Mathematical modeling and effect of thin-layer drying and lyophilization on antioxidant compounds from ultrasonic-assisted extracted <i>Muntingia calabura</i> peels

Tavone, Luciana Alves da Silva; Nascimento, Kauyse Matos; Fachina, Yasmin Jaqueline; Madrona, Grasiele Scaramal; Bergamasco, Rita de Cássia; Scapim, Mônica Regina da Silva

doi:10.4025/actasciagron.v43i1.50301

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CROP PRODUCTION • Acta Sci., Agron. 43 • 2021 • https://doi.org/10.4025/actasciagron.v43i1.50301 copy

Mathematical modeling and effect of thin-layer drying and lyophilization on antioxidant compounds from ultrasonic-assisted extracted Muntingia calabura peels

Authorship SCIMAGO INSTITUTIONS RANKINGS

ABSTRACT.

Muntingia calabura fruits are rich in bioactive compounds such as antioxidants, and the consumption of these compounds is associated with cancer prevention and aging. In this study, mathematical models were used to fit the experimental data of the Muntingia calabura peel drying kinetics, and the effective diffusion coefficient, activation energy and thermodynamic properties of the process were determined. Then, the effect of the drying temperature on the antioxidant activity and phenolic compounds of fruit peels was examined using conventional extraction and ultrasonication. Among the analyzed models, the logarithmic model was selected to represent the drying phenomenon of the calabura peel kinetics. The effective diffusion coefficient decreased by 74% as the temperature increased from 40 to 60°C, and the activation energy for liquid diffusion during drying was 23.96 kJ mol^-1. The enthalpy and entropy decreased with increasing temperature, while the Gibbs free energy increased by 5% for each 10°C increase in temperature. Regarding the content of phenolic compounds and the antioxidant activity of the calabura peel, it was observed that an increase in the drying temperature had a positive effect on the conservation of the bioactive compounds, making it possible to conclude that drying at 60°C and ultrasound extraction are the most suitable approach to conduct the process.

Keywords:
effective diffusion coefficient; lyophilized; bioactive compounds

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[1] * Author for correspondence. E-mail: luciana.alves.engali@gmail.com

Name of model	Mathematical expression.	References
Difussion Approach	MR = a exp(-kt) + (1-a) exp(-kbt)	(Akpinar, 2006Akpinar, E. K. (2006). Mathematical modelling of thin layer drying process under open sun of some aromatic plants. Journal of Food Engineering, 77(4), 864-870. DOI: 10.1016/j.jfoodeng.2005.08.014 https://doi.org/10.1016/j.jfoodeng.2005.... )
Two Term	MR = a exp(-k₁t) + b exp(-k₂t)	(Sharaf-Eldeen, Blaisdell, & Hamdy, 1980Sharaf-Eldeen, Y. I., Blaisdell, J. L., & Hamdy, M. Y. (1980). A model for ear corn drying. Transactions of the ASAE , 23(5), 1261-1265. DOI: 10.13031/2013.34757 https://doi.org/10.13031/2013.34757... )
Henderson & Pabis	MR = a exp(-kt)	(Henderson, 1974Henderson, S. M. (1974). Progress in developing the thin layer drying equation. Transactions of the ASAE, 17(6), 1167-1168. DOI: 10.13031/2013.37052 https://doi.org/10.13031/2013.37052... )
Logaritmic	MR = a exp(-kt) + c	(Kingsly, Goyal, Manikantan, & Ilyas, 2007Kingsly, R. P., Goyal, R. K., Manikantan, M. R., & Ilyas, S. M. (2007). Effects of pretreatments and drying air temperature on drying behaviour of peach slice. International Journal of Food Science & Technology , 42(1), 65-69. DOI: 10.1111/j.1365-2621.2006.01210.x https://doi.org/10.1111/j.1365-2621.2006... )
Midilli et.al. (2002Midilli, A., Kucuk, H., & Yapar, Z. (2002). A new model for single-layer drying. Drying Technology, 20(7), 1503-1513. DOI: 10.1081/DRT-120005864 https://doi.org/10.1081/DRT-120005864... )	MR = a exp(-ktⁿ) + bt	(Midilli et al., 2002Midilli, A., Kucuk, H., & Yapar, Z. (2002). A new model for single-layer drying. Drying Technology, 20(7), 1503-1513. DOI: 10.1081/DRT-120005864 https://doi.org/10.1081/DRT-120005864... )
Newton	MR = exp(-kt)	(Lewis, 1921Lewis, W. K. (1921). The rate of drying of solid materials. Journal of Industrial & Engineering Chemistry, 13(5), 427-432. DOI: 10.1021/ie50137a021 https://doi.org/10.1021/ie50137a021... )
Page	MR = exp(-ktⁿ)	(Page, 1949Page, G. E. (1949). Factors influencing the maximum rates of air drying shelled corn in thin layers. Retrieved on Aug. 8, 2019 from https://docs.lib.purdue.edu/dissertations/AAI1300089 https://docs.lib.purdue.edu/dissertation... )
Thompson	MR = exp(-a-(a²+4bt)^0,5/(2b))	(Thompson, Peart, & Foster, 1968Thompson, T. L., Peart, R. M., & Foster, G. H. (1968). Mathematical simulation of corn drying - A new model. Transactions of the ASAE , 11(4), 582-586. DOI: 10.13031/2013.39473 https://doi.org/10.13031/2013.39473... )
Valcam	MR = a + bt + ct^1,5 + dt²	(Madamba, Driscoll, & Buckle, 1996Madamba, P. S., Driscoll, R. H., & Buckle, K. A. (1996). The thin-layer drying characteristics of garlic slices. Journal of Food Engineering , 29(1), 75-97. DOI: 10.1016/0260-8774(95)00062-3 https://doi.org/10.1016/0260-8774(95)000... )
Verma	MR = a exp(-k₁t) ) + (1-a) exp(-k₂t)	(Lalit, Verma, Bucklin, Endan, & Wratten, 1985Lalit, R., Verma, L. R., Bucklin, R. A., Endan, J. B., & Wratten, F. T. (1985). Effects of drying air parameters on rice drying models. Transactions of the ASAE , 28(1), 296-301. DOI: 10.13031/2013.32245 https://doi.org/10.13031/2013.32245... )

Model Name	Drying temperatures
	40°C			50°C			60°C
	R²	χ²	RMSE	R²	χ²	RMSE	R²	χ²	RMSE
Difussion Approach	0.9989	0.00023	0.01503	0.9995	0.00012	0.01117	0.9979	0.00046	0.02155
Two Term	0.9996	0.00010	0.00989	0.9995	0.00012	0.02203	0.9985	0.00036	0.01897
Henderson e Pabis	0.9996	0.00009	0.00950	0.9995	0.00011	0.01043	0.9985	0.00031	0.01774
Logaritmic	0.9996	0.00009	0.00938	0.9997	0.00007	0.00863	0.9989	0.00025	0.01588
Midilli, Kucuk, and Yapar (2002Midilli, A., Kucuk, H., & Yapar, Z. (2002). A new model for single-layer drying. Drying Technology, 20(7), 1503-1513. DOI: 10.1081/DRT-120005864 https://doi.org/10.1081/DRT-120005864... )	0.9999	0.00003	0.00542	0.9998	0.00005	0.00696	0.9993	0.00017	0.01314
Newton	0.9989	0.00021	0.01442	0.9994	0.00012	0.01075	0.9979	0.00041	0.02024
Page	0.9996	0.00009	0.00927	0.9995	0.00011	0.01067	0.9983	0.00035	0.01879
Thompson	0.9992	0.00017	0.01292	0.9995	0.00012	0.01099	0.9980	0.00043	0.02079
Valcam	0.9998	0.00004	0.00650	0.9998	0.00004	0.00628	0.9994	0.00015	0.01205
Verma	0.9989	0.00023	0.01501	0.9995	0.00012	0.01117	0.9979	0.00046	0.02155

Propriedades termodinâmicas
Temperature (K)	ΔH (kJ mol^-1)	ΔS (kJ mol^-1 K^-1)	ΔG (kJ mol^-1)	Def (m² s^-1)
313.16	21.3607	-0.3399	127.4250	1.9164 x 10^-11
323.16	21.2775	-0.3402	131.1610	2.5447 x 10^-11
333.16	21.1944	-0.3404	134.8996	3.3302 x 10^-11

Extraction		Sample
Extraction		CD40	CD50	CD60	Lyophilized
Conventional	TPC	1,102.83 ± 87.37^bB	1,086.17 ± 5.77^bA	1,092.83 ± 81.29^bB	1,544.5 ± 207.85^aA
	ABTS	22.56 ± 2.07^bB	29.94 ± 1.99^bB	34.9 ± 0.94^abB	45.31 ± 1.5^aA
	FRAP	482.32 ± 39.81^cB	582.46 ± 12.96^cB	782.74 ± 45.4^bB	857.6 ± 95.34^aA
Ultrassound	TPC	1,322.83 ± 135.31^bcA	1,246.17 ± 60.48^cA	1,579.5 ± 43.3^aA	1,531.17 ± 87.8^abA
	ABTS	48.61 ± 1.1^bA	48.51 ± 9.6^bA	62.71 ± 10.22^aA	51.43 ± 4.39^abA
	FRAP	587.81 ± 27.53^cA	739.96 ± 65.74^bA	888.22 ± 33.71^aA	1,159.96 ± 6.68^aB