Received: 16/07/2019 Revised: 19/09/2019 Accepted: 20/09/2019 Online First: 04/10/2019
Abstract
Watermelon seeds are by-product of watermelon, rich in fat and proteins and normally discarded. The present research is planned to use watermelon seed flour as protein supplement in formulation of cookies at 0, 10, 20, 30 and 40% substitute with wheat flour. The results of the present study indicated that samples of watermelon seed flour added cookies contain more proteins (12.47%), fat (21.75%), ash (1.85%) and fibre (2.36%) as compared to cookies without watermelon seed flour samples, significantly. Addition of watermelon seed flour affects the physical parameters of cooking by decreasing the spread factor. However, panelists for sensory evaluation accept the cookies containing watermelon seed flour at all concentrations in terms of color, crispiness, flavor, texture and overall acceptability. So, watermelon seed flour can be used for preparation of cookies with improved protein, fat, fibre and ash content.
Keywords: Cookies; Physico-chemical parameters; Protein supplement; Sensory properties; Watermelon seed flour
Introduction
Watermelon (Citrullus lanatus) is a vine like drought annual flowering plant originated in Southern Africa. It is enriched with nutrients i.e. vitamin A, B6 and C, lycopene, antioxidants and amino acids. Its water content (92%) keeps hydrated and full of electrolytes which help to prevent from heat stroke. Pakistan ranks 30th in water melon production and its share is only 0.3% in the world. In Pakistan, utilization of water melon fruit is limited to the direct consumption of fresh fruits [1]. In food industry, water melon pulp is used for preparation of cocktails, juices and nectars. Processing of fruits and vegetables generate a large amount of residues which cause disposal and environmental problems. The rind and seeds are usually discarded. In some countries, rind is used as vegetable after cooking. Watermelon rind is also a rich source of natural fibre and studied to increase fibre content in cakes [2]. It is [3] also recommended to the use of watermelon rind powder to improve health promoting nutraceutial and functional properties for the production of cookies. On the other hand, watermelon seeds are rich in fats and proteins and can be added in different foods as a protein source and fat replacement [4].
Proteins from plant sources have been getting importance as their enrichment in food has been increasing among health conscious people and vegetarians [5]. However, it's needed that enrichment should not change functional and organoleptic characteristics of final product [6, 7]. In addition, these protein enriched product should meet consumer expectation in terms of satisfaction, nutrition and affordability [8].
Cookies are the most popularly consumed bakery items for all age groups due to affordable cost, ready to eat nature, good nutritional quality, longer shelf life and availability in different tastes [9]. So, the present study was planned to add watermelon seed flour as protein supplement in cookies and to evaluate its effect on physical, chemical and organoleptic acceptability of cookies.
Materials and methods
Preparation of watermelon seed flour
Watermelon seeds were purchased from local market, Sargodha, Pakistan, ground into powder and sieved to get powder with an average particle size of 65pm. Proximate composition of this powder was assessed by the methods described in AOAC [10]. Powder was then stored in polyethylene bags till further use.
Preparation of cookies
Cookies from wheat flour replacing watermelon seed flour at 0, 10, 20, 30 and 40% were prepared according to method No. 10-53.01 as described in AACC [11].
Physical analysis of cookies
Biscuits were evaluated for their physical parameters like diameter (mm), thickness (mm) and spread ratio (diameter/thickness) according to described method of AACC [11].
Chemical composition of cookies
Moisture, protein, fat, ash, fiber and NFE contents were determined according to the official methods of the AOAC [10]. All analysis were performed in triplicate.
Sensory evaluation of biscuits
Sensory evaluation was conducted using a semi-trained panel of twenty judges. Coded samples of cookies were presented to each of the judges and they were asked to assess the biscuits for color, texture, taste, aroma and overall acceptability according to the procedure described by [12].
Statistical analysis
Results obtained were subjected to analysis of variance (ANOVA) and the means were compared using LSD as described by [13].
Results and discussion
Proximate composition of watermelon seed flour
Table 1 shows the proximate composition of watermelon seed flour. The results obtained are similar to the results reported by [14, 15] who used watermelon seed powder for preparation of cookies and soup, respectively.
Physical properties of cookies
The effect of replacing 0, 10, 20, 30 and 40% of wheat flour with watermelon seed flour on physical properties of cookies was studied and the data are showed in (Table 2). The results revealed that all selected treatments caused significant decrease in diameter of cookies as compared to the control (59.67 mm) except 10% of watermelon seed flour added cookies given diameter significantly equal to control (57.33 mm). It was also clear that using watermelon seed flour at all levels in cookies preparations resulted in significant increase in thickness when compared with 7.50 mm for control. The higher thickness (14.5 mm) was recorded at 40% watermelon seed flour. Decrease in diameter in watermelon seed flour added cookies can be due to dilution of gluten. Concerning the spread ratio, it was observed that replacing wheat flour with watermelon seed flour decrease the spread ratio except of T1 where replacement is 10%. These results are in line with those obtained by [61]. It was [17] also reported that addition of apricot seed flour and fiber-rich fruit powders reduce the spread ratio values of cookies.
Chemical composition of cookies
Chemical composition of cookies prepared with watermelon seed flour by replacing wheat flour at 0, 10, 20, 30 and 40% showed that addition of watermelon seed flour increase fat, protein, fibre and ash content significantly as compared to control (Table 3). Lowest moisture content was observed in T0 (6.93%) and highest score was found in T4 (8.27). It was also reported that addition of mango peel and mango seed powder increased the moisture content in various samples [16]. Watermelon seed flour supplemented biscuits showed higher moisture content than control. This can be due to hygroscopic nature of seed flour. The highest fat content (21.75), protein content (12.47), fibre (2.30) and ash (1.85) was found to be in T4 (having 40% watermelon seed flour). As shown in (Table 1), watermelon seed flour contains fat 46.78, protein 26.37, fiber 4.10 and ash 3.73. Thus, the addition of watermelon seed flour increases this content in cookies. [18] reported that apricot kernel flour is high in proteins, fat and total dietary fibre and addition of this flour increase proteins, fat and dietary fiber in cookies. Similar findings were observed in biscuits prepared by adding mango peel and seed [19].
Sensory characteristics of cookies
The sensory parameter (color, crispiness, flavor, texture and overall acceptability) of the cookies supplemented with watermelon seed flour were and results are show in (Table 4). Color and crispiness of cookies prepared by replacing wheat flour with watermelon seed flour were improved while scores for flavor and texture were affected but still fall in the acceptable level in the nine-point hedonic scale. However, overall acceptability was not affected and remain non-significant in all samples with and without watermelon seed flour added cookies (p>0.05).
Results showed that texture was affected by addition watermelon seed flour. This can be due to increased water absorption which can result in harder texture. Results of sensory evaluation are similar to that of [16].
Conclusion
It is concluded that watermelon seed flour can be utilized successfully for the preparation of cookies with improved protein, fat, fiber and ash content without affecting the sensory acceptability of final product.
Authors' contributions
Conceived and designed the experiments: MT Hassan & T Kausar, Performed the experiments: MT Hassan, Analyzed the data: MT Hassan, T Kausar & GM Din, Contributed reagents / materials/ analysis tools: MT Hassan & T Kausar, Wrote the paper: T Kausar & MT Hassan.
Citation
Tusneem Kausar, Muhammad Tahir Hassan and Ghulam Mueen ud Din. Utilization of watermelon seed flour as protein supplement in cookies. Pure and Applied Biology. Vol. 9, Issue 1, pp202-206. http://dx.doi.org/10.19045/bspab.2020.90024
References
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Abstract
Watermelon seeds are by-product of watermelon, rich in fat and proteins and normally discarded. The present research is planned to use watermelon seed flour as protein supplement in formulation of cookies at 0, 10, 20, 30 and 40% substitute with wheat flour. The results of the present study indicated that samples of watermelon seed flour added cookies contain more proteins (12.47%), fat (21.75%), ash (1.85%) and fibre (2.36%) as compared to cookies without watermelon seed flour samples, significantly. Addition of watermelon seed flour affects the physical parameters of cooking by decreasing the spread factor. However, panelists for sensory evaluation accept the cookies containing watermelon seed flour at all concentrations in terms of color, crispiness, flavor, texture and overall acceptability. So, watermelon seed flour can be used for preparation of cookies with improved protein, fat, fibre and ash content.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer