Index

ABSTRACT

The exploitation of cocoyam (Colocasia esculenta) for food is limited to direct consumption of primary products which often result in huge post-harvest losses. This study reports the development and storage of flour from cocoyam with the intent of establishing suitable storage conditions for its storage. Fresh cocoyam corms obtained from the Federal University of Technology (FUTA) Research Farm, were peeled, washed, sliced, oven-dried and then milled into the powder. Insights into the is essential to maintain Good keeping quality of food materials is a function of the relationship between their air relative humidity (expressed as water activity (aw)) and equilibrium moisture content. The gravimetric method was used to determine the adsorption isotherms of cocoyam flour. In the range of temperature (20 - 40 oC) and aw (0.10 - 0.80) typical of the tropical environment, different concentrations of concentrated acid (H2SO4) solutions were used to vary the condition of the research area. The experimental data were compared with six widely recommended models for food sorption isotherms (GAB, BET, Oswin, modified Oswin, Hasley & Smith). The plot of moisture sorption isotherms also resulted in a sigmoidal shape which is influenced by temperature variation. Generally, the Modified Oswin model was found most suitable to describe the sorption isotherm of cocoyam flour.

Keywords: Sorption, Cocoayam, Water activity, Gravimetric method.

DOI: 10.20448/803.4.2.200.207

Citation | Olumurewa J. A. V.; Olabinjo O.O.; Olaide, F. (2019). Sorption Characteristics of Cocoyam (Colocasia Esculenta) at Different Temperatures. Canadian Journal of Agriculture and Crops, 4(2): 200-207.

Copyright: This work is licensed under a Creative Commons Attribution 3.0 License

Funding : This study received no specific financial support.

Competing Interests: The authors declare that they have no competing interests.

History : Received: 15 August 2019 / Revised: 19 September 2019 / Accepted: 25 October 2019 / Published: 2 December 2019 .

Publisher: Online Science Publishing

Highlights of this paper

  • This study reports the development and storage of flour from cocoyam with the intent of establishing suitable storage conditions for its storage.
  • The Modified Oswin model was found most suitable to describe the sorption isotherm of cocoyam flour.

1. INTRODUCTION

In many developing countries of the world, roots and tubers such as cassava (Manihot esculenta), sweet potato (Ipomoea batatas), yam (Dioscorea sp), and cocoyams (Colocasia esculenta and Xanthosoma sagittifolium) are important household food security and income crops. Very good sources of starch and they satiate consumers. Predominantly, they are cultivated in West Africa and are important food crops for more than 400 million people worldwide [1, 2].

According to Enwere [3] corms and cormels can be eating cooked or pounded with cassava or yam to make fufu to be eaten with stew, also they are used as a thickener in soup preparation. The flours if precooked find good uses in pie filing, the binder in sausage and as emulsifiers in food stems [4]. Cocoyam is processed into chips for continuous food supply during the hunger periods. It was reported that the nutritional and chemical composition of cocoyam if duly utilized, would alleviate the problem of food insecurity in the tropics [5].

Some species of cocoyam contain high content of calcium oxalate crystals (780 mg per 100 g) and this has been responsible for the acridity or irritation caused by cocoyam. Oxalates tend to precipitate calcium and make it unavailable for use by the body. But this can be reduced by peeling, grating, soaking and fermentation processes [6].  Added to the problem of oxalate is that they are very susceptible to physical damage during harvesting which leads to high post-harvest losses.

According to Onyeike, et al. [7] corms and cormels will store well by processing them into flour, and according to Kwarteng and Towler [8] its flours can store much longer than the tubers of cocoyam. The knowledge of physical and other engineering characteristics of cocoyam will enhance its application in other food systems and improve its marketing potential. Cocoyam flour is good for making biscuits or as composites in bread production [9-11]. Apart from the consumption of various cocoyam foods, rural households also vend them as a way of coping with food insecurity. Advances in cocoyam processing and marketing could enable poor households in Nigeria to strengthen their food availability, storability, access and utilization [12].

Food sorption isotherm is the thermodynamic relationship between water activity (aw) and the equilibrium moisture content (EMC) of food product at constant temperature and pressure. According to Famurewa and Oladejo [13] this knowledge is highly important to Food Processing Engineers to design and optimize drying equipment and for quality, stability and shelf-life predictions. This study aims at studying how cocoyam can be made into flour to increase its utilization by predicting the suitable model for storage of cocoyam flour.

2. MATERIALS AND METHODS

In this study, the cocoyam cultivar was obtained from the University Research Farm. The chemical (concentrated H2SO4) was sourced from the Food Science and Technology Laboratory of the Federal University of Technology, Akure and was of analytical grade.

2.1. Sample preparation

Cocoyam tubers were washed with clean water, peeled with a clean stainless knife, and cut into slices using FUTA Slicing Machine. The sliced cocoyam was then oven-dried at a temperature of 60 oC until a constant weight was achieved. The dried cocoyam tubers were then milled with FUTA Plate Mill.

2.1.1. Humidity Control

The static gravimetric procedure as described by Oyelade, et al. [14] was employed in this study. At 20, 30 & 40 oC, varying measures of H2SO4  were mixed with deionized water to make up a 250 ml of desiccant to give water activities (aw) of 0.1, 0.20, 0.40, 0.60, 0.65, & 0.80, respectively. 20 grams of each of the cocoyam samples were put in a petri dish and the petri dish inside desiccators. The desiccators were placed in Genlab Incubator Model M75CPD (Genlab Ltd., Cheshire, England). to maintain the required temperature. Samples were being monitored in the incubator by weighing daily until constant weights were achieved. The equilibrium moisture contents of the equilibrated samples were determined on a dry basis [14]. The goodness of fit of the models was evaluated using three indicators namely: lowest of residual sum of squares (RSS) and standard error of estimate (SEE) and highest of the coefficient of determination (R2).

3. RESULTS AND DISCUSSION

Table 1 shows the values of equilibrium moisture contents at different water activities. The higher the water activities, the higher the equilibrium moisture contents and vice versa. Table 2 presents the model constant values for sorption isotherm of cocoyam flour at 20, 30 and 40 oC respectively. The goodness of fit of the models was evaluated using R2, RSS and SEE, and their values are as shown in Table 3. The indicators are determined as defined in Equation 1, Equation 2 and Equation 3.

Where:

Mcal = Calculated Equilibrium Moisture Content.

Mpred= Predicted Equilibrium Moisture Content.

df =     Degree of Freedom.

RES = Regression Error Sum of Squares.

TES = Total Error Sum of Squares.

Table-1. Equilibrium moisture contents obtained at different water activities.
Aw
EMC(20 0C)
EMC(30 0C)
EMC(40 0C)
0.1
0.027
0.024
0.02
0.2
0.047
0.044
0.037
0.4
0.07
0.063
0.059
0.6
0.095
0.078
0.076
0.8
0.12
0.098
0.093
Table-2. Model constant values for sorption isotherm of cocoyam flour at 20, 30 and 40 oc.
Temp
Gab
Bet
Oswin
M.Oswin
Hasley
Smith
20 oC
C= 30.042
Mo=0.0329
K= 0.8035
C= 40.581
Mo=0.0329
C=0.0736
n= 0.3566
a= 0.00198
b= 0.0035
C= 0.3566
C=0.00240
n = 0.0639
C= 0.0314
n= -0.056
30 oC
C= 21.046
K= 0.7190
Mo=0.0401
C= 28.046
Mo=0.037
C= 0.0655
n= 0.3163
a= 0.0015
b= 0.002
c= 0.3163
c=0.019
n= 0.0713
c=0.00310
n= -0.045
40 oC
C= 10.662
K= 0.612
Mo=0.04072
C= 12.908
Mo= 0.039
C= 0.0608
n= 0.3417
a= 0.0013
b= 0.0015
C = 0.341
C= 0.0017
n=0.00692
C=0.0262
n= -0.0457
Table-3. Coefficient of determination (R2), Standard error of estimate (SEE) and residual sum of square (RSS) of the sorption isotherm models of cocoyam flour.
Temp
 
Gab
Bet
Oswin
M.Oswin
Hasley
Smith
20 °C
R2
0.927
0.9493
0.9898
0.9898
0.8492
0.9761
RSS
0.017
0.00102
9.27E-05
9.27E-05
0.003099
0.00216
SEE
-0.01139
-0.008
7.37E-03
0.00022
-0.014
1.64E-09
30 °C
R2
0.8854
0.9317
0.9792
0.9797
0.7755
0.9554
RSS
0.0017
0.0012
0.00013
0.00013
0.00317
0.0029
SEE
-0.1149
0.00114
0.00032
0.00032
-0.0147
1.31E-09
40 oC
R2
0.9076
0.9626
0.9723
0.9723
0.7834
0.9479
RSS
0.0012
0.0012
0.00032
0.000173
0.00263
0.000319
SEE
-0.0948
0.00389
0.00044
0.00044
-0.01276
2.3E-05.

Figure 1 represents the sorption isotherm graph for cocoyam flour at 20, 30 and 40 oC. The moisture sorption isotherms have sigmoid shape profiles for all of the three temperatures.

The equilibrium moisture content (EMC) was observed to be increasing with an increase in water activity (aw). This finding agrees with the generally observed trend that the higher the value of aw the more the quantity of adsorbed moisture. This corroborates the observation that at higher aw, more water is available for binding at the active site of the solid. Many researchers have reported isotherms which followed this principle in the literature [15-22] .

To validate the suitable model, the calculated EMC at different aw determined were used against the predicted at the same aw to plot the adsorption isotherms shown in Figures 2 to 19. The isotherms followed the characteristic type II (sigmoid shape) classification of Brunamer reported by Oyelade [18]. This is typical of isotherms of products high in starch content as observed by Onayemi and Oluwamukomi [23] and Kumar, et al. [24].

Figure-1. Sorption isotherm graph for cocoyam flour at 20, 30 and 40 oC.
Figure-2. Oswin model validation at 20oC.   
Figure-3. Gab model validation at 20 oC.
Figure-4. Bet model validation at 20 oC.
Figure-5. M.Oswin model validation at 20 oC.
Figure-6. Hasley model validation at 20 oC.
Figure-7. Smith model validation at 20 oC.
Figure-8. Oswin model validation at 30 oC.
Figure-9. Gab model validation at 30 oC.
Figure-10. Bet model validation at 30 oC.
Figure-11. M.Oswin model validation at 30 oC.
Figure-12. Hasley model validation at 30 oC.
Figure-13. Smith model validation at 30 oC.
Figure-14. Oswin model validation at 40.
Figure-15. Gab model validation at 40 oC.
Figure-16. Bet model validation at 40.
Figure-17. M.Oswin model validation at 40 oC.
Figure-18. Hasley model validation at 40 oC.
Figure-19. Smith model validation at 40 oC.

4. CONCLUSION

The investigation of sorption isotherm of cocoyam flour unveiled sigmoid shape type II which is typical for most foods [18, 23, 25] . The equilibrium moisture contents for cocoyam flours decreased with an increase in temperature [18] and at low water small amount of water was absorbed into the active site but at high water activity, much more water was absorbed leading to a rapid increase in equilibrium moisture content. Comparing the experimental data at 20, 30  and 40 °C showed that the Modified Oswin model gave the best model for the cocoyam flour and the increasing temperature in the adsorption isotherm showed a decreasing in moisture content at a given water activity.

REFERENCES

[1]          C. Eze and E. Okorji, "Cocoyam production by women farmers under improved and local technologies in Imo State, Nigeria," African Journal of Science, vol. 5, pp. 113-116, 2003.

[2]          L. O. Sanni, O. O. Onadipe, P. Ilona, M. D. Mussagy, A. Abass, and A. G. O. Dixon, Successes and challenges of Cassava enterprise in West Africa: A case study of Nigeria, Benin, and Sierra Leone. Ibadan. Nigeria: International Institute of Tropical Agriculture, 2009.

[3]          N. J. Enwere, Foods of plant origin. Nsukka: Afro-Orbis Publications Limited, University of Nigeria, 1998.

[4]          T. N. Fagbemi and O. Olaofe, "Functional properties of raw and pre-cooked Taro (Colocasia esculenta) and Tannia (Xanthosoma saggitifolium) flours," in Proceedings. 22nd Annual NIFST Conference. Abeokuta, 1998, pp. 154-155.13.

[5]          A. Onasanya, A. Ayeleso, O. Adewale, E. Oluwaleye, E. Adewole, A. Ojo, and A. Afolabi, "Antioxidant potentials and fatty acid composition of Colocasia esculenta var. antiquorum," International Journal of Applied Research and Technology, vol. 4, pp. 3 – 7, 2015.

[6]          Food info.net, Tropical roots and tubers: Cocoyam. The Netherlands: Wageningen University, 2010.

[7]          E. N. Onyeike, E. O. Ayalogu, and S. G. Uzogara, "Influence of heat processing of African yam bean seed (Sphenostylis stenocarpa) flour on the growth and organ weights of rats," Plant Foods for Human Nutrition, vol. 48, pp. 85-93, 1995.Available at: https://doi.org/10.1007/bf01088303.

[8]          J. A. Kwarteng and M. J. Towler, West African agriculture. A textbook for schools and colleges. London: MacmillanPub, 1994.

[9]          M. Idowu, A. Oni, and B. Amusa, "Bread and biscuit making potential of some Nigerian cocoyam cultivars," Nigerian Food Journal, vol. 14, pp. 1-12, 1996.

[10]        L. U. Opara, Edible Aroids: Postharvest operation in: AGST/FAO: Dzanilo, M. (Ed.). New Zealand: Massey University, 2002.

[11]        M. Ojinnaka, E. Akobundu, and M. Iwe, "Cocoyam starch modification effects on functional, sensory and cookies qualities," Pakistan Journal of Nutrition, vol. 8, pp. 558-567, 2009.Available at: https://doi.org/10.3923/pjn.2009.558.567.

[12]        M. Dimelu, A. Okoye, B. Okoye, A. Agwu, O. Aniedu, and A. Akinpelu, "Determinants of gender efficiency of small-holder cocoyam farmers in Nsukka agricultural zone of Enugu State Nigeria," Scientific Research and Essays, vol. 4, pp. 028-032, 2009.

[13]        J. Famurewa and C. Oladejo, "Isotherm models of tacca starch (Tacca Involucrata) at ambient temperature using some common packaging materials," Journal of Engineering and Engineering Technology, vol. 10, pp. 74-82, 2016.

[14]        O. Oyelade, J. Igbeka, and O. Aworh, "Moisture isotherms of cowpea flour at 30° C and 40° C," Journal of Applied Sciences, vol. 4, pp. 1700-1711, 2001.

[15]        S. Kaya and T. Kahyaoglu, "Thermodynamic properties and sorption equilibrium of pestil (grape leather)," Journal of Food Engineering, vol. 71, pp. 200-207, 2005.Available at: https://doi.org/10.1016/j.jfoodeng.2004.10.034.

[16]        N. Arslan and H. Togˇrul, "Modelling of water sorption isotherms of macaroni stored in a chamber under controlled humidity and thermodynamic approach," Journal of Food Engineering, vol. 69, pp. 133-145, 2005.Available at: https://doi.org/10.1016/j.jfoodeng.2004.08.004.

[17]        S. Basu, U. Shivhare, and A. Mujumdar, "Models for sorption isotherms for foods: A review," Drying Technology, vol. 24, pp. 917-930, 2006.Available at: https://doi.org/10.1080/07373930601031711.

[18]        O. J. Oyelade, "Equilibrium moisture content models for Lafun," International Journal of Food Engineering, vol. 4, pp. 1- 17, 2008.

[19]        Z. Yan, M. J. Sousa‐Gallagher, and F. A. Oliveira, "Effect of temperature and initial moisture content on sorption isotherms of banana dried by tunnel drier," International Journal of Food Science & Technology, vol. 43, pp. 1430-1436, 2008.Available at: https://doi.org/10.1111/j.1365-2621.2007.01676.x.

[20]        J. Blahovec and S. Yanniotis, "Modified classification of sorption isotherms," Journal of Food Engineering, vol. 91, pp. 72-77, 2009.Available at: https://doi.org/10.1016/j.jfoodeng.2008.08.007.

[21]        A. Raji and J. Ojediran, "Moisture sorption isotherms of two varieties of millet," Food and Bioproducts Processing, vol. 89, pp. 178-184, 2011.Available at: https://doi.org/10.1016/j.fbp.2010.06.001.

[22]        S. Chowdhury, D. Sarker, T. Smith, P. Roy, and M. Wahid, "Effects of dietary tamarind on cholesterol metabolism in laying hens," Poultry Science, vol. 84, pp. 56-60, 2005.Available at: https://doi.org/10.1093/ps/84.1.56.

[23]        O. Onayemi and M. Oluwamukomi, "Moisture equilibria of some dehydrated cassava and yam products," Journal of Food Process Engineering, vol. 9, pp. 191-200, 1987.Available at: https://doi.org/10.1111/j.1745-4530.1987.tb00124.x.

[24]        A. Kumar, S. Des Etages, P. Coelho, G. Roeder, and M. Snyder, "High-throughput methods for the large-scale analysis of gene function by transposon tagging," Methods Enzymol, vol. 328, pp. 550-574, 2000.

[25]        J. Famurewa, M. Oluwamukomi, and J. Alaba, "Storage stability of pupuru flour (A Cassava Product) at room temperature," British Journal of Applied Science & Technology, vol. 2, pp. 138-145, 2012.Available at: https://doi.org/10.9734/bjast/2012/613.

Online Science Publishing is not responsible or answerable for any loss, damage or liability, etc. caused in relation to/arising out of the use of the content. Any queries should be directed to the corresponding author of the article.