Comparison of Different Techno-Functional Properties of Raw Lemon Pomace and Lemon Pomace Powder, and Development of Nutritional Biscuits by Incorporation of Lemon Pomace Powder

Lemon is one among the fruits of a highly respectable class known as citrus, well known for its nutritious juice and beverage products, rich with a range of micro and macro elements, and functional bioactives. After extraction of juice, the pomace left has great potential as a sustainable agricultural processing by-product, due to its vast application in the food, feed and pharma industries. Lemon pomace powder was prepared from the by-product obtained after the extraction of juice from the lemon. Dried lemon pomace powder contained fiber (60.12 g 100 g-1), moisture (10.67 g 100 g-1), protein (4.89 g 100 g-1), fat (2.17 g 100 g-1), sugar (4.81 g 100 g-1) and ash (3.21 g 100 g-1), indicating higher amounts of ash, fat and fiber contents than wheat flour. The water-holding and oil-holding capacities of lemon pomace powder were noticed 5.9 and 3.2 g, respectively. Lightness (L*) and yellowness (b*) of powder were decreased while redness (a*) was increased in powder as compared to raw pomace. Water activity was decreased, while dry matter and pH of pomace powder were significantly increased as compared to raw pomace. Microbiological analyses revealed lower mold, yeast and total viable counts in lemon pomace powder as compared to raw lemon pomace. Dried lemon pomace powder was replaced with wheat flour at concentrations of 0%, 5%, 10% and 15% in biscuits. The biscuits were evaluated for chemical and sensory properties. Data revealed that the incorporation of lemon pomace powder improved the chemical and sensory properties of biscuits significantly. Highly acceptable biscuits with good sensory properties were obtained by incorporating 10% lemon pomace powder, with the potential use of promoting health

Food Application of Orange Seed Powder through Incorporation in Wheat Flour to Boost Vitamin and Mineral Profiles of Formulated Biscuits

The significance of conducting research for its application has been noted as a result of the rising global food production and waste generation. As a result, there is increasing interest in fruits and vegetable seeds that contain bioactive chemicals, such as those that are obtained from orange seeds. In the current work, orange seed powder replaced wheat flour at 0, 2.5, 5, 7.5, and 10% levels, to observe changes in physicochemical features of developed biscuits. Proximate analysis of orange seed powder and wheat flour revealed that orange seed powder has high fat, fiber, protein, and ash contents as compared to wheat flour, whereas moisture contents in wheat flour were high. In developed biscuits, the highest values (percentage) of ash (9.68±0.04), fiber (6.79±0.12), protein (10.42±0.25), and fat (36.90±0.55) were found in biscuits developed with 10% orange seed powder. Orange seed powder was a comparatively good source of both macro and micro minerals, as compared to wheat flour. High contents of selenium (5.32±0.03), iron (2.12±0.05), zinc (3.88±0.12), and manganese (2.25±0.04) mg/100 g, present in orange seed powder, were the prominent findings of this research work, as wheat flours were observed to be deficient in these trace minerals. Contents of calcium, magnesium, potassium, zinc, manganese, zinc, and selenium in control biscuits were found 20.51±0.08, 17.29±0.04, 46.12±0.05, 1.06±0.01, 1.97±0.01, 0.12±0.01, and 0.11±0.01 mg/100 g, respectively, and replacement of wheat flour with 10% orange seed powder increased values of these minerals to 103.90±0.35, 44.35±0.50, 71.29±0.32, 2.59±0.4, 2.75±0.02, 1.31±0.01, and 2.02±0.05 mg/100 g, respectively. Vitamins E and K, which were not detected in wheat flour, were present in orange powder in high amount, whereas B group vitamins, which were also present in wheat flour, were observed in significantly high quantities in orange seed powder. Increment in vitamin A, D, E, K, and B complexes was significant as a result of orange seed powder supplementation, except for vitamins B1 and B2, which were slightly decreased. Sensory evaluation revealed that a 5% replacement of orange seed powder provided good quality biscuits with acceptable colour, flavor, taste, texture, and overall acceptability. Orange seed powder could prove an important ingredient in the baking industry with the potential of promoting the nutritional value of foods

Physical and Rheological Studies of Biscuits Developed with Different Replacement Levels of Pumpkin (Cucurbita maxima) Peel, Flesh, and Seed Powders

Several studies have been found in the literature about the phytochemistry, nutritional profiles, and pharmacological potential of pumpkin and pumpkin-based food products but a very few data have been found about the impact of the addition of pumpkin powders on physical and rheological behaviors of bakery products. The present research work was conducted to investigate that powder of which part of pumpkin and in what percentage could prove the most acceptable to develop good quality biscuits with optimum rheological and physical characteristics, which will be very useful to utilize pumpkin waste streams with effective and efficient mechanism for benefit of mankind in terms of development of new variety of bakery items. Peel, flesh, and seeds of pumpkin were utilized in the form of dried powder at 0, 5, 10, and 15% replacement levels to develop biscuits. Farinographic studies revealed that water absorption and dough development time were significantly increased to 65.69 ± 0.60% and 5.80 ± 0.012 min, respectively, at 15% pumpkin peel powder replacement, whereas dough stability was significantly decreased for 15% replacement level of pumpkin peel, flesh, and seed powders. Mixing tolerance index was significantly increased by these replacements. Mixographic studies revealed that mixing time of control dough was 3.55 ± 0.029 min, which was significantly decreased to 3.03 ± 0.015, 2.94 ± 0.023, and 3.23 ± 0.017 min for 15% replacement level of pumpkin peel, flesh, and seed powders, respectively. Similarly, peak height values were significantly decreased as replacement levels of pumpkin powders were increased up to 15%. Width and spread factor were significantly decreased, whereas thickness was significantly increased by these replacements. These replacements of pumpkin powders with white flour did not pose negative impact on rheological behavior of composite flours, which ultimately resulted in the development of improved quality biscuits

Physiological and biochemical variations of naturally ripened mango (Mangifera Indica L.) with synthetic calcium carbide and ethylene

Abstract To meet the increasing consumer demands for fruits, the implementation of artificial ripening techniques using synthetic chemicals has become increasingly commonplace among less ethical fruit production companies in today’s global market. The objective of present work was to establish a difference in the physiological and biochemical and profiles of naturally ripened mangoes vs. those ripened by application of synthetic calcium carbide and ethylene. The application of calcium carbide at 10 g/kg mangoes resulted early ripening in 2 days, with a 3-day shelf life, as compared with 5 and 6 days, for mangoes ripened by ethylene and naturally, respectively. Higher levels of calcium carbide reduced moisture, fiber, protein and carbohydrates content and increased the ash content of mangoes, as compared to higher levels of ethylene, whereas in naturally ripened mangoes the content percentages were 80.21, 3.57, 3.05 6.27 and 4.74, respectively. Artificial ripening resulted in significant loss of ascorbic, citric and malic acid, as values were recorded 35.94, 2.12 and 0.63 mg/g, respectively, in mangoes ripened with 10 g/kg of calcium carbide. However, in naturally ripened mangoes the amounts of these acids were recorded significantly (p < 0.05) high as 52.29, 3.76 and 1.37 mg/g, respectively. There was an increase in total soluble solids (TSS) and reducing sugars, and a decrease in titratable acidity in calcium carbide (10 g/kg) treated mangoes. Elemental analyses revealed high levels of minerals in naturally ripened mangoes, with significant values of iron (0.45 mg/100 g), zinc (0.24 mg/100 g) and copper (0.17 mg/100 g). The organoleptic quality of the fruit decreased significantly (p < 0.05) as a result of the use of calcium carbide. Although use of artificial ripening techniques provides speedy ripening of mangoes, there are obvious limitations. Consequently, natural ripening should be promoted in order to have safer and more nutritious mangoes