré-tratamento com etanol na cinética de secagem, modelagem matemática e qualidade final de folhas de taioba. Maior temperatura e uso de etanol proporcionaram menor tempo de secagem. Equações empíricas foram empregadas para avaliação do comportamento da secagem, das quais as equações Logarítmica e Midilli & Kuçuk apresentaram melhores desempenhos. Foi observada diferença significativa (p ≤ 0,05) no teor de ácido ascórbico, atividade antioxidante e compostos fenólicos totais nos diferentes tratamentos. Houve preservação do teor de ácido ascórbico nos tratamentos em que o etanol foi aplicado. Menores teores de compostos fenólicos totais e atividade antioxidante foram observados quando o etanol foi empregado. Não houve diferença significativa (p > 0,05) nos valores de pH e acidez titulável.

Termos para indexação:
Desidratação de alimentos; vegetais não convencionais; Xanthosoma sagittifolium (L.) Schott.

INTRODUCTION

Due to biodiversity wealth, many plant species are underexploited, but these products can be used as an alternative nutrient source, complementing feeding and assisting populations with their subsistence. Non-conventional vegetables present limited distribution, restricted to locations close to their production. These vegetables are not organized in a productive chain, instead conventional vegetables (such as lettuce, potatoes, and tomatoes), and present reduced commercial interest (Almeida et al., 2014ALMEIDA, M. E. F. et al. Caracterização química das hortaliças não-convencionais conhecidas como ora-pro-nobis. Bioscience Journal, 30(3):431-439, 2014.; Ziegler et al., 2020ZIEGLER, V. et al. Nutritional enrichment of beef burgers by adding components of non-conventional food plants. Brazilian Journal of Food Technology, 23:e2019030, 2020.).

The taioba [Xanthosoma sagittifolium (L.) Schott] is an example of a non-conventional vegetable which presents edible leaves and tubers and is widely distributed in regions of South America, Africa, and Asia. The taioba leaves present potential nutritional and functional benefits, but they are underutilized (Jackix et al., 2013JACKIX, E. A. et al. Cholesterol reducing and bile-acid binding properties of taioba (Xanthosoma sagittifolium) leaf in rats fed a high-fat diet. Food Research International, 51(2):886-891, 2013.; Ukom; Nwanagba; Okereke, 2020UKOM, A.; NWANAGBA, N.; OKEREKE, D. Effect of drying methods on the chemical composition and anti- nutritional properties of a cocoyam (Xanthosoma Maffafa Schott) tuber flour and leaf powder. EAS Journal of Nutrition and Food Sciences, 1873(4):197-203, 2020.). Oliveira et al. (2013OLIVEIRA, D. D. C. D. S. et al. Composição mineral e teor de ácido ascórbico nas folhas de quatro espécies olerícolas não-convencionais. Horticultura Brasileira, 31(3):472-475, 2013.) found higher levels of potassium, phosphorus, calcium and magnesium in taioba leaves, compared with conventional vegetables (chicory, cabbage and watercress).

Drying techniques are widely employed as a food preservation method. The convective drying is the most used for industrial purposes, but this process presents some drawbacks, including low energy efficiency, long heat exposure, and changes in structural, nutritional, functional and sensorial product characteristics. Edible leaves are considered heat-sensitive materials and must be dried in the vacuum drying system - VD at low temperatures (< 50 ºC), for a reduction in drying time process, oxygen suppression and properties maintenance (Babu et al., 2018BABU, A. K. et al. Review of leaf drying: Mechanism and influencing parameters, drying methods, nutrient preservation, and mathematical models. Renewable and Sustainable Energy Reviews, 90(3):536-556, 2018.; Oliveira et al., 2021OLIVEIRA, L. F. et al. Drying of ‘yacon’ pretreated by pulsed vacuum osmotic dehydration. Brazilian Journal of Agricultural and Environmental Engineering, 25(8):560-565, 2021.; Szadzińska et al., 2018SZADZIŃSKA, J. et al. Microwave- and ultrasound-assisted convective drying of raspberries: Drying kinetics and microstructural changes. Drying Technology , 37(1):1-12, 2018.).

Comparing different drying methods (shade drying, freeze drying, oven drying and vacuum drying), Ebadi et al. (2015EBADI, M. T. et al. Influence of different drying methods on drying period, essential oil content and composition of Lippia citriodora Kunth. Journal of Applied Research on Medicinal and Aromatic Plants, 2(4):182-187, 2015.) concluded that VD at 60 ºC could be considered an alternative approach for lemon verbena (Lippia citriodora Kunth) drying. The VD of coriander leaves (Coriandrum sativum L.) was studied by Thirugnanasambandham and Sivakumar (2016THIRUGNANASAMBANDHAM, K.; SIVAKUMAR, V. Enhancement of shelf life of Coriandrum sativum leaves using vacuum drying process: Modeling and optimization. Journal of the Saudi Society of Agricultural Sciences , 15(2):195-201, 2016.). Those authors evaluated the effects of vacuum, loading rate and temperature and concluded that the VD was an effective method to achieve desired final moisture content.

The ethanol pretreatment is related to a reduction in drying process time (Souza et al., 2018SOUZA, A. U. et al. The influence of ethanol and vacuum on okara drying. Journal of Food Chemistry & Nanotechnology, 4(4):271-286, 2018.), diffusivity increase (Corrêa et al., 2012CORRÊA, J. L. G. et al. The influence of ethanol on the convective drying of unripe, ripe, and overripe bananas. Drying Technology , 30(8):817-826, 2012.), and the maintenance of nutritional and sensory characteristics (Araújo et al., 2020ARAÚJO, C. S. et al. Influence of pretreatment with ethanol and drying temperature on physicochemical and antioxidant properties of white and red pulp pitayas dried in foam mat. Drying Technology, 1-10, 2020.).

The aims of this work were to (i) investigate the effect of VD and ethanol pretreatment (at different temperatures) on the drying behavior of a non-conventional vegetable: taioba; (ii) evaluate the suitability of diffusional and empirical equations for predicting the process; and (iii) to examine the final quality of the dried leaves (ascorbic acid retention, total phenolic content, antioxidant capacity, pH and titratable acid).

MATERIAL AND METHODS

Sample preparation

Edible taioba leaves [Xanthosoma sagittifolium (L.) Schott] were obtained from a local producer (Lavras, Brazil, 21º 14’ 45’’ S; 44º 59’ 59’’ E). The selected leaves present similar visual aspects (size, shape, color) and absence of physical injuries. Prior to the drying experiments, the leaves were stored at 4 ± 1 ºC. The samples were characterized with respect to the initial moisture content (Association of Official Agricultural Chemists - AOAC, 2016ASSOCIATION OF OFFICIAL AGRICULTURAL CHEMISTS - AOAC. Official Methods of Analysis of AOAC International. 20th Ed, Rockville, Maryland, USA, 2016. 3172p.) and water activity (a_w) (Aqualab, 3-TE model, Decagon Devices Inc., Pullman, WA, USA). The initial moisture content was 5.711 ± 0.103 kg water/kg dry basis (d.b.) and the a_w was 0.984 ± 0.002, demonstrating its perishability.

The leaves were washed in tap water, gently dried with absorbent paper, and sliced in slabs (4.0 × 10^-2 m length, 2.0 × 10^-2 m width). The pretreated samples were sprayed with ethanol (4.0 × 10^-4 L) on each leaf side (Corrêa et al., 2012CORRÊA, J. L. G. et al. The influence of ethanol on the convective drying of unripe, ripe, and overripe bananas. Drying Technology , 30(8):817-826, 2012.).

Vacuum drying experiments

The vacuum drying of pretreated and untreated samples was conducted in a temperature-controlled oven (Solab SL104/40, Piracicaba, Brazil) coupled with a vacuum pump. The experiments were performed at two different temperatures, generally employed for leaves drying (40 and 50 ºC). A vacuum pressure of 10 kPa was applied. During the vacuum drying, the mass of the samples was monitored using a digital balance. All the drying experiments were carried out in triplicate, and for each assay, approximately 25 slices were used.

Drying kinetics and mathematical modeling

Drying behavior

The experimental results obtained were fitted using drying equations. The moisture ratio (MR) of the samples was calculated using the Equation 1.

M R = \frac{X_{t} - X_{e}}{X_{0} - X_{e}}

(1)

where MR is the moisture ratio [dimensionless], X_t is the moisture content at a specific time [kg water/kg], X₀ is the initial moisture content [kg water/kg] and X_e is the moisture content under equilibrium conditions [kg water/kg].

The drying rate (DR) of the taioba leaves was calculated using Equation 2.

D R = \frac{X_{t + d t} - X_{t}}{d_{t}}

(2)

where DR is drying rate [kg water/ (kg × min)], t is time [min] and dt is time increase [min].

Effective diffusivity determination

The effective diffusivity (D_eff) was obtained according to the analytical solution of Fick’s second law in unsteady state (Equation 3):

\frac{\partial X_{t}}{\partial t} = D_{e f f} \nabla^{2} X_{t}

(3)

where D_eff is the effective diffusivity [m² /s].

The solution to Equation 3 is obtained using the Fourier series, following some assumptions:

Uniform initial moisture content $X (z,0) = X_{0}$ ;

Moisture concentration symmetry $\frac{\partial X_{t}}{\partial t}|_{_{\underset{}{_{z = 0}}}} = 0$ ;

Equilibrium content at the surface, $X (L, t) = X_{e}$ ;

The samples are infinite slabs (length and width much greater than thickness);

Isothermal process;

Shrinkage and external resistance to mass transfer are neglected;

Considering a brief process and unidirectional moisture diffusion, the D_eff is calculated according to Equation 4.

M R = (\frac{8}{π^{2}} \sum_{i = 0}^{\infty} \frac{1}{{(2 i + 1)}^{2}} \exp (- {(2 i + 1)}^{2} π^{2} D_{e f f} \frac{t}{4 L^{2}}))

(4)

where L is the characteristic length (half of the thickness), which corresponds to 2.842 × 10^-4 m.

Empirical equations

The drying curve was fitted with some empirical equations derived from Fick’s diffusion model. The empirical equations applied to agricultural products are shown in Table 1.

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Table 1:
Empirical equations applied to the drying curves.

Quality analyses

The following analyses were performed in either fresh or dried taioba leaves. All the analyses were performed in triplicate.

Total phenolic content

The total phenolic content (TPC) was quantified in the Folin-Ciocalteu assay (Singleton; Rossi, 1965SINGLETON, V.; ROSSI, J. Colorimetry of total phenolic compounds with phosphomolybdic-phosphotungstic acid reagents. American Journal of Enology and Viticulture, 16:144-158, 1965.) with certain modifications. The absorbance was measured by UV-visible spectrophotometer (Cary 50, Varian, Australia) at 750 nm. Gallic acid was used as the standard, and the results were expressed as gallic acid equivalents (GAE) in mg/ g (d.b.).

Antioxidant activity

The DPPH (2,2-difenil-1-picril-hidrazil) radical-scavenging capacity of the leaf extracts was evaluated according to Brand-Williams et al. (1995)BRAND-WILLIAMS, W. et al. Use of a free radical method to evaluate antioxidant activity. LWT - Food Science and Technology, 28(1):25-30, 1995. with slight modifications. The DPPH method is an electron transfer based assay, based on the sequester the stable radical DPPH•, which measures the antioxidant capacity (Apak et al., 2013APAK, R. et al. Methods of measurement and evaluation of natural antioxidant capacity/activity (IUPAC Technical Report). Pure and Applied Chemistry, 85(5):957-998, 2013.).

Ascorbic acid

The ascorbic acid (AA) content was determined according to Strohecker and Henning (1967STROHECKER, R. L.; HENNING, H. M. Análisis de vitaminas: Métodos comprobados. Madrid: Paz Montalvo, 1967. 428p.) by the colorimetric method using 2,4-dinitrophenyl hydrazine. Briefly, the AA was extracted with 0.5 % oxalic acid, filtered, and dosed in the extract, using AA as a standard. The absorbance was measured by a UV-visible spectrophotometer (Cary 50, Varian, Australia) at 520 nm. The results were expressed in mg/100 g (d.b.).

pH and titratable acidity

The pH was obtained in a pHmeter (Digimed, DMpH-2 model, São Paulo, Brazil) and the titratable acidity (TA) determination was performed by titration with an NaOH solution, according to AOAC (2016). The TA was expressed as mg of citric acid (CA)/g (d. b.)

Statistical analyses

Statistical evaluation of the mathematical modeling

The results were analyzed using Statistica software (Statistica 8.0, Statsoft Inc., Tulsa, UK). The equations parameters were estimated using a non-linear regression procedure. The coefficient of determination (R²), root mean square error (RMSE), reduced chi-square (χ²), and percent mean deviation modulus (P%) were used to determine the quality of the adjustment. Higher R² and lower RMSE and P% values indicated better adjustment (Babu et al., 2018BABU, A. K. et al. Review of leaf drying: Mechanism and influencing parameters, drying methods, nutrient preservation, and mathematical models. Renewable and Sustainable Energy Reviews, 90(3):536-556, 2018.). These parameters can be calculated using Equations (5, 6 and 7):

R M S E = \sqrt{\frac{1}{N} \sum {(Y - \hat{Y})}^{2}}

(5)

χ^{2} = {\frac{\sum (Y - \hat{Y})}{D F}}^{2}

(6)

P (%) = \frac{100}{N - D F} \sum |\frac{Y - \hat{Y}}{Y}|

(7)

where Y and Ŷ denote experimental and predicted values respectively, DF is the residual degrees of freedom (number of experimental observations minus the number of model parameters) and N is number of experimental observations.

Statistical evaluation of the quality analysis

The quality analysis results were evaluated by one-way ANOVA at the 95% probability level. The means were compared using the Tukey test, in case of significant effects (p < 0.05). These analyses were also performed using the software Statistica 8.0 (Statsoft Inc., Tulsa, UK).

RESULTS AND DISCUSSION

Drying kinetic

Figure 1 shows the drying curves of untreated and treated taioba leaves during the vacuum drying. The time for the samples to reach a final moisture content of 0.873 ± 0.003 kg water/ kg d.b. ranged from 720 min (50 ºC, ethanol) to 1500 min (40 ºC, untreated).

Figure 1:
Natural logarithm of the dimensionless moisture versus time in different vacuum drying treatments.

Lower drying time was observed in the treatments at 50 ºC (Figure 1). The internal resistance to moisture removal reduces as the drying temperature increases. Such a fact is related to the increase in the water molecules mobility. The external resistance also reduces with the temperature, due to the increase in the driving force. According to Figure 1, the drying time decreased by about 40 % increasing the drying air temperature from 40 to 50 °C. The enhancement of vapor pressure in the sample intensifies the moisture evaporation from the solid inner to the surface, with the temperature increase (Aral; Beşe, 2016ARAL, S.; BEŞE, A. V. Convective drying of hawthorn fruit (Crataegus spp.): Effect of experimental parameters on drying kinetics, color, shrinkage, and rehydration capacity. Food Chemistry, 210:577-584, 2016.; Cano-Lamadrid et al., 2018CANO-LAMADRID, M. et al. Quality of pomegranate pomace as affected by drying method. Journal of Food Science and Technology, 55(3):1074-1082, 2018.; Oliveira et al., 2021OLIVEIRA, L. F. et al. Drying of ‘yacon’ pretreated by pulsed vacuum osmotic dehydration. Brazilian Journal of Agricultural and Environmental Engineering, 25(8):560-565, 2021.).

Some authors, as Elhussein and Şahin (2018ELHUSSEIN, E. A. A.; ŞAHIN, S. Drying behaviour, effective diffusivity and energy of activation of olive leaves dried by microwave, vacuum and oven drying methods. Heat and Mass Transfer, 54(7):1901-1911, 2018.) and Thirugnanasambandham and Sivakumar (2016THIRUGNANASAMBANDHAM, K.; SIVAKUMAR, V. Enhancement of shelf life of Coriandrum sativum leaves using vacuum drying process: Modeling and optimization. Journal of the Saudi Society of Agricultural Sciences , 15(2):195-201, 2016.), have concluded that high temperatures lead to a reduction in the total drying time during the vacuum drying of olive and Coriandrum leaves, respectively.

The ethanol treatment reduced the drying time, for both temperatures (Figure 1). The pretreatments could reduce the drying time by about 20 %. This fact occurred due to the Marangoni effect. This effect is due to the existence of a surface tension gradient at the interface between the liquids (water + ethanol). The ethanol presents a lower surface tension (and higher volatility) than pure water, and in this solution, a rather strong convective motion may be produced, which results in a surface shear stress, facilitating the water removal (Gambaryan-Roisman, 2015GAMBARYAN-ROISMAN, T. Modulation of marangoni convection in liquid films. Advances in Colloid and Interface Science, 222:319-331, 2015.).

Similar reports were presented by Silva, Celeghini and Silva (2018SILVA, M. G.; CELEGHINI, R. M. S.; SILVA, M. A. Effect of ethanol on the drying characteristics and on the coumarin yield of dried guaco leaves (Mikania laevigata Schultz Bip. Ex Baker). Brazilian Journal of Chemical Engineering, 35(3):1095-1104, 2018.) during the drying of treated and untreated guaco leaves (Mikania laevigata Schultz Bip. ex Baker). In this study, comparing the treatments with and without ethanol, a reduction in drying time ranging from 16 to 20 %, at 50 and 60 ºC, respectively, was observed. The influence of ethanol pretreatment was evaluated by Souza et al. (2018SOUZA, A. U. et al. The influence of ethanol and vacuum on okara drying. Journal of Food Chemistry & Nanotechnology, 4(4):271-286, 2018.) during the vacuum and convective drying of okara (soy coproduct processing). The ethanol reduced the drying time by 20 to 40 %, saving energy.

The Figure 2 shows the drying rates of taioba leaves during the different treatments.

Figure 2:
The drying rate of taioba leaves versus moisture content in different vacuum drying treatments.

It can be seen from Figure 2 that the different treatments were found in the falling rate period, which implies that the diffusion mass transfer controls the drying process. The absence of a constant drying rate period has been reported by several authors during agricultural food drying (Babu et al., 2018BABU, A. K. et al. Review of leaf drying: Mechanism and influencing parameters, drying methods, nutrient preservation, and mathematical models. Renewable and Sustainable Energy Reviews, 90(3):536-556, 2018.; Lyu et al., 2017LYU, J. et al. Drying characteristics and quality of kiwifruit slices with/without osmotic dehydration under short- and medium-wave infrared radiation drying. International Journal of Food Engineering , 13(8):1-15, 2017.; Purkayastha et al., 2013PURKAYASTHA, D. M. et al. Thin layer drying of tomato slices. Journal of Food Science and Technology , 50(4):642-653, 2013.).

At the end of the process when moisture content was low, the drying rate under all drying conditions reduced (Figure 2), and it was higher in the leaves pretreated with ethanol [> 0.002 kg water/ (kg × min)]. In such situation, the water molecules form a eutectic solution with the ethanol, which accelerates the water evaporation, by reducing the vapor pressure, as can be noted at the process beginning. The higher DR during the initial period of the process is related to the increased water migration and evaporation, and less external resistance (Esturk, 2012ESTURK, O. Intermittent and continuous microwave-convective air-drying characteristics of sage (Salvia officinalis) leaves. Food and Bioprocess Technology, 5:1664-1673, 2012.; Mghazli et al., 2017MGHAZLI, S. et al. Drying characteristics and kinetics solar drying of Moroccan rosemary leaves. Renewable Energy, 108:303-310, 2017.; Yilmaz; Alibas, 2017YILMAZ, A.; ALIBAS, I. Determination of microwave and convective drying characteristics of coriander leaves. Journal of Biological and Environmental Sciences, 11(32):75-85, 2017.).

As can be observed in Figures 1 and 2, the leaves dried at 50 ºC present higher drying rates (lower drying periods). The drying temperature increase promoted an increase in the drying rate, thus the drying time was reduced. Shi, Zheng and Zhao (2013SHI, Q.; ZHENG, Y.; ZHAO, Y. Mathematical modeling on thin-layer heat pump drying of yacon (Smallanthus sonchifolius) slices. Energy Conversion and Management, 71:208-216, 2013.) pointed out that the water molecules move faster with the temperature increase, due to the enhancement in the heat transfer rate. During leaf drying, Doymaz (2009DOYMAZ, I. Thin-layer drying of spinach leaves in a convective dryer. Journal of Food Process Engineering, 32(1):112-125, 2009.) and Therdthai and Zhou (2009THERDTHAI, N.; ZHOU, W. Characterization of microwave vacuum drying and hot air drying of mint leaves (Mentha cordifolia Opiz ex Fresen). Journal of Food Engineering , 91(3):482-489, 2009.) observed that the increase in the air temperature improved the drying rate of spinach and mint, respectively.

Mathematical model

Several mathematical models were used for modeling the drying kinetics. Table 2 presents the effective diffusivity (D_eff) values.

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Table 2:
Effective diffusivities (D_eff) and statistical parameters during the VD of taioba leaves.

The D_eff values ranged from 4.418 × 10^-11 to 8.008 × 10^-11 m²/s and the R² values ranged from 0.9058 to 0.9899. The RMSE and χ² values were under 1.184 × 10^-1 and 1.525 × 10^-2, respectively.

The D_eff values vary with the agricultural material and the experimental conditions, hindering the comparison of exact values, but the results presented in Table 2 indicate an analogous magnitude order of edible leaves subjected to drying processes (Elhussein; Şahin, 2018ELHUSSEIN, E. A. A.; ŞAHIN, S. Drying behaviour, effective diffusivity and energy of activation of olive leaves dried by microwave, vacuum and oven drying methods. Heat and Mass Transfer, 54(7):1901-1911, 2018.). During the drying of bay laurel leaves, Ghnimi, Hassini and Bagane (2016GHNIMI, T.; HASSINI, L.; BAGANE, M. Experimental study of water desorption isotherms and thin-layer convective drying kinetics of bay laurel leaves. Heat and Mass Transfer , 52(12):2649-2659, 2016.) observed D_eff varying from 1.21 × 10^-11 to 5.27 × 10^-11 m²/s in the temperature range of 45-75 °C and during the drying of rosemary leaves, Mghazli et al. (2017MGHAZLI, S. et al. Drying characteristics and kinetics solar drying of Moroccan rosemary leaves. Renewable Energy, 108:303-310, 2017.) observed D_eff varying from 1.21 × 10^-11 to 5.27 × 10^-11 m²/s in the temperature range of 50-80 °C.

According to Table 2, the pretreatment with ethanol reduced the accuracy of this diffusive model (R² < 0.93). This fact occurred due to the interaction between the water and the ethanol, which affects the initial and boundary assumptions employed for the analytical development of this model (such as constant initial moisture distribution and homogeneous D_eff) during the drying process, beyond the Marangoni’s effect (Junqueira et al., 2021JUNQUEIRA, J. R. J. et al. Modeling mass transfer during osmotic dehydration of different vegetable structures under vacuum conditions. Food Science and Technology, 41(2):439- 448, 2021.; Simpson et al., 2015SIMPSON, R. Diffusion mechanisms during the osmotic dehydration of granny smith apples subjected to a moderate electric field. Journal of Food Engineering , 166:204-211, 2015.).

The highest D_eff values were obtained at the highest temperature (50 ºC). This behavior was expected and is consistent with the process physics, since D_eff encompasses all phenomena that can intervene in the water migration in the system: the higher temperature, the lower internal resistance (Golestani; Raisi; Aroujalian, 2013GOLESTANI, R.; RAISI, A.; AROUJALIAN, A. Mathematical modeling on air drying of apples considering shrinkage and variable diffusion coefficient. Drying Technology , 31(1):40-51, 2013.). Elhussein and Şahin (2018ELHUSSEIN, E. A. A.; ŞAHIN, S. Drying behaviour, effective diffusivity and energy of activation of olive leaves dried by microwave, vacuum and oven drying methods. Heat and Mass Transfer, 54(7):1901-1911, 2018.) studied different methods for olive leaves drying and noted that the D_eff ranged from 1.1 × 10^-10 m²/s (at 50 ºC) to 6.2 × 10^-10 m²/s (at 90 ºC) in the VD method.

Table 3 summarizes the empirical equation parameters with their comparison criteria (R², RMSE, χ² and P%) for their suitability. In general, all the empirical equations were found highly appropriate for describing the taioba leaves drying behavior in different treatments. The R² value were higher than 0.988, and the RMSE, χ² and P% were lower than 0.04, 0.003 and 8.82, respectively. The P% value analysis was conducted and according to Kaushal and Sharma (2016KAUSHAL, P.; SHARMA, H. K. Osmo-convective dehydration kinetics of jackfruit (Artocarpus heterophyllus). Journal of the Saudi Society of Agricultural Sciences, 15(2):118-126, 2016.), P% < 5 indicates an excellent fit, while P% > 10 is indicative of an inadequate fit.

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Table 3:
Adjustment parameters and statistics results obtained from different thin-layer drying equations.

Therefore, depending on the relatively high P% values (> 5), Henderson & Pabis, Page, Two terms and Wang & Singh equations were the least compatible models, even though under some conditions, these equations adequately described the experimental drying.

The suitability of Logarithmic, Midilli & Kuçuk and Parabolic equations for portraying the convective drying behavior of agricultural products is extensively presented in the literature (Kucuk et al., 2014KUCUK, H. et al. A Review on thin-layer drying-curve equations. Drying Technology , 32(7):757-773, 2014.). Mbegbu, Nwajinka and Amaefule (2021MBEGBU, N. N.; NWAJINKA, C. O.; AMAEFULE, D. O. Thin layer drying models and characteristics of scent leaves (Ocimum gratissimum) and lemon basil leaves (Ocimum africanum). Heliyon, 7(1):e05945, 2021.) reported that the Logarithmic model showed good fit for scent and lemon basil leaves in the vacuum drying processes. Such a model was used for describing the drying behavior of thyme leaves during convective drying at different temperatures (Turan; Firatligil, 2019TURAN, O. Y.; FIRATLIGIL, F. E. Modelling and characteristics of thin layer convective air-drying of thyme (Thymus vulgaris) leaves. Czech Journal of Food Sciences, 37(2):128-134, 2019.).

Alara et al. (2018ALARA, O. R. et al. Mathematical modeling of thin layer drying using open sun and shade of Vernonia amygdalina leaves. Agriculture and Natural Resources, 52(1):53-58, 2018.) concluded that the Midilli & Kuçuk model could be used in the prediction of both open sun and shade drying behavior of Vernonia amygdalina Del. leaves.

Quality analysis

The effect of ethanol pretreatment and temperature during the vacuum drying on total phenolic content (TPC), total antioxidant activity (TAA), ascorbic acid (AA), pH and titratable acidity (TA) was evaluated. The results are shown in Figures 3 and 4 and Table 4. Different treatments caused significant changes in TPC and AA, but no differences were observed for pH and TA.

Figure 3:
Total phenolic content (TPC) of taioba leaves in different vacuum drying treatments. Means followed by different letters show significant differences (p ≤ 0.05), according to Tukey’s test.

Figure 4:
Total antioxidant activity (TAA) of taioba leaves in different vacuum drying treatments. Means followed by different letters show significant differences (p ≤ 0.05), according to Tukey’s test.

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Table 4:
Chemical characteristics of dried taioba leaves.

The TPC of the fresh leaves was 5.01 ± 0.15 mg GAE/g (d. b.), and according to Figure 3, all treatments exhibited TPC reduction. A higher TPC retention (p < 0.05) was observed in the untreated treatments (without ethanol pretreatment). In those treatments, the retention ranged from 57.11 % (50 ºC, untreated) to 62.34 % (40 ºC, untreated). The TPC retention is desirable, since phenolics present a wide range of biological activity, including antioxidant properties (Del Rio et al., 2013DEL RIO, D. et al. Dietary (poly)phenolics in human health: Structures, bioavailability, and evidence of protective effects against chronic diseases. Antioxidants & Redox Signaling, 18(14):1818-1892, 2013.).

The phenolic compounds are within the vacuole (apart from the enzymes and oxygen). During the drying process, irreversible changes in the cellular structure are observed, and a decompartmentation occurs, favoring degradative reactions, since those damages trigger the release of enzymes (mainly polyphenol oxidase and peroxidase) and decreases the TPC. Nevertheless, the vacuum limits the oxygen concentration (for oxidative reactions), the phenolic compounds are heat sensitive, and the exposure to the heat and light could complete the phenolics damage (Erbay; Icier, 2009ERBAY, Z.; ICIER, F. Optimization of hot air drying of olive leaves using response surface methodology. Journal of Food Engineering , 91(4):533-541, 2009.; Zielinska; Zielinska; Markowski, 2018ZIELINSKA, M.; ZIELINSKA, D.; MARKOWSKI, M. The Effect of microwave- vacuum pretreatment on the drying kinetics, color and the content of bioactive compounds in osmo-microwave-vacuum dried cranberries (Vaccinium macrocarpon). Food and Bioprocess Technology , 11:585-602, 2018.).

Our results are also in agreement with those reported by Nóbrega et al. (2014NÓBREGA, E. M. et al. The impact of hot air drying on the physical-chemical characteristics, bioactive compounds and antioxidant activity of acerola (Malphigia emarginata) residue. Journal of Food Processing and Preservation, 39(2):131-141, 2014.), who observed that the TPC of acerola residue was significantly reduced after convective drying.

The TAA seems to be related to the phenolic presence, and their properties may change because of their oxidation state, and it was determined by the DPPH• method. According to Figure 4, a significant difference between treatments (p > 0.05) was observed.

Regardless of the temperature, the ethanol treatment leads to a lower DPPH• radical scavenging activity, when compared to the untreated. According to Rojas and Augusto (2018ROJAS, M. L.; AUGUSTO, P. E. D. Ethanol and ultrasound pre-treatments to improve infrared drying of potato slices. Innovative Food Science and Emerging Technologies, 49:65-75, 2018.), the use of ethanol can produce or intensify of microchannels, which in processes as drying, could cause the loss of food matrix compounds. The best result should be attributed to the treatment submitted to 40 °C, untreated (63.12 % ± 0.01), followed by samples submitted to 50 °C, untreated (59.76 % ± 0.08). Such a result reinforces that compounds with antioxidant character may exhibit thermosensitivity and significant degradation with increased temperature (Lutz; Hernández; Henríquez, 2015LUTZ, M.; HERNÁNDEZ, J.; HENRÍQUEZ, C. Phenolic content and antioxidant capacity in fresh and dry fruits and vegetables grown in Chile. CyTA - Journal of Food, 13(4):541-547, 2015.).

The results showed that the drying method had a significant effect on AA content (p ≤ 0.05), according to Table 4. The highest AA content [0.860 ± 0.002 mg/ g (d.b.)] occurred with VD at 40 ºC with ethanol pretreatment, and the lowest AA content was obtained by [0.239 ± 0.002 mg/ g (d.b.)] VD at 50 ºC without ethanol pretreatment. All the treatments presented lower AA content, compared with fresh taioba leaves [4.924 ± 0.007 mg/ g (d.b.)]. Such a reduction was expected, as this vitamin is heat-sensitive (Junqueira et al., 2017JUNQUEIRA, J. R. J. et al. Convective drying of cape gooseberry fruits: Effect of pretreatments on kinetics and quality parameters. LWT - Food Science and Technology , 82:404-410, 2017.).

The temperature increase enhances the drying evaporation, reducing the total drying time (Figure 1), although, a degradation of heat-sensitive compounds is observed, indicating quality loss (Saini et al., 2014SAINI, R. K. et al. Effect of dehydration methods on retention of carotenoids, tocopherols, ascorbic acid and antioxidant activity in Moringa oleifera leaves and preparation of a RTE product. Journal of Food Science and Technology , 51(9):2176-2182, 2014.). During the pequi drying under different conditions, Mendonça et al. (2017MENDONÇA, K. S. et al. Influences of convective and vacuum drying on the quality attributes of osmo-dried pequi (Caryocar brasiliense Camb.) slices. Food Chemistry , 224:212-218, 2017.) found that samples dried at low temperatures, had high AA retention. The ethanol pretreatment assisted the AA preservation (Table 4). This technique increases the moisture evaporation, reducing the long exposure to temperature conditions (Araújo et al., 2020ARAÚJO, C. S. et al. Influence of pretreatment with ethanol and drying temperature on physicochemical and antioxidant properties of white and red pulp pitayas dried in foam mat. Drying Technology, 1-10, 2020.).

The pH of the fresh taioba leaves was 5.87 ± 0.01. According to Table 4, an increase in pH was observed and it was not significantly different among the samples (p > 0.05). The pH values ranged from 6.09 ± 0.02 to 6.13 ± 0.04. This result might be due to the organic acids in the leaves, moreover the drying process may provoke the acidic compounds evaporation (Sagrin; Chong, 2013SAGRIN, M. S.; CHONG, G. H. Effects of drying temperature on the chemical and physical properties of Musa acuminata Colla (AAA Group) leaves. Industrial Crops and Products, 45:430-434, 2013.). Similar reports were found by Shitanda and Wanjala (2006SHITANDA, D.; WANJALA, N. V. Effect of different drying methods on the quality of jute (Corchorus olitorius L.). Drying Technology , 24(1):95-98, 2006.) during the evaluation of different drying techniques of jute leaves and by Sagrin and Chong (2013)SAGRIN, M. S.; CHONG, G. H. Effects of drying temperature on the chemical and physical properties of Musa acuminata Colla (AAA Group) leaves. Industrial Crops and Products, 45:430-434, 2013. during the drying of banana leaves in different temperatures.

According to Table 4, no significant difference (p > 0.05) was observed in the TA values among the treatments. The TA of the fresh leaves was 0.365 ± 0.097 mg CA/g (d. b.). In general, the exposure to high temperatures during the drying leads to organic acid degradation, inducing the oxidation of those compounds. The TA values ranged from 0.152 ± 0.013 to 0.182 ± 0.022 mg CA/ g (d.b.). No difference was observed in that parameter, and this occurred probably due to the oxygen suppression during the vacuum processes (Oliveira et al., 2021OLIVEIRA, L. F. et al. Drying of ‘yacon’ pretreated by pulsed vacuum osmotic dehydration. Brazilian Journal of Agricultural and Environmental Engineering, 25(8):560-565, 2021.).

CONCLUSIONS

Higher temperature and ethanol pretreatment promoted a shortened drying process. The D_eff ranged from 4.4 × 10^-11 to 8.0 × 10^-11 m²/s, and the Logarithmic and Midilli & Kuçuk equations performed best adjustments. The treatments presented a significant difference (p ≤ 0.05) in the TPC, TAA and AA. There was no significant difference (p > 0.05) in pH values and titratable acidity. Preservation in the AA content and a reduction in the TPC and TAA were observed in pretreated samples.

AUTHORS CONTRIBUTION

Conceptual idea: Junqueira, J. R. J.; Corrêa, J. L. G.; Methodology design: Junqueira, J. R. J.; Resende, N. S.; Data collection: Junqueira, J. R. J.; Mendonça, K. S.; Data analysis and interpretation: Junqueira, J. R. J.; Corrêa, J. L. G.; Balbinoti, T. C. V.; Writing and editing: Junqueira, J. R. J.; Corrêa, J. L. G.; Gatti, I. P.

ACKNOWLEDGMENTS

This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001.

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BRAND-WILLIAMS, W. et al. Use of a free radical method to evaluate antioxidant activity. LWT - Food Science and Technology, 28(1):25-30, 1995.
CANO-LAMADRID, M. et al. Quality of pomegranate pomace as affected by drying method. Journal of Food Science and Technology, 55(3):1074-1082, 2018.
CORRÊA, J. L. G. et al. The influence of ethanol on the convective drying of unripe, ripe, and overripe bananas. Drying Technology , 30(8):817-826, 2012.
DEL RIO, D. et al. Dietary (poly)phenolics in human health: Structures, bioavailability, and evidence of protective effects against chronic diseases. Antioxidants & Redox Signaling, 18(14):1818-1892, 2013.
DOYMAZ, I. Thin-layer drying of spinach leaves in a convective dryer. Journal of Food Process Engineering, 32(1):112-125, 2009.
EBADI, M. T. et al. Influence of different drying methods on drying period, essential oil content and composition of Lippia citriodora Kunth. Journal of Applied Research on Medicinal and Aromatic Plants, 2(4):182-187, 2015.
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ESTURK, O. Intermittent and continuous microwave-convective air-drying characteristics of sage (Salvia officinalis) leaves. Food and Bioprocess Technology, 5:1664-1673, 2012.
GAMBARYAN-ROISMAN, T. Modulation of marangoni convection in liquid films. Advances in Colloid and Interface Science, 222:319-331, 2015.
GHNIMI, T.; HASSINI, L.; BAGANE, M. Experimental study of water desorption isotherms and thin-layer convective drying kinetics of bay laurel leaves. Heat and Mass Transfer , 52(12):2649-2659, 2016.
GOLESTANI, R.; RAISI, A.; AROUJALIAN, A. Mathematical modeling on air drying of apples considering shrinkage and variable diffusion coefficient. Drying Technology , 31(1):40-51, 2013.
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JUNQUEIRA, J. R. J. et al. Modeling mass transfer during osmotic dehydration of different vegetable structures under vacuum conditions. Food Science and Technology, 41(2):439- 448, 2021.
KAUSHAL, P.; SHARMA, H. K. Osmo-convective dehydration kinetics of jackfruit (Artocarpus heterophyllus). Journal of the Saudi Society of Agricultural Sciences, 15(2):118-126, 2016.
KUCUK, H. et al. A Review on thin-layer drying-curve equations. Drying Technology , 32(7):757-773, 2014.
LUTZ, M.; HERNÁNDEZ, J.; HENRÍQUEZ, C. Phenolic content and antioxidant capacity in fresh and dry fruits and vegetables grown in Chile. CyTA - Journal of Food, 13(4):541-547, 2015.
LYU, J. et al. Drying characteristics and quality of kiwifruit slices with/without osmotic dehydration under short- and medium-wave infrared radiation drying. International Journal of Food Engineering , 13(8):1-15, 2017.
MADHIYANON, T.; PHILA, A.; SOPONRONNARIT, S. Models of fluidized bed drying for thin-layer chopped coconut. Applied Thermal Engineering, 29(14-15):2849-2854, 2009.
MBEGBU, N. N.; NWAJINKA, C. O.; AMAEFULE, D. O. Thin layer drying models and characteristics of scent leaves (Ocimum gratissimum) and lemon basil leaves (Ocimum africanum). Heliyon, 7(1):e05945, 2021.
MENDONÇA, K. S. et al. Influences of convective and vacuum drying on the quality attributes of osmo-dried pequi (Caryocar brasiliense Camb.) slices. Food Chemistry , 224:212-218, 2017.
MGHAZLI, S. et al. Drying characteristics and kinetics solar drying of Moroccan rosemary leaves. Renewable Energy, 108:303-310, 2017.
MIDILLI, A.; KUCUK, H.; YAPAR, Z. A new model for single-layer drying. Drying Technology , 20(7):1503-1513, 2002
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OLIVEIRA, L. F. et al. Drying of ‘yacon’ pretreated by pulsed vacuum osmotic dehydration. Brazilian Journal of Agricultural and Environmental Engineering, 25(8):560-565, 2021.
PURKAYASTHA, D. M. et al. Thin layer drying of tomato slices. Journal of Food Science and Technology , 50(4):642-653, 2013.
ROJAS, M. L.; AUGUSTO, P. E. D. Ethanol and ultrasound pre-treatments to improve infrared drying of potato slices. Innovative Food Science and Emerging Technologies, 49:65-75, 2018.
SAGRIN, M. S.; CHONG, G. H. Effects of drying temperature on the chemical and physical properties of Musa acuminata Colla (AAA Group) leaves. Industrial Crops and Products, 45:430-434, 2013.
SAINI, R. K. et al. Effect of dehydration methods on retention of carotenoids, tocopherols, ascorbic acid and antioxidant activity in Moringa oleifera leaves and preparation of a RTE product. Journal of Food Science and Technology , 51(9):2176-2182, 2014.
SHARMA, G. P.; PRASAD, S. Effective moisture diffusivity of garlic cloves undergoing microwave-convective drying. Journal of Food Engineering , 65(4):609-617, 2004.
SHI, Q.; ZHENG, Y.; ZHAO, Y. Mathematical modeling on thin-layer heat pump drying of yacon (Smallanthus sonchifolius) slices. Energy Conversion and Management, 71:208-216, 2013.
SHITANDA, D.; WANJALA, N. V. Effect of different drying methods on the quality of jute (Corchorus olitorius L.). Drying Technology , 24(1):95-98, 2006.
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SINGLETON, V.; ROSSI, J. Colorimetry of total phenolic compounds with phosphomolybdic-phosphotungstic acid reagents. American Journal of Enology and Viticulture, 16:144-158, 1965.
SOUZA, A. U. et al. The influence of ethanol and vacuum on okara drying. Journal of Food Chemistry & Nanotechnology, 4(4):271-286, 2018.
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ZIELINSKA, M.; ZIELINSKA, D.; MARKOWSKI, M. The Effect of microwave- vacuum pretreatment on the drying kinetics, color and the content of bioactive compounds in osmo-microwave-vacuum dried cranberries (Vaccinium macrocarpon). Food and Bioprocess Technology , 11:585-602, 2018.

Publication Dates

Publication in this collection
06 Dec 2021
Date of issue
2021

History

Received
17 Sept 2021
Accepted
03 Nov 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] AKPINAR, E. K.; BICER, Y.; YILDIZ, C. Thin layer drying of red pepper. Journal of Food Engineering, 59(1):99-104, 2003.

[2] ALARA, O. R. et al. Mathematical modeling of thin layer drying using open sun and shade of Vernonia amygdalina leaves. Agriculture and Natural Resources, 52(1):53-58, 2018.

[3] ALMEIDA, M. E. F. et al. Caracterização química das hortaliças não-convencionais conhecidas como ora-pro-nobis. Bioscience Journal, 30(3):431-439, 2014.

[4] APAK, R. et al. Methods of measurement and evaluation of natural antioxidant capacity/activity (IUPAC Technical Report). Pure and Applied Chemistry, 85(5):957-998, 2013.

[5] ARAL, S.; BEŞE, A. V. Convective drying of hawthorn fruit (Crataegus spp.): Effect of experimental parameters on drying kinetics, color, shrinkage, and rehydration capacity. Food Chemistry, 210:577-584, 2016.

[6] ARAÚJO, C. S. et al. Influence of pretreatment with ethanol and drying temperature on physicochemical and antioxidant properties of white and red pulp pitayas dried in foam mat. Drying Technology, 1-10, 2020.

[7] ASSOCIATION OF OFFICIAL AGRICULTURAL CHEMISTS - AOAC. Official Methods of Analysis of AOAC International. 20th Ed, Rockville, Maryland, USA, 2016. 3172p.

[8] BABU, A. K. et al. Review of leaf drying: Mechanism and influencing parameters, drying methods, nutrient preservation, and mathematical models. Renewable and Sustainable Energy Reviews, 90(3):536-556, 2018.

[9] BRAND-WILLIAMS, W. et al. Use of a free radical method to evaluate antioxidant activity. LWT - Food Science and Technology, 28(1):25-30, 1995.

[10] CANO-LAMADRID, M. et al. Quality of pomegranate pomace as affected by drying method. Journal of Food Science and Technology, 55(3):1074-1082, 2018.

[11] CORRÊA, J. L. G. et al. The influence of ethanol on the convective drying of unripe, ripe, and overripe bananas. Drying Technology , 30(8):817-826, 2012.

[12] DEL RIO, D. et al. Dietary (poly)phenolics in human health: Structures, bioavailability, and evidence of protective effects against chronic diseases. Antioxidants & Redox Signaling, 18(14):1818-1892, 2013.

[13] DOYMAZ, I. Thin-layer drying of spinach leaves in a convective dryer. Journal of Food Process Engineering, 32(1):112-125, 2009.

[14] EBADI, M. T. et al. Influence of different drying methods on drying period, essential oil content and composition of Lippia citriodora Kunth. Journal of Applied Research on Medicinal and Aromatic Plants, 2(4):182-187, 2015.

[15] ELHUSSEIN, E. A. A.; ŞAHIN, S. Drying behaviour, effective diffusivity and energy of activation of olive leaves dried by microwave, vacuum and oven drying methods. Heat and Mass Transfer, 54(7):1901-1911, 2018.

[16] ERBAY, Z.; ICIER, F. Optimization of hot air drying of olive leaves using response surface methodology. Journal of Food Engineering , 91(4):533-541, 2009.

[17] ESTURK, O. Intermittent and continuous microwave-convective air-drying characteristics of sage (Salvia officinalis) leaves. Food and Bioprocess Technology, 5:1664-1673, 2012.

[18] GAMBARYAN-ROISMAN, T. Modulation of marangoni convection in liquid films. Advances in Colloid and Interface Science, 222:319-331, 2015.

[19] GHNIMI, T.; HASSINI, L.; BAGANE, M. Experimental study of water desorption isotherms and thin-layer convective drying kinetics of bay laurel leaves. Heat and Mass Transfer , 52(12):2649-2659, 2016.

[20] GOLESTANI, R.; RAISI, A.; AROUJALIAN, A. Mathematical modeling on air drying of apples considering shrinkage and variable diffusion coefficient. Drying Technology , 31(1):40-51, 2013.

[21] HENDERSON, S. M.; PABIS, S. Grain drying theory I. Temperature effects on drying coefficient. Journal of Agricultural Engineering Research, 6:169-174, 1961.

[22] JACKIX, E. A. et al. Cholesterol reducing and bile-acid binding properties of taioba (Xanthosoma sagittifolium) leaf in rats fed a high-fat diet. Food Research International, 51(2):886-891, 2013.

[23] JUNQUEIRA, J. R. J. et al. Convective drying of cape gooseberry fruits: Effect of pretreatments on kinetics and quality parameters. LWT - Food Science and Technology , 82:404-410, 2017.

[24] JUNQUEIRA, J. R. J. et al. Modeling mass transfer during osmotic dehydration of different vegetable structures under vacuum conditions. Food Science and Technology, 41(2):439- 448, 2021.

[25] KAUSHAL, P.; SHARMA, H. K. Osmo-convective dehydration kinetics of jackfruit (Artocarpus heterophyllus). Journal of the Saudi Society of Agricultural Sciences, 15(2):118-126, 2016.

[26] KUCUK, H. et al. A Review on thin-layer drying-curve equations. Drying Technology , 32(7):757-773, 2014.

[27] LUTZ, M.; HERNÁNDEZ, J.; HENRÍQUEZ, C. Phenolic content and antioxidant capacity in fresh and dry fruits and vegetables grown in Chile. CyTA - Journal of Food, 13(4):541-547, 2015.

[28] LYU, J. et al. Drying characteristics and quality of kiwifruit slices with/without osmotic dehydration under short- and medium-wave infrared radiation drying. International Journal of Food Engineering , 13(8):1-15, 2017.

[29] MADHIYANON, T.; PHILA, A.; SOPONRONNARIT, S. Models of fluidized bed drying for thin-layer chopped coconut. Applied Thermal Engineering, 29(14-15):2849-2854, 2009.

[30] MBEGBU, N. N.; NWAJINKA, C. O.; AMAEFULE, D. O. Thin layer drying models and characteristics of scent leaves (Ocimum gratissimum) and lemon basil leaves (Ocimum africanum). Heliyon, 7(1):e05945, 2021.

[31] MENDONÇA, K. S. et al. Influences of convective and vacuum drying on the quality attributes of osmo-dried pequi (Caryocar brasiliense Camb.) slices. Food Chemistry , 224:212-218, 2017.

[32] MGHAZLI, S. et al. Drying characteristics and kinetics solar drying of Moroccan rosemary leaves. Renewable Energy, 108:303-310, 2017.

[33] MIDILLI, A.; KUCUK, H.; YAPAR, Z. A new model for single-layer drying. Drying Technology , 20(7):1503-1513, 2002

[34] NÓBREGA, E. M. et al. The impact of hot air drying on the physical-chemical characteristics, bioactive compounds and antioxidant activity of acerola (Malphigia emarginata) residue. Journal of Food Processing and Preservation, 39(2):131-141, 2014.

[35] OLIVEIRA, D. D. C. D. S. et al. Composição mineral e teor de ácido ascórbico nas folhas de quatro espécies olerícolas não-convencionais. Horticultura Brasileira, 31(3):472-475, 2013.

[36] OLIVEIRA, L. F. et al. Drying of ‘yacon’ pretreated by pulsed vacuum osmotic dehydration. Brazilian Journal of Agricultural and Environmental Engineering, 25(8):560-565, 2021.

[37] PURKAYASTHA, D. M. et al. Thin layer drying of tomato slices. Journal of Food Science and Technology , 50(4):642-653, 2013.

[38] ROJAS, M. L.; AUGUSTO, P. E. D. Ethanol and ultrasound pre-treatments to improve infrared drying of potato slices. Innovative Food Science and Emerging Technologies, 49:65-75, 2018.

[39] SAGRIN, M. S.; CHONG, G. H. Effects of drying temperature on the chemical and physical properties of Musa acuminata Colla (AAA Group) leaves. Industrial Crops and Products, 45:430-434, 2013.

[40] SAINI, R. K. et al. Effect of dehydration methods on retention of carotenoids, tocopherols, ascorbic acid and antioxidant activity in Moringa oleifera leaves and preparation of a RTE product. Journal of Food Science and Technology , 51(9):2176-2182, 2014.

[41] SHARMA, G. P.; PRASAD, S. Effective moisture diffusivity of garlic cloves undergoing microwave-convective drying. Journal of Food Engineering , 65(4):609-617, 2004.

[42] SHI, Q.; ZHENG, Y.; ZHAO, Y. Mathematical modeling on thin-layer heat pump drying of yacon (Smallanthus sonchifolius) slices. Energy Conversion and Management, 71:208-216, 2013.

[43] SHITANDA, D.; WANJALA, N. V. Effect of different drying methods on the quality of jute (Corchorus olitorius L.). Drying Technology , 24(1):95-98, 2006.

[44] SILVA, M. G.; CELEGHINI, R. M. S.; SILVA, M. A. Effect of ethanol on the drying characteristics and on the coumarin yield of dried guaco leaves (Mikania laevigata Schultz Bip. Ex Baker). Brazilian Journal of Chemical Engineering, 35(3):1095-1104, 2018.

[45] SIMPSON, R. Diffusion mechanisms during the osmotic dehydration of granny smith apples subjected to a moderate electric field. Journal of Food Engineering , 166:204-211, 2015.

[46] SINGLETON, V.; ROSSI, J. Colorimetry of total phenolic compounds with phosphomolybdic-phosphotungstic acid reagents. American Journal of Enology and Viticulture, 16:144-158, 1965.

[47] SOUZA, A. U. et al. The influence of ethanol and vacuum on okara drying. Journal of Food Chemistry & Nanotechnology, 4(4):271-286, 2018.

[48] STROHECKER, R. L.; HENNING, H. M. Análisis de vitaminas: Métodos comprobados. Madrid: Paz Montalvo, 1967. 428p.

[49] SZADZIŃSKA, J. et al. Microwave- and ultrasound-assisted convective drying of raspberries: Drying kinetics and microstructural changes. Drying Technology , 37(1):1-12, 2018.

[50] THERDTHAI, N.; ZHOU, W. Characterization of microwave vacuum drying and hot air drying of mint leaves (Mentha cordifolia Opiz ex Fresen). Journal of Food Engineering , 91(3):482-489, 2009.

[51] THIRUGNANASAMBANDHAM, K.; SIVAKUMAR, V. Enhancement of shelf life of Coriandrum sativum leaves using vacuum drying process: Modeling and optimization. Journal of the Saudi Society of Agricultural Sciences , 15(2):195-201, 2016.

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Model	Equations	References
Henderson & Pabis	$M R = a \exp (- k t)$	Henderson and Pabis (1961HENDERSON, S. M.; PABIS, S. Grain drying theory I. Temperature effects on drying coefficient. Journal of Agricultural Engineering Research, 6:169-174, 1961.)
Logarithmic	$M R = a \exp (- k t) + b$	Akpinar et al. (2003AKPINAR, E. K.; BICER, Y.; YILDIZ, C. Thin layer drying of red pepper. Journal of Food Engineering, 59(1):99-104, 2003.)
Midilli & Kuçuk	$M R = a \exp (- k t^{n}) + b t$	Midilli et al. (2002MIDILLI, A.; KUCUK, H.; YAPAR, Z. A new model for single-layer drying. Drying Technology , 20(7):1503-1513, 2002)
Page	$M R = \exp (- k t^{n})$
Parabolic	$M R = a + b t + c t^{2}$	Sharma and Prasad (2004SHARMA, G. P.; PRASAD, S. Effective moisture diffusivity of garlic cloves undergoing microwave-convective drying. Journal of Food Engineering , 65(4):609-617, 2004.)
Two terms	$M R = a \exp (- k_{0} t) + b \exp (- k_{1} t)$	Madhiyanon et al. (2009MADHIYANON, T.; PHILA, A.; SOPONRONNARIT, S. Models of fluidized bed drying for thin-layer chopped coconut. Applied Thermal Engineering, 29(14-15):2849-2854, 2009.)
Wang & Singh	$M R = 1 + a t + b t^{2}$	Wang and Singh (1978WANG, C. Y.; SINGH, R. P. Use of variable equilibrium moisture content in modelling rice drying. ASAE Meeting paper, 78:6505, 1978.)

Treatment	D_eff ×10¹¹ [m/s²]	R²	RMSE × 10²	χ² × 10³
40 ºC (untreated)	5.054	0.9899	3.909	1.630
40 ºC (ethanol)	4.418	0.9393	8.758	8.309
50 ºC (untreated)	8.008	0.9858	4.342	2.042
50 ºC (ethanol)	6.335	0.9058	11.845	15.254

Equation	Constant	R²	RMSE	χ²	P (%)
40 ºC (untreated)
Henderson & Pabis	a= 0.95; k= 1.91×10^-5	0.9972	0.0206	0.0005	P (%)	2.796
Logarithmic	a= 0.96; k= 1.93×10^-5; c= -1.21×10^-2	0.9972	0.0206	0.0005	2.438
Midilli & Kuçuk	a= 1.00; k= 6.81×10^-4; n=0.64 ; b= -2.51×10^-6	0.9994	0.0093	0.0001	2.181
Page	k= 9.00×10^-5 ; n= 0.86	0.9966	0.0227	0.0006	5.199
Parabolic	a= 0.93; b= -1.59×10^-5; c= 8.17×10^-11	0.9962	0.0240	0.0007	3.022
Two terms	a= 4.30×10^-5; b= 0.95; k₀= 6.24×10^-5; k₁= 1.95×10^-5	0.9972	0.0204	0.0005	2.354
Wang & Singh	a= -1.96×10^-5; b= 1.16×10^-10	0.9888	0.0412	0.0019	6.479
40 ºC (ethanol)
Henderson & Pabis	a= 1.04; k= 2.31×10^-5	0.9930	0.0301	0.0011	6.479	4.092
Logarithmic	a= 1.08; k= 2.14×10^-5; c= -4.85×10^-2	0.9932	0.0297	0.0011	3.378
Midilli & Kuçuk	a= 1.05; k= 5.17×10^-5; n= 0.91; b= 1.11×10^-6	0.9935	0.0289	0.0012	2.642
Page	k= 7.83×10^-6; n= 1.10	0.9913	0.0337	0.0013	3.341
Parabolic	a= 1.02; b= -2.00×10^-5; c= 1.15×10^-10	0.9916	0.0329	0.0014	3.384
Two terms	a= 2.81; b = -1.77; k₀ = 2.60×10^-5; k₁ = 2.78×10^-5	0.9930	0.0301	0.0013	3.970
Wang & Singh	a= -1.86×10^-5; b= 9.99×10^-11	0.9905	0.0349	0.0014	2.983
50 ºC (untreated)
Henderson and Pabis	a= 0.96; k= 3.25×10^-5	0.9971	0.0194	0.0004	2.983	3.458
Logarithmic	a= 0.97; k= 3.22×10^-5; c= -5.86×10^-3	0.9971	0.0194	0.0005	3.502
Midilli and Kuçuk	a= 0.99; k= 2.38×10^-4; n= 0.79; b= 2.12×10^-6	0.9983	0.0149	0.0003	3.928
Page	k= 9.98×10^-5; n= 0.89	0.9970	0.0197	0.0004	4.318
Parabolic	a= 0.95; b= 2.61×10^-5; c= 2.15×10^-10	0.9962	0.0223	0.0006	3.045
Two terms	a= -0.17; b = 1.13; k₀ = 3.25×10^-5; k₁ = 3.25×10^-5	0.9971	0.0194	0.0005	3.458
Wang and Singh	a= -3.03×10^-5; b= 2.78×10^-10	0.9905	0.0355	0.0015	5.511
50 ºC (ethanol)
Henderson and Pabis	a= 1.08; k= 3.41×10^-5	0.9879	0.0432	0.0028	5.511	8.827
Logarithmic	a= 1.95; k= 1.38×10^-5; c= -0.89	0.9945	0.0291	0.0011	3.747
Midilli and Kuçuk	a= 1.04; k= 1.31×10^-5; n= 1.05; b= 5.23×10^-6	0.9946	0.0289	0.0016	3.867
Page	k= 6.68×10^-7; n= 1.38	0.9919	0.0353	0.0015	5.542
Parabolic	a= 1.05; b= 2.61×10^-5; c= 1.36×10^-10	0.9943	0.0295	0.0012	3.870
Two terms	a= 7.34; b = -6.29; k₀ = 5.87×10^-5; k₁ = 6.52×10^-5	0.9928	0.0333	0.0017	6.099
Wang and Singh	a= -2.13×10^-5; b= 4.28×10¹¹	0.9910	0.0372	0.0016	3.217

Treatment	AA [mg/ g (d. b.)]	pH [-]	TA [mg CA/g (d. b.)]
40 ºC (untreated)	0.689 ± 0.003 b	6.13 ± 0.04 a	0.174 ± 0.026 a
40 ºC (ethanol)	0.860 ± 0.002 a	6.11 ± 0.03 a	0.152 ± 0.013 a
50 ºC (untreated)	0.239 ± 0.002 c	6.09 ± 0.02 a	0.182 ± 0.022 a
50 ºC (ethanol)	0.683 ± 0.004 b	6.10 ± 0.04 a	0.175 ± 0.013 a
CV (%)	1.60	0.93	1.54

Brasil

Brasil

Ethanol pretreatment in taioba leaves during vacuum drying

Pré-tratamento com etanol em folhas de taioba durante secagem à vácuo

ABSTRACT

RESUMO

INTRODUCTION

MATERIAL AND METHODS

Sample preparation

Vacuum drying experiments

Drying kinetics and mathematical modeling

Drying behavior

Effective diffusivity determination

Empirical equations

Quality analyses

Total phenolic content

Antioxidant activity

Ascorbic acid

pH and titratable acidity

Statistical analyses

Statistical evaluation of the mathematical modeling

Statistical evaluation of the quality analysis

RESULTS AND DISCUSSION

Drying kinetic

Mathematical model

Quality analysis

CONCLUSIONS

AUTHORS CONTRIBUTION

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History