Extraction Methods for Obtaining Natural Blue Colorants

Background: Blue is a color not often present in food. Even so, it is especially attractive to children. Today, most blue coloring agents used by the food industry are synthetic. With increasing health issues concern by the scientific community and the general population, there is a trend to look for natural alternatives to most synthetic products. There only exist few natural blue colorants, which are presented in a literature survey, along with the methods currently used for their recovery from natural sources. The best extraction methods and process parameters for the extraction of blue anthocyanins, iridoids and phycocyanin are discussed. Methods: A literature survey was conducted to detect the main sources of blue colorants found in nature. The focus was on the extraction methods used to recover such molecules, with the objective of finding efficient and environmentally safe techniques for application at industrial level, and, thus, allowing the production of natural blue colorants at scale high enough for food industry consumption. Results: The main natural blue colorants found in literature are anthocyanins, phycocyanin, and genipin. While anthocyanins can be recovered from a variety of plants, the source of phycocyanin are algae, and genipin can be obtained specifically from Gardenia jasminoides Ellis and Genipa americana L. Several extraction techniques have been applied to recover blue colorants from such sources, from classical methods using organic solvents, to more sophisticated technologies as ultrasoundassisted extraction, supercritical fluid extraction, pressurized liquid extraction, high-pressure extraction, and enzyme-assisted extraction. Conclusion: There is great potential for anthocyanins, phycocyanin and genipin use as natural food additives with health benefits, besides imparting color. However, the technologies for the colorants recovery and application are not mature enough. Therefore, this area is still developing, and it is necessary to evaluate the economic feasibility of the proposed extraction processes, along with the safety and acceptance of colored food using these additives.

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Carotenoids: Source of Food Colour and its Benefits

International Journal for Modern Trends in Science and Technology - RTT2020 ◽

10.46501/ijmtst060707 ◽

2020 ◽

Vol 6 (7) ◽

pp. 42-51

Keyword(s):

Food Industry ◽

Food Additives ◽

Natural Food ◽

Allergic Reactions ◽

Bakery Products ◽

Food Industries ◽

Food Colorant ◽

Medicinal Value ◽

Food Colour ◽

Yellow Orange

Food colour or food additives are widely used in a food industries, to enhance the organoleptic (colour, flavour, appurtenance, taste and texture) quality to food. To protect and increase the shelf life of food, additives are incorporated into it, normally food additive or food colorant from synthetic origin are mostly used in food industry. Colours like yellow, orange, red, green etc. are highly preferred in soft drinks, candies, bakery products etc. which carries some adverse effects on human health such as allergic reactions, hyperactivity, carcinoma etc. An alternative is to use natural food colorant/additive from natural sources in the form of carotenoids which can be incorporated into food with medicinal value or health benefits.

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Extraction Methods of Oils and Phytochemicals from Seeds and Their Environmental and Economic Impacts

Processes ◽

10.3390/pr9101839 ◽

2021 ◽

Vol 9 (10) ◽

pp. 1839

Author(s):

Valerie M. Lavenburg ◽

Kurt A. Rosentrater ◽

Stephanie Jung

Keyword(s):

Food Industry ◽

Edible Oils ◽

Economic Impacts ◽

Extraction Methods ◽

Oil Extraction ◽

Economic Feasibility ◽

Soybean Plant ◽

Hemp Seed ◽

Advantages And Disadvantages ◽

Practical Standpoint

Over recent years, the food industry has striven to reduce waste, mostly because of rising awareness of the detrimental environmental impacts of food waste. While the edible oils market (mostly represented by soybean oil) is forecasted to reach 632 million tons by 2022, there is increasing interest to produce non-soybean, plant-based oils including, but not limited to, coconut, flaxseed and hemp seed. Expeller pressing and organic solvent extractions are common methods for oil extraction in the food industry. However, these two methods come with some concerns, such as lower yields for expeller pressing and environmental concerns for organic solvents. Meanwhile, supercritical CO2 and enzyme-assisted extractions are recognized as green alternatives, but their practicality and economic feasibility are questioned. Finding the right balance between oil extraction and phytochemical yields and environmental and economic impacts is challenging. This review explores the advantages and disadvantages of various extraction methods from an economic, environmental and practical standpoint. The novelty of this work is how it emphasizes the valorization of seed by-products, as well as the discussion on life cycle, environmental and techno-economic analyses of oil extraction methods.

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Agro-Food Byproducts as a New Source of Natural Food Additives

Molecules ◽

10.3390/molecules24061056 ◽

2019 ◽

Vol 24 (6) ◽

pp. 1056 ◽

Cited By ~ 37

Author(s):

Margarida Faustino ◽

Mariana Veiga ◽

Pedro Sousa ◽

Eduardo Costa ◽

Sara Silva ◽

...

Keyword(s):

Phenolic Compounds ◽

Circular Economy ◽

Food Production ◽

Food Industry ◽

Food Additives ◽

Food Additive ◽

Added Value ◽

Natural Food ◽

Secondary Products ◽

Functional Ingredients

Nowadays, the agro-food industry generates high amounts of byproducts that may possess added value compounds with high functionality and/or bioactivity. Additionally, consumers’ demand for healthier foodstuffs has increased over the last years, and thus the food industry has strived to answer this challenge. Byproducts are generally secondary products derived from primary agro-food production processes and represent an interesting and cheaper source of potentially functional ingredients, such as peptides, carotenoids, and phenolic compounds, thus promoting a circular economy concept. The existing body of work has shown that byproducts and their extracts may be successfully incorporated into foodstuffs, for instance, phenolic compounds from eggplant can be potentially used as a mulfitunctional food additive with antimicrobial, antioxidant, and food colorant properties. As such, the aim of this review is to provide insights into byproducts and their potential as new sources of foodstuffs additives.

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Natural food additives, ingredients and flavourings

10.1533/9780857095725 ◽

2012 ◽

Cited By ~ 11

Author(s):

David Baines ◽

Richard Seal

Keyword(s):

Food Additives ◽

Natural Food

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Different types of components obtained from Monascus purpureus with neuroprotective and anti-inflammatory potentials

Food & Function ◽

10.1039/d1fo01711j ◽

2021 ◽

Author(s):

Ho-Cheng Wu ◽

Yih-Fung Chen ◽

Ming-Jen Cheng ◽

Ming-Der Wu ◽

Yen-Lin Chen ◽

...

Keyword(s):

Food Additives ◽

Monascus Purpureus ◽

Natural Food ◽

Asian Countries ◽

Different Types ◽

Anti Inflammatory

The mold Monascus has been used as the natural food coloring agent and food additives for more than 1,000 years in Asian countries. In Chinese herbology, it was also used...

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Phycocyanin content and nutritional profile of Arthrospira platensis from Mexico: efficient extraction process and stability evaluation of phycocyanin

BMC Chemistry ◽

10.1186/s13065-021-00746-1 ◽

2021 ◽

Vol 15 (1) ◽

Author(s):

Sanghamitra Khandual ◽

Edgar Omar Lopez Sanchez ◽

Hugo Espinosa Andrews ◽

Jose Daniel Padilla de la Rosa

Keyword(s):

Storage Temperature ◽

Extraction Process ◽

Arthrospira Platensis ◽

Extraction Methods ◽

Precipitation Method ◽

Partial Purification ◽

Natural Food ◽

Solvent Ratio ◽

C Storage ◽

Dry Biomass

AbstractPhycocyanin is a blue natural food colorant with multiple health benefits. Here we propose an efficient phycocyanin extraction method from Arthrospira platensis from Mexico. Three extraction methods were applied to optimize the extraction process, using water and buffer as solvents, with three pH values at two agitation times. The highest phycocyanin, 54.65 mg/g, was extracted from dry biomass with water as a solvent using an ultrasonication bar. The optimum condition of extraction was determined to be 1:50 biomass/solvent ratio for dry biomass, with the freeze/thaw method for 20 min repeated twice, and then agitated at 120 rpm for 24 h. The phycocyanin content was 48.88 mg/g biomass, with a purity of 0.47. For scalable phycocyanin productivity, the sonication method is recommended as there is no statistical difference. The phycocyanin stability was best at − 20 °C storage temperature at pH 7 for 35 days. Partial purification with ammonium sulfate was found to be suitable as a fractional precipitation method, first at 0–20% and then 20–65%, to get purity nearly 1. Total protein was found to be 55.52%, and total amino acids after phycocyanin extraction was 33%. The maximum phycocyanin yield using water as a solvent was the most interesting result regardless of the method used for extraction.

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Processing Methodologies of Wet Microalga Biomass Toward Oil Separation: An Overview

Molecules ◽

10.3390/molecules26030641 ◽

2021 ◽

Vol 26 (3) ◽

pp. 641

Author(s):

Vânia Pôjo ◽

Tânia Tavares ◽

Francisco Xavier Malcata

Keyword(s):

Food System ◽

Lipid Extraction ◽

High Energy ◽

Economic Feasibility ◽

Alternative Source ◽

Microalgal Biomass ◽

Energy Demands ◽

Chemical Profiles ◽

System Sustainability ◽

Industrial Level

One of the main goals of Mankind is to ensure food system sustainability—including management of land, soil, water, and biodiversity. Microalgae accordingly appear as an innovative and scalable alternative source in view of the richness of their chemical profiles. In what concerns lipids in particular, microalgae can synthesize and accumulate significant amounts of fatty acids, a great fraction of which are polyunsaturated; this makes them excellent candidates within the framework of production and exploitation of lipids by various industrial and health sectors, either as bulk products or fine chemicals. Conventional lipid extraction methodologies require previous dehydration of microalgal biomass, which hampers economic feasibility due to the high energy demands thereof. Therefore, extraction of lipids directly from wet biomass would be a plus in this endeavor. Supporting processes and methodologies are still limited, and most approaches are empirical in nature—so a deeper mechanistic elucidation is a must, in order to facilitate rational optimization of the extraction processes. Besides circumventing the current high energy demands by dehydration, an ideal extraction method should be selective, sustainable, efficient, harmless, and feasible for upscale to industrial level. This review presents and discusses several pretreatments incurred in lipid extraction from wet microalga biomass, namely recent developments and integrated processes. Unfortunately, most such developments have been proven at bench-scale only—so demonstration in large facilities is still needed to confirm whether they can turn into competitive alternatives.

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Whole body metabolism is improved by hemin added to high fat diet while counteracted by nitrite: a mouse model of processed meat consumption.

Food & Function ◽

10.1039/d1fo01199e ◽

2021 ◽

Author(s):

Diana Abu Halaka ◽

Ofer Gover ◽

Einat Rauchbach ◽

Shira Zelber-Sagi ◽

Betty Schwartz ◽

...

Keyword(s):

High Fat Diet ◽

Food Industry ◽

Food Additives ◽

Whole Body ◽

Processed Meat ◽

Traditional Food ◽

High Fat ◽

Curing Agents ◽

Whole Body Metabolism ◽

Processed Meat Consumption

Nitrites and nitrates are traditional food additives used as curing agents in the food industry. They inhibit the growth of microorganisms and convey a typical pink color to the meat....

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Utilization and evaluation of Citrus natsudaidai peel waste as a source of natural food additives

Food Chemistry ◽

10.1016/j.foodchem.2021.131464 ◽

2021 ◽

pp. 131464

Author(s):

Yu Matsuo ◽

Kanako Akita ◽

Honoka Taguchi ◽

Shuji Fujii ◽

Yumiko Yoshie-Stark ◽

...

Keyword(s):

Food Additives ◽

Natural Food

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An integrated chemical and technological approach for assessing Portuguese wheat flours quality and lengthening bread shelf-life

Emirates Journal of Food and Agriculture ◽

10.9755/ejfa.2019.v31.i11.2037 ◽

2019 ◽

pp. 884

Author(s):

Fernando Cebola Lidon ◽

Diana Daccak ◽

Paula Scotti-Campos ◽

Maria Manuela Silva ◽

Ana Sofia Bagulho ◽

...

Keyword(s):

Shelf Life ◽

Large Scale ◽

Current Trend ◽

Food Additives ◽

Bread Making ◽

Technological Parameters ◽

Full Characterization ◽

Technological Approach ◽

Industrial Level

The current trend of large-scale bread production is to facilitate processing at an industrial level, considering the use of flour mixtures with different chemical and technological parameters and incorporating food additives. Accordingly, costs can be minimized, whereas the quality and the shelf-life of the final product might increase, but a full characterization of the flours that must be used and the selection of the food additives to be incorporated into the dough is required. In this context, three Portuguese wheat flour varieties were evaluated (FariRamos, Nacional and AJMiranda), as well as two types of food additives with the aim to increase bread shelf-life. In these flours, the levels of K, S, P, Ca and Cl prevailed, but the moisture and ash contents of FariRamos were the highest and lowest, respectively. The colour of all flours was generally within the desired standard values. Nacional flour contained a higher fat content, but all the flours showed a higher relative abundance of linoleic acid (C18:2), followed by palmitic acid (C16:0) and oleic acid (C18:1). AJMiranda flour revealed a higher content of wet gluten and protein, but the SDS sedimentation index showed a higher value in the FariRamos flour. The fall index, which directly monitors the activity of the α-amylase enzyme, showed a lower value in AJMiranda and Nacional. Through farinograph and alveographyc analysis it was found that FariRamos has a tenacious gluten, but AJMiranda and Nacional had a balanced gluten, yet all of them can be classified as medium flours. Bread making with a mix of FariRamos, AJMiranda and Nacional flours and incorporating preservative food additives revealed the highest shelf-life (11-days) with methyl p-hydroxybenzoate [0.05 %] and benzoic acid [0.1 %], but the colour of the breads showed a relationship of intensity of white colour that depended on the additive used. At the end of the shelf-life, molds of the Eurotium, Trichoderma and Cladosporium genera developed in the bread. It was concluded that the chemical and technological approach applied in the characterization of the flour varieties, can be directly used to define the quality and shelf-life in the bakery industry, allowing the establishment of minimum commercialization prices.

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