Evaluation and modeling of changes in shelf life,firmness and color of ‘Hass’ avocado depending on storage temperature

Abstract

In this study, ‘Hass’ avocado samples were stored at different temperatures to determine changes in firmness, color and other physicochemical support properties throughout the storage time and to represent shelf life depending on temperature from the evolution of these quality properties. From the experimental data, a set of models were adjusted to represent the change of each property as a function of time and temperature by using a first-order kinetics to represent the evolution of lightness (L*) and the chromatic coordinate b*, and a logistic equation to represent firmness and a*. The effect of temperature was represented by using Arrhenius equations. From the models of firmness and color, suitable equations were obtained to predict shelf life considering the relationship with the senescence stage (between 20 and 33 days). All the models were adjusted satisfactorily, obtaining regression coefficients higher than 0.95. In order to determine the predictive capacity of the proposed models, a validation experiment was carried out by storing fruits at 12 ℃ until reaching the senescence stage. With the models, it was possible to satisfactorily predict the changes in color and firmness and it was possible to estimate the shelf life time at 12 ℃ (28 ± 3.1 days).

Keywords

Predictive model shelf life time senescence color firmness

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References

Amodio

Derossi

Colelli

(2013) Modelling sensorial and nutritional changes to better define quality and shelf life of fresh-cut melons. Journal of Agricultural Engineering 43(4): 6, .

Amodio

Derossi

Colelli

(2017) Modeling shelf life of packaged, ready-to-eat fruits and vegetables with reference to the fate of nutritional compounds. In: Yahia

(ed) Fruit and Vegetable Phytochemicals, Chichester, UK: John Wiley & Sons, Ltd, pp. 833–856.

Carvalho

Bernal

Cartagena

VJR

et al. (2015) Fatty acid content of avocados (Persea americana Mill. cv. Hass) in relation to orchard altitude and fruit maturity stage. Agronomía Colombiana 33(2): 220–227.

Castellanos

Algecira

(2012) Modelling change in color and firmness of baby banana (Musa acuminata AA) in modified atmosphere packaging. Agronomia Colombiana 30(1): 84–94.

Castellanos DA, Mendoza R, Gavara R, et al. (2017). Respiration and ethylene generation modeling of “Hass” avocado and feijoa fruits and application in modified atmosphere packaging. International Journal of Food Properties 20(2): 333–349.

Castellanos

Polanía

Herrera

(2016) Development of an equilibrium modified atmosphere packaging (EMAP) for feijoa fruits and modeling firmness and color evolution. Postharvest Biology and Technology 120: 193–203.

Chen

Ramaswamy

(2002) Color and texture change kinetics in ripening bananas. LWT - Food Science and Technology 35(5): 415–419.

Defilippi

Ejsmentewicz

Covarrubias

et al. (2018) Changes in cell wall pectins and their relation to postharvest mesocarp softening of “Hass” avocados (Persea americana Mill.). Plant Physiology and Biochemistry 128: 142–151.

Do Nascimento Nunes

Nicometo

Emond

et al. (2014) Improvement in fresh fruit and vegetable logistics quality: Berry logistics field studies. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 372(2017): 20130307–20130307.

10.

Goulao

Oliveira

(2008) Cell wall modifications during fruit ripening: When a fruit is not the fruit. Trends in Food Science and Technology 19(1): 4–25.

11.

Hertog

MLATM

Nicholson

Jeffery

(2004) The effect of modified atmospheres on the rate of firmness change of ‘Hayward’ kiwifruit. Postharvest Biology and Technology 31(3): 251–261.

12.

Hertog

MLATM

Nicholson

Whitmore

(2003) The effect of modified atmospheres on the rate of quality change in ‘Hass’ avocado. Postharvest Biology and Technology 29(1): 41–53.

13.

Hess B, Ke D and Kader AA (1993) Changes in intracellular pH,ATP and glycolytic enzymes in ‘Hass’ avocado in response to low O2 and high CO2 stresses. Proceeding of Sixth International Controlled Atmosphere Research Conference. Ithaca, New York: Cornell University.

14.

Kang

Lee

(1998) A kinetic model for transpiration of fresh produce in a controlled atmosphere. Journal of Food Engineering 35(1): 65–73.

15.

Kassim

Workneh

Bezuidenhout

(2013) A review on postharvest handling of avocado fruit. African Journal of Agricultural Research 8(21): 2385–2402.

16.

Liu

Sievert

Arpaia

et al. (2002) Postulated physiological roles of the seven-carbon sugars, mannoheptulose and perseitol in avocado. Journal of the American Society for Horticultural Science 127(1): 108–114.

17.

Maftoonazad

Ramaswamy

(2008) Effect of pectin-based coating on the kinetics of quality change associated with stored avocados. Journal of Food Processing and Preservation 32(4): 621–643.

18.

Márquez

Yepes

Sanchez

et al. (2014) Cambios físico-químicos del aguacate (persea americana mill. cv. “hass”) en poscosecha para dos municipios de antioquia. Temas Agrarios 19(1): 32.

19.

Nambi

Thangavel

Shahir

et al. (2016) Color kinetics during ripening of indian mangoes. International Journal of Food Properties 19(10): 2147–2155.

20.

Nannyonga

Bakalis

Andrews

et al. (2016) Mathematical modelling of color, texture kinetics and sensory attributes characterisation of ripening bananas for waste critical point determination. Journal of Food Engineering 190: 205–210.

21.

Ochoa-Ascencio

Hertog

MLATM

Nicolaï

(2009) Modelling the transient effect of 1-MCP on ‘Hass’ avocado softening: A Mexican comparative study. Postharvest Biology and Technology 51(1): 62–72.

22.

Osuna-García

Doyon

Salazar-García

et al. (2010) Effect of harvest date and ripening degree on quality and shelf life of Hass avocado in Mexico. Fruits 65(6): 367–375.

23.

Ozdemir

Topuz

(2004) Changes in dry matter, oil content and fatty acids composition of avocado during harvesting time and post-harvesting ripening period. Food Chemistry 86(1): 79–83.

24.

Perez

Mercado

Soto-Valdez

(2004) Note. Effect of Storage Temperature on the Shelf Life of Hass Avocado (Persea Americana). Food Science and Technology International 10(2): 73–77.

25.

Salcedo

Quiñones

Melgarejo

et al. (2018) Variation in the fatty acid profile and quality of ‘Hass’ avocados preserved during cold storage. Acta Horticulturae 1194: 1007–1010.

26.

Santos

JCB

Vilas Boas

Prado

MET

et al. (2005) Avaliação da qualidade do abacaxi ‘Pérola’ minimamente processado armazenado sob atmosfera modificada. Ciência e Agrotecnologia 29(2): 353–361.

27.

Soliva-Fortuny

Grigelmo-Miguel

Odriozola-Serrano

et al. (2001) Browning evaluation of ready-to-eat apples as affected by modified atmosphere packaging. Journal of Agricultural and Food Chemistry 49(8): 3685–3690.

28.

Yang

Zhang

Joyce

et al. (2009) Characterization of chlorophyll degradation in banana and plantain during ripening at high temperature. Food Chemistry 114(2): 383–390.

29.

Zerbini

Vanoli

Grassi

et al. (2006) A model for the softening of nectarines based on sorting fruit at harvest by time-resolved reflectance spectroscopy. Postharvest Biology and Technology 39(3): 223–232.

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