Open access peer-reviewed chapter

Valorization of Prickly Pear [Opuntia ficus-indica (L.) Mill]: Nutritional Composition, Functional Properties and Economic Aspects

Written By

Francisca Hernández García, Lucia Andreu Coll, Marina Cano-Lamadrid, David López Lluch, Ángel A. Carbonell Barrachina and Pilar Legua Murcia

Submitted: 20 December 2019 Reviewed: 05 March 2020 Published: 31 March 2020

DOI: 10.5772/intechopen.92009

From the Edited Volume

Invasive Species - Introduction Pathways, Economic Impact, and Possible Management Options

Edited by Hamadttu El-Shafie

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Abstract

Opuntia ficus-indica (L.) Mill, usually named prickly pear or nopal cactus, is the Cactaceae plant with the greatest economic relevance in the world. It is a tropical or subtropical plant, native to tropical and subtropical America, which can grow in arid and semiarid climates. Prickly pear is mainly known by its fruits, popularly named “tunas” or “figs,” but their cladodes are also consumed, principally in Mexico, which is the country with the largest cultivated area and the largest producer. There is ample evidence of the health benefits of prickly pear: it shows high antioxidant activity, it is a source of nutrients and vitamins and it presents medicinal uses, among others. Furthermore, prickly pear presents other uses, including cosmetics, biofuel production, animal nutrition and soil phytoremediation.

Keywords

  • cactus pear
  • fruit
  • antioxidant activity
  • health benefits
  • peel
  • pulp

1. Introduction

Opuntia ficus-indica L. Mill, usually known as prickly pear, cactus pear or nopal, is a tropical or subtropical plant that belongs to the Cactaceae family, originally from arid and semiarid regions of America. This plant can grow in arid and semiarid climates, being the Cactaceae plant with the greatest economic relevance in the world [1]. It produces an edible and highly flavored fruit, known as “cactus pear,” which is a berry with numerous seeds and thick peel, enclosing a delicately flavored pulp [2]. Their cladodes are also consumed, mainly in Mexico, which is the country with the largest area under cultivation and the largest producer [3, 4] but it is also cultivated in the United States, Spain, Italy, South Africa and Argentina, among other countries [5, 6]. Prickly pear fruit is commonly consumed in fresh, but it can also be consumed as juices, jam, syrups and other processed products. They are widely employed in Latin America. The current demand of prickly pear in Spain is increasing [4, 6].

There are ample evidences of the health benefits of consumption of prickly pear due to its source of nutrients and vitamins [4, 7, 8] and antioxidant properties due to its content of bioactive compounds [2, 9, 10]. Additionally, prickly pear presents medicinal uses: it is used in treatment of hyperglycemia and high levels of cholesterol [7, 11, 12] and its consumption is linked with lower incidence of coronary diseases and some types of cancer [8, 13], among others.

This chapter is focused on the nutritional composition, bioactive compounds and economic aspects of prickly pear fruits through a compilation and synthesis of the available studies. With this, the authors intend to contribute to the knowledge of O. ficus-indica and also to promote new scientific research and industrial use of this crop.

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2. Nutritional composition

Table 1 shows nutritional composition of prickly pear pulp and peel. Prickly pear fruit pulp has high content of protein, lipids and moisture but low content of total fiber and ash comparing to the peel.

ConstituentsUnitPulpPeelReferences
Moisture%90.6688.92[15]
Titratable acidityg citric acid L −10.23–1.600.61–3.40[9]
Total soluble solids° Brix10.7–15.78.03–15.4[9]
pH5.41–6.014.83–5.59[9]
Energykcal 100 g−1 dw361169[17]
Protein% dw1.621.53[15]
Lipids% dw0.560.32[15]
Total fibers% dw4.655.83[15]
Ash% dw2.603.40[15]
Fructoseg L−157.8–88.027–81.8[9]
Glucoseg L−1103–14457–128[18]

Table 1.

Nutritional composition of prickly pear fruit pulp and peel.

About sugar profile, glucose and fructose are the predominant ones in both peel and pulp. On average, fruit pulp shows high content of glucose (123 g L−1) and fructose (71.7 g L−1) than peel (91.0 and 52.0 g L−1, respectively) [9].

Prickly pear fruit also stands out for its mineral contents. Potassium is the major macronutrient in pulp (199–410.7 mg 100 g−1 dw), followed by calcium (12.4–49.1 mg 100 g−1 dw) and magnesium (18 mg 100 g−1 dw). Fruit peel presents magnesium (18.6–987 mg 100 g−1 dw), calcium (49.04–951) and potassium (320–549 mg 100 g−1 dw) as the major macronutrients [14, 15]. Fruit pulp shows lower level of sodium (0.70–1.09 mg 100 g−1 dw) than peel (1.8–951 mg 100 g−1 dw) [14, 15, 16]. Iron, manganese and copper are the major microelements in fruit peel and pulp [14, 15]. The mineral pattern depends on the fruit origin and crop factors [15].

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3. Bioactive compounds

Table 2 shows the main bioactive compounds present in prickly pear fruit peel and pulp. These are betalains (betanin and indicaxanthin), flavonoids, phenolics, vitamin C and carotenoids.

CompoundsUnitPulpPeelReferences
Vitamin Cmg 100 g−1 fw28–79.259.8[2, 14, 19, 20]
Total flavonoidsmg rutin equivalents g−1 fw0.2–0.71.4–2.8[21, 22]
Total phenolic contentmg rutin equivalents g−1 fw2–2.55.4–6.2[21]
Carotenoidsμg g−1 fw2.56–3.7912.58–16.93[2, 6]
Indicaxanthinmg 100 g−1 fw2.61–39.6[19, 20]
Betaninmg 100 g−1 fw0.10–1.04[20]

Table 2.

Principal bioactive compounds in prickly pear fruit pulp and peel.

fw, fresh weight.

Betalains are water-soluble pigments (containing nitrogen) that are responsible for the red or yellow color of fruits, flowers, roots and leaves of plants belonging to the order of Caryophyllales, in which Cactaceae plants are included. [19]. Prickly pear fruits are characterized by various colors due to the combination of two betalain pigments, the purple-red betanin and the yellow-orange indicaxanthin [20]. These compounds make prickly pear fruits a good source of bioactive compounds with antioxidant properties, which may have beneficial effects on the consumer’s health [19].

Flavonoids are a group of secondary metabolites of plants implicated in fruit and flower coloration, photosensitization and energy transfer, among others. Flavonoids present high antioxidant activity that helps to neutralize damaging free radicals and to prevent oxidative stress in the human body [21, 22]. Prickly pear fruits contain more flavonoids in the peel than in the pulp and there are fewer flavonoids than phenolic compounds (Table 2) [21].

Vitamin C is an essential nutrient for humans that provides a high antioxidant activity and prevents against oxidative stress in humans [14, 20, 21]. The content of this vitamin depends on the cultivar among other factors, being higher in red cultivars, which show higher concentration of vitamin C than some common fruits such as apple, peach and grapes [2].

Carotenoids are organic pigments that belong to isoprenoid group and are widely distributed among fruits. They are responsible for most yellow, orange and red colors in vegetables. These pigments contribute to the appearance and attractiveness of a fruit. They can also perform as antioxidants [2, 6]. Concentration of carotenoids in prickly pear fruits is slightly lower than that reported for other fruits but it confirms the observation that yellow-colored fruits present higher concentrations than colored fruits [2].

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4. (Poly)phenols and phenolic profile

Polyphenols are an important group of natural compounds, founded in plants and characterized by the presence of more than one phenol group in their structure. These molecules are considered to be of high scientific and therapeutic interest, because they help to prevent degenerative diseases, cardiovascular diseases and cancers, among others, due to their antioxidant activity [21, 23].

In general, the peel of prickly pear fruits is richer than pulp in total phenolic content [21, 24, 25] (Table 2). The profile of individual (poly)phenolic compounds depends on the cultivar [18]. Generally, predominant compounds in prickly pear fruit pulp and peel are ferulic acid and derivatives, isorhamnetin and derivatives, sinapic acid and derivatives, and quercetin and derivatives [5, 18, 24]. Other compounds found in these botanical parts are kaempferol, myricetin, luteolin, catechin, naringin and syringaresinol, among others [5, 18, 24].

The presence of the phenolic compounds in prickly pear fruit peel and pulp, due to its antioxidant activity, makes this fruit an important product that can contribute to prevent human degenerative diseases such as cancer, diabetes, hypercholesterolemia, arteriosclerosis or cardiovascular and gastric diseases [21, 25]. Table 3 shows some compounds found in the most recent studies [5, 18, 26] about phenolic profile of prickly pear fruit peel and pulp.

CompoundPulp [18]Peel [18]Pulp [5]Peel [5]Pulp and peel [26]
Protocatechuic acid-hexosidexx
Piscidic acidxxx
Caffeic acid 4-O-glucuronidex
4-Hydroxybenzoic acid derivativexx
p-Coumaric acid 4-O-glucosidex
Myricetin-hexosidexx
Ferulic acid derivativexxx
Ferulic acid-hexosidexx
Guaiacyl(t8-O-4)guaiacyl-hexosidexx
Sinapic acid-hexosidexx
Syrinigyl(t8-O-4)guaiacylxx
Quercetin-hexoside-pentosidex
Quercetin-rhamnose-hexoside-
rhamnose
x
Rutin-pentosidex
Syrinigyl(t8-O-4)guaiacylx
Kaempferol-di-rhamnose-hexosidex
Kaempferol-glucosyl-rhamnosidexxx
Kaempferol 3-O-(2”rhamnosyl-galactoside)7-O rhamnosidex
Taxifolinx
Isorhamnetin-rhamnose-
rutinoside
xx
Isorhamnetin glucosyl-rhamnosyl-
rhamnoside
xx
Isorhamnetin glucosyl-pentosidexx
Isorhamnetin glucosyl-rhamnosidexxx
Quercetin-hexoside-pentosidexx
Isorhamnetin derivativexx
Dihydrosinapic acid hexosidexx
Quercetin-3-O-rutinoside (rutin)xxx
Secoisolariciresinol-hexosidexx
Quercetin-hexosidexx
Kaempferol-rutinosidex
Syringaresinolxx
Naringenin-hexosidexx
Isorhamnetin-rutinosidexx
Isorhamnetin-3-O-glucosidex
Isorhamnetin diglucosidex
Isorhamnetin-C-hexosidex
Eucomic acidx
Naringinxx
Guaiacyl(8-O-4) syrinigyl (8-8) guaiacyl-hexosidexx
Feruloyl derivativex
Trihydroxy-methoxy-flavonolxx

Table 3.

Phenolic compounds found in prickly pear fruit peel and pulp in the most recent studies.

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5. Sugars and organic acid composition

Citric and malic acids are the major organic acids present in prickly pear fruit pulp and peel. Other organic acids, such as oxalic, tartaric, quinic, shikimic and fumaric acids, are present in traces. Citric acid ranges from 1.60 to 3.20 g L−1 in fruit peel and shows values from 0.30 to 1.61 in pulp g L−1 [9]. Malic acid shows concentrations between 1.04 and 2.20 g L−1 in peel and 1.20 and 2.10 g L−1 in pulp. However, cladodes show higher values of these acids (71.8 g L−1 of malic acid and 37.7 g L−1 of citric acid) and also contain succinic acid (43 g L−1) [9]. This is due to the CAM metabolism of O. ficus-indica, especially in the cladodes. Organic acids are accumulated in the vacuole during night and suffer a reciprocal reserve carbohydrates accumulation during the daytime phase [27].

Organic acids in fruits are in lower concentration in comparison with cladodes; however, fruits, especially pulp, are characterized by high sugar content. Some authors [9] studied the concentration of glucose and fructose in fruits and their results show that glucose predominates over fructose in both fruit peel and pulp (123 g L−1 of glucose and 91 g L−1 of fructose in pulp versus 91 g L−1 of glucose and 52 g L−1 of fructose in fruit peel). However, other studies [28] show that glucose, fructose and sucrose concentration is higher in fruit peel than in pulp. These results indicate that concentration of sugars may depend on the cultivars.

Sugar concentration in prickly pear fruit makes it a good source of energy and a natural source of sweetness for food preparations. Besides, fructose contributes to the typical sweet taste of this fruit, due to its high wetness compared with glucose and sucrose [29].

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6. Volatile compounds

Volatile compounds influence the sensory quality of fruits. Their aromas are formed from a complex group of chemical substances such as aldehydes, alcohols, ketones, terpenes and esters, among others. These compounds usually show a low concentration in fruits and their variability depends on cultivar, climatological conditions, maturity and storage conditions, among other factors [30]. In prickly pear fruit pulp, the content of these compounds varies from 3.33 mg 100 g−1 to 14.86 mg 100 g−1 [31].

Even though prickly pears have no strong aroma, up to 61 compounds have been identified [32]. In a recent research [31], the studied cultivars showed aldehydes and terpenes as the most numerous compounds. Both chemical groups and alcohols were the most abundant compounds. However, other studies reported alcohols [32, 33, 34] and esters [35] as the most numerous and abundant compounds. Some predominant compounds are D-limonene (citrus notes), 2,6-nonadienal (vegetable notes), nonanol (green, melon and fatty attributes), 2-hexenal (almond, apple green, sweet and vegetable notes), and 1-hexanol (green and sweet notes), among others [31, 32, 33].

Although prickly pear fruits are highly valued for their health-promoting benefits, sensory analysis is needed to complete the knowledge of aroma of this fruit and the effect of the cultivar [31].

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7. Fatty acids

The consumption of monounsaturated and polyunsaturated fatty acids (MUFAs and PUFAs, respectively) has been stated to provide health benefits. It also contributes to the improvement of various health conditions regarding obesity, cardiovascular diseases, diabetes mellitus and even some types of cancer [13, 36].

Prickly pear fruit pulp and peel showed important percentages of MUFAs and PUFAs. In fruit pulp, MUFAs ranged from 16.9 to 40.2% (as % of total of fatty acid profile) and PUFAs ranged from 35.2 to 53.9%. Fruit peel showed slightly lower values of MUFAs (6.90–31%) but higher ones in PUFAs (37.0–63.2%) [37]. Furthermore, prickly pear seed oil showed high percentages of PUFAs, recorded at levels between 57.90 and 63.29%, and MUFAs, ranged from 19.81 to 23.30% [38].

The most abundant compounds in fruit pulp, peel and seed oil were linoleic (C18:2), oleic (C18:1) and palmitic (C16:0) acids [15, 37]. Prickly pear fruit peel showed higher percentages of linoleic acid than fruit pulp (41.2 and 29.2% respectively), but pulp presented higher percentages of oleic acid than peel (26.8% in pulp and 14.4% in peel). Both peel and pulp showed similar percentages of palmitic acid [37].

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8. Health benefits: antioxidant activity

Antioxidant activity is one of the major mechanisms by which fruits and vegetables provide health benefits. Fruits and vegetable are also able to inhibit excessive oxidation due to free radicals, which are in the form of reactive oxygen species [9]. Prickly pear is rich in antioxidant product, containing phenolic compounds, carotenoids, betalains and vitamin C, all of which could be directly responsible for the health benefits [39]. Antioxidant activity in prickly pear fruit and peels may be affected by environmental factors, cultivar, genetic diversity, phenotype, agronomic practices, environmental and climatic conditions and processing of the fruit, among others [40]. Besides, the processing method and the extraction solvent affect antioxidant activity of O. ficus-indica extracts [26].

Antioxidant activity can be measured by different methods depending on the various mechanisms of antioxidant action. For example, some authors [2, 6, 8, 9, 10, 26, 41] studied antioxidant activity by DPPH, ABTS·+, FRAP and ORAC methods. DPPH method consists in the elimination of DPPH radical by antioxidant compounds present in the extracts, which determines its ability to capture radicals. The ABTS method captures the cationic ABTS·+ radical. FRAP method measures the ability to reduce Fe3+ in the sample. ORAC method measures the ability of the sample to scavenge peroxyl radicals.

Table 4 shows the antioxidant activity of O. ficus-indica depending on the method and the part analyzed (pulp and peel). The scavenging activity of DPPH, ABTS·+ and FRAP methods is higher in fruit peel. This trend can be observed in other fruits like pomegranate [42], guava fruit [43] and berries [44]. The consumption of fruits with high antioxidant activity, such as prickly pear fruits, is related to preventing degenerative diseases such as cancer, diabetes, hypercholesterolemia, arteriosclerosis or cardiovascular and gastric diseases [21, 25].

MethodUnitPulpPeelReferences
ABTSmmol Trolox kg−1 dw6.40–30.614.7–36.9[9]
μmol Trolox g−1 fw6.70[10]
DPPHmmol Trolox kg−1 dw58.4–60.154.8–59.6[9]
μmol Trolox 100 g−1 fw108.85–122.47141.60–141.80[6]
FRAPmmol Trolox kg−1 dw15.0–32.340.2–116[9]
μmol Fe (II) g−1 dw18.42–137.6558.70–175.44[26]
ORACmmol kg−1 fw3.68–8.16[41]
μmol Trolox g−1 fw26.3[2]

Table 4.

Antioxidant activity of prickly pear fruit pulp and peel by different methods.

dw, dry weight; fw, fresh weight.

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9. Processed products

One of the oldest ways to preserve highly perishable fruits is through different processing systems. Although it is necessary to do more research in preservation of prickly pear fruit and use it out of the harvest period, there are some processed products obtained from prickly pear fruit. The main ones are juices and nectars, marmalades and jams, dehydrated sheets, sweeteners, alcohol and wines [29, 45].

Juices and nectars from prickly pear fruit are mostly water. They contain appreciable amounts of sugars, vitamins and mineral salts (mainly potassium, calcium and sodium). They also are a good source of bioactive substances such as phenolic compounds, betalains, vitamin C and β-carotene. These products show different percentages of fruit pulp (15–75%), citric acid (0.3%), sucrose and water [45, 46].

Marmalades and jams are usually prepared from ripe fruits with high sugar content. In their manufacturing, it is important to control the sugar/pulp ratio, type and quantities of acidifying agents and the percentage of added pectin (thickening agent). Prickly pear fruit pulp already contains pectin, responsible for the viscosity of the pulp, which is a positive element toward the production of juices, marmalades and jams [45, 47].

Regarding prickly pear dehydrated sheets, there are different formulations and methods for their elaboration, mixing pulp in different sucrose ratios (0–10%). The thickness of the sheets is usually 5–15 mm. The preparations need to be spread and then dried at 60–70°C for at least 44 hours. Some authors mix prickly pear pulp with other fruits, like quince or melon pulps [45, 48, 49].

Sweetener liquid preparation from prickly pear fruit pulp implies enzymatic clarification of pulp juice, its decoloration and its vacuum concentration until 60°Brix (56% of glucose, 44% of fructose approximately). The obtained product shows a density and water activity similar to that of honey and marmalades and its characteristics are similar to other sweetener liquids currently marketed [45, 50].

Alcoholic beverages from O. ficus-indica are less known than those from other processed products. Some authors, for obtaining prickly pear wine, inoculated their juice with Saccharomyces cerevisiae and added SO2 (10 mg L−1) and citric acid for obtaining a pH 3.3, and then performed fractional distillation [51]. Besides, prickly pear fruit pulp can be added to other alcoholic beverages such as yakju, increasing the levels of alcohol, sugars and antioxidant activity [52].

Prickly pear seed oil is another potential product that can be obtained during fruit processing. Linoleic acid is the main fatty acid, and the percentages of PUFAs and MUFAs reach 63.29 and 23.30%, respectively [38]. Besides, other physical and chemical characteristics, such as refractive index, iodine number and saponification number, make it similar to other vegetable oils such as corn or grape seed oil [45].

  1. Economic evaluation of prickly pear fruit production

Nowadays, O. ficus-indica cultivation is developed in at least 18 countries in arid and semiarid areas. The extension of this crop is more than 100,000 ha [53]. This does not include naturalized plants or plants cultivated for home consumption.

Prickly pear has been used since the sixteenth century as an important subsistence crop in many communities of Africa, Asia, Europe and America, although fruit consumption remains limited to local ethnic markets and there is little export. Only Mexico, Italy, Chile, South Africa and Argentina produce cactus pear in a commercial way [3].

Mexico is the world’s largest producer of prickly pear, accounting for 45% of world production [3, 4]. Other important producing countries of prickly pear are Italy (12.2%) and South Africa (3.7%). The rest of the production is in Argentina, Chile, Bolivia, Peru, Colombia, United States of America, Morocco, Algeria, Libya, Tunisia, Egypt, Jordan, Pakistan, Israel, Greece, Spain and Portugal [3, 4].

Regarding Mexico, the planted area covers around 50,000–70,000 ha and the gross annual production is 300,000–500, 000 tones. It is the fifth fruit crop in the country and about 20,000 families obtain some income from cactus pear cultivation. Vegetable production, featured by small plots of land cultivation, supposes an additional 12,000 ha of cultivated area [54]. In this country, the cultivation of prickly pear presents the advantage that it produces employment and income in areas where few other crops can be produced [55].

Italy is the second world producer and the principal world exporter of cactus pear, mostly concentrated (96%) in Sicily with 7000–8300 ha producing about 78,000–87,000 tones per year [55]. South Africa’s 1500 hectares produces about 15,000 tones. Other countries where cactus pear is cultivated are South Africa (1500 ha, 15,000 tones of fruit production), Argentina (1650 ha), Brazil (500,000 ha), Chile (934 ha), Peru (5000 tones of fruit production) and California (120 ha) [4]. However, it is difficult to quantify areas and production of prickly pear crop because it is a crop with low economic and social importance in most of the countries, so that there are not consistent economic data about it [4].

In Mexico, the main producer, the average production is approximately 12.8 t ha−1 (400 crates), which are sold at an average price of 3.2 euros each crate. This gives a total of 1280 euros per hectare, and the profit is approximately 340 per hectare, because the costs of tools, weeding, pruning, fertilization, fumigation, harvest and transport, among others [56]. In the case of Italy, the average production is approximately 15.1 t ha−1, the incomes are 5.71 euros per hectare on average and the average profit per hectare is 1658.88 euros [55, 57]. In Spain, average production per hectare is 234 t ha−1, and the average price is 1.42 euros per kilogram. Prices depend on the moment of the season and go from 1.8 euros per kilogram to 1.05 euros. This implies an average income of 555, 254.7 euros per hectare. So, average profit is 545, 801 euros per hectare.

Besides, prickly pear fruits show a high amount of compounds with biofunctional, nutraceutical and cosmetic properties, above crops like Opuntia joconostle, Ziziphus jujube, Stenocereus pruinosus, Stenocereus stellatus and Punica granatum [58, 59, 60, 61]. However, no economic value analysis of the cactus pear cultivation based on obtention of these biofunctional, medicinal, nutraceutic and cosmetic compounds has been done. These compounds reach a value in the marketplace of 213.68 € per 20 mg in the case of kaempferol or 204.53 € per 10 mg in the case of isorhamnetin, and both are present in prickly pear fruit, among others.

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10. Other aspects

Besides the health benefits of fruit consumption, O. ficus-indica presents other multiple applications in different areas:

  • There are studies about the antigenotoxic capacity of the cladodes against mycotoxin zearalenone (mycotoxin F-2, produced by some species of Fusarium) in mice [62, 63].

  • Cladodes of O. ficus-indica could be used to produce biofuels, specifically bioethanol and biogas [64, 65].

  • Due to its clotting power, cladodes could be used as a natural coagulant to remove turbidity and color in raw waters, with a yield of 65 g of coagulant per kg of cladodes [66].

  • Some studies showed that supplementing the feeding of goats with cladodes and fruit peels may be an important resource to reduce their water intake, without detrimental effects on digestion, growth and meat quality [67, 68].

  • Pigments of red and purple prickly pear cultivars could be used in food industry as additives in products like sweets, desserts and dairy products. These additives were obtained by microencapsulation technique of betalains [69, 70].

  • Due to its Crassulacean acid metabolism (CAM), O. ficus-indica has been studied for its ability of endure prolonged drought and CO2 uptake, which can help to mitigate effects caused by desertification and global climatic change [71, 72].

  • O. ficus-indica could be used in phytoremediation of contaminated soils with Se, Pb and other contaminant substances [73, 74].

References

  1. 1. Kiesling R. Origen, domesticación y distribución de Opuntia ficus-indica. Journal of the Professional Association for Cactus Development. 1998;3:50-59
  2. 2. Kuti JO. Antioxidant compounds from four Opuntia cactus pear fruit varieties. Food Chemistry. 2004;85(4):527-533
  3. 3. Reyes-Agüero JA, Aguirre JR, Carlín-Castelán F, González-Durán A. Diversity of wild and cultivated opuntia variants in the meridional highlands plateau of Mexico. Acta Horticulturae. 2013;995:69-74
  4. 4. FAO, Food and Agricultural Organization. In: Inglese P, Mondragon C, Nefzaoui A, Saenz C, editors. Ecologia del cultivo, manejo y usos del nopal. Roma, Italy: FAO; 2018. pp. 1-174
  5. 5. García-Cayuela T, Gómez-Maqueo A, Guajardo-Flores D, Welti-Chanes J, Cano MP. Characterization and quantification of individual betalain and phenolic compounds in Mexican and Spanish prickly pear (Opuntia ficus-indica L. mill) tissues: A comparative study. Journal of Food Composition and Analysis. 2019;76:1-13. DOI: 10.1016/j.jfca.2018.11.002
  6. 6. Cano MP, Gómez-Maqueo A, García-Cayuela T, Welti-Chanes J. Characterization of carotenoid profile of Spanish Sanguinos and Verdal prickly pear (Opuntia ficus-indica, spp.) tissues. Food Chemistry. 2017;237:612-622. DOI: 10.1016/j.foodchem.2017.05.135
  7. 7. Cherkaoui-Malki M, Nasser B, El Kebbaj M, Badreddine A, Latruffe N, El-Mostafa K, et al. Nopal Cactus (Opuntia ficus-indica) as a source of bioactive compounds for nutrition. Health and Disease. Molecules. 2014;19(9):14879-14901
  8. 8. Feugang JM. Nutritional and medicinal use of Cactus pear (Opuntia spp.) cladodes and fruits. Frontiers in Bioscience. 2007;11(1):2574
  9. 9. Andreu L, Nuncio-Jáuregui N, Carbonell-Barrachina ÁA, Legua P, Hernández F. Antioxidant properties and chemical characterization of Spanish Opuntia ficus-indica Mill . cladodes and fruits. Journal of the Science of Food and Agriculture. 2017;98:1566-1573
  10. 10. Fernández-López JA, Almela L, Obón JM, Castellar R. Determination of antioxidant constituents in cactus pear fruits. Plant Foods for Human Nutrition. 2010;65(3):253-259
  11. 11. Frati AC, Jiménez E, Ariza CR. Hypoglycemic effect of Opuntia ficus indica in non insulin-dependent diabetes mellitus patients. Phytotherapy Research. 1990;4(5):195-197
  12. 12. Ennouri M, Fetoui H, Bourret E, Zeghal N, Guermazi F, Attia H. Evaluation of some biological parameters of Opuntia ficus indica. 2. Influence of seed supplemented diet on rats. Bioresource Technology. 2006;97(16):2136-2140
  13. 13. Serra AT, Poejo J, Matias AA, Bronze MR, Duarte CMM. Evaluation of Opuntia spp. derived products as antiproliferative agents in human colon cancer cell line (HT29). Food Research International. 2013;54(1):892-901. DOI: 10.1016/j.foodres.2013.08.043
  14. 14. El-Said NM, Ashraf IN, Sahar AR, Deraz SF. Prickly pear [Opuntia ficus-indica (L.) mill] peels: Chemical composition, nutritional value and protective effects on liver and kidney functions and cholesterol in rats. Functional Plant Science and Biotechnology. 2011;5:30-35
  15. 15. El-Beltagi HS, Mohamed HI, Elmelegy AA, Eldesoky SE, Safwat G. Phytochemical screening, antimicrobial, antiaxidant, anticancer activities and nutritional values of cactus (Opuntia ficus indicia) pulp and peel. Fresenius Environmental Bulletin. 2019;28(2):1545-1562
  16. 16. Salim N, Abdelwaheb C, Rabah C, Ahcene B. Chemical composition of Opuntia ficus-indica (L.) fruit. African Journal of Biotechnology. 2009;8(8):1623-1624
  17. 17. Garcia-Amezquita LE, Tejada-Ortigoza V, Heredia-Olea E, Serna-Saldívar SO, Welti-Chanes J. Differences in the dietary fiber content of fruits and their by-products quantified by conventional and integrated AOAC official methodologies. Journal of Food Composition and Analysis. 2018;67:77-85
  18. 18. Mena P, Tassotti M, Andreu L, Nuncio-Jáuregui N, Legua P, Del Rio D, et al. Phytochemical characterization of different prickly pear (Opuntia ficus-indica (L.) Mill.) cultivars and botanical parts: UHPLC-ESI-MSn metabolomics profiles and their chemometric analysis. Food Research International. 2018;108:301-308
  19. 19. Albano C, Negro C, Tommasi N, Gerardi C, Mita G, Miceli A, et al. Betalains, phenols and antioxidant capacity in cactus pear [Opuntia ficus-indica (L.) mill.] fruits from Apulia (South Italy) genotypes. Antioxidants. 2015;4(2):269-280
  20. 20. Butera D, Tesoriere L, Di Gaudio F, Bongiorno A, Allegra M, Pintaudi AM, et al. Antioxidant activities of sicilian prickly pear (Opuntia ficus indica) fruit extracts and reducing properties of its betalains: Betanin and indicaxanthin. Journal of Agricultural and Food Chemistry. 2002;50(23):6895-6901
  21. 21. Yeddes N, Chérif JK, Guyot S, Sotin H, Ayadi MT. Comparative study of antioxidant power, polyphenols, flavonoids and betacyanins of the peel and pulp of three Tunisian Opuntia forms. Antioxidants. 2013;2(2):37-51
  22. 22. Mabrouki L, Zougari B, Bendhifi M, Borgi MA. Evaluation of antioxidant capacity, phenol and flavonoid contents of Opuntia streptacantha and Opuntia ficus indica fruits pulp. National Journal of Technology. 2015:2-8
  23. 23. Scalbert A, Johnson IT, Saltmarsh M. Polyphenols: Antioxidants and beyond. The American Journal of Clinical Nutrition. 2005;81(1):215-217
  24. 24. El-Mostafa K, El Kharrassi Y, Badreddine A, Andreoletti P, Vamecq J, El Kebbaj MS, et al. Nopal cactus (Opuntia ficus-indica) as a source of bioactive compounds for nutrition, health and disease. Molecules. 2014;19(9):14879-14901
  25. 25. Galati EM, Mondello MR, Giuffrida D, Dugo G, Miceli N, Pergolizzi S, et al. Chemical characterization and biological effects of sicilian Opuntia ficus indica (L.) mill. Fruit juice: Antioxidant and antiulcerogenic activity. Journal of Agricultural and Food Chemistry. 2003;51(17):4903-4908
  26. 26. Aruwa CE, Amoo S, Kudanga T. Phenolic compound profile and biological activities of southern African Opuntia ficus-indica fruit pulp and peels. Lebensmittel-Wissenschaft & Technologie. 2019;111(May):337-344. DOI: 10.1016/j.lwt.2019.05.028
  27. 27. Stintzing FC, Schieber A, Carle R. Evaluation of colour properties and chemical quality parameters of cactus juices. European Food Research and Technology. 2003;216(4):303-311
  28. 28. Graça Miguel M, Gago C, Valente R, Guerreiro A, Antunes D, Manhita A, et al. Qualitative evaluation of fruits from different Opuntia ficus-indica ecotypes/cultivars harvested in South Portugal. Journal of Food Biochemistry. 2018;42(6):1-11
  29. 29. Corrales-garcía J, Andrade-rodríguez J, Bernabé-Cruz E. Response of six cultivars of tuna fruits to cold storage. Journal of the Professional Association for Cactus Development. 1997;2:160-168
  30. 30. Vázquez-Araújo L, Burló F, Melgarejo P, Carbonell-Barrachina ÁA, Martínez JJ, Calín-Sánchez Á. Volatile composition and sensory quality of Spanish pomegranates (Punica granatum L.). Journal of the Science of Food and Agriculture. 2010;91(3):586-592
  31. 31. Andreu-Coll L, Noguera-Artiaga L, Carbonell-Barrachina ÁA, Legua P, Hernández F. Volatile composition of prickly pear fruit pulp from six Spanish cultivars. Journal of Food Science. 2020;85:358-363
  32. 32. Flath RA, Takahashi JM. Volatile constituents of prickly pear (Opuntia ficus indica Mill., de Castilla variety). Journal of Agricultural and Food Chemistry. 1978;26(4):835-837
  33. 33. Arena E, Campisi S, Fallico B, Lanza MC, et al. Aroma value of volatile compounds of prickly pear. Italian Journal of Food Science. 2001;13(3):312-319
  34. 34. Oumato J, Zrira S, Petretto GL, Saidi B, Salaris M, Pintore G. Volatile constituents and polyphenol composition of Opuntia ficus - indica (L.) mill from Morocco. Revue Marocaine des Sciences Agronomiques et Vétérinaires. 2016;4(3):5-11
  35. 35. Rodríguez SA, Díaz S, Nazareno MA. Characterization of volatile organic compounds of Opuntia fruit pulp - changes in cactus fruit aroma as a consequence of pulp processing. Acta Horticulturae. 2015;1067:305-310
  36. 36. Rodríguez-Cruz M, Tovar A, del Prado M, Torres N. Mecanismos moleculares de los ácidos grasos poliinsaturados y sus beneficios. Revista de investigacion clinica. 2005;57(3):457-472
  37. 37. Andreu-Coll L, Cano-Lamadrid M, Sendra E, Carbonell-Barrachina Á, Legua P, Hernández F. Fatty acid profile of fruits (pulp and peel) and cladodes (young and old) of prickly pear [Opuntia ficus-indica (L.) Mill.] from six Spanish cultivars. Journal of Food Composition and Analysis. 2019;84:103294. DOI: 10.1016/j.jfca.2019.103294
  38. 38. De Wit M, Hugo A, Shongwe N. Quality assesment of seed oil from selected cactus pear cultivars (Opuntia ficus-indica and Opuntia robusta). Journal of Food Processing & Preservation. 2017;41(3):e12898
  39. 39. Jimenez-Aguilar D, Mujica-Paz H, Welti-Chanes J. Phytochemical characterization of prickly pear (Opuntia spp.) and of its nutritional and functional properties: A review. Current Nutrition & Food Science. 2014;10(1):57-69
  40. 40. Moussa-Ayoub TE, Abd El-Hady ESA, Omran HT, El-Samahy SK, Kroh LW, Rohn S. Influence of cultivar and origin on the flavonol profile of fruits and cladodes from cactus Opuntia ficus-indica. Food Research International. 2014;64:864-872
  41. 41. Stintzing FC, Herbach KM, Mosshammer MR, Carle R, Yi W, Sellappan S, et al. Color, betalain pattern, and antioxidant properties of cactus pear (Opuntia spp.) clones. Journal of Agricultural and Food Chemistry. 2005;53(2):442-451
  42. 42. Calín-Sanchez Á, Figiel A, Szarycz M, Lech K, Nuncio-Jáuregui N, Carbonell-Barrachina ÁA. Drying kinetics and energy consumption in the dehydration of pomegranate (Punica granatum L.) arils and rind. Food and Bioprocess Technology. 2014;7(7):2071-2083
  43. 43. Marquina V, Araujo L, Ruíz J, Rodríguez-Malaver A, Vit P. Composición química y capacidad antioxidante en fruta, pulpa y mermelada de guayaba (Psidium guajava L.). Archivos Latinoamericanos de Nutrición. 2008;58(1):98-102
  44. 44. Oszmiański J, Wojdyło A, Lachowicz S. Effect of dried powder preparation process on polyphenolic content and antioxidant activity of blue honeysuckle berries (Lonicera caerulea L. var. kamtschatica). LWT- Food Science and Technology. 2016;67:214-222
  45. 45. Saenz C. Processing technologies: An alternative for cactus pear (Opuntia spp.) fruits and cladodes. Journal of Arid Environments. 2000;46(3):209-225
  46. 46. Lamia I, Zouhir C, Youcef A. Characterization and transformation of the Opuntia ficus indica fruits. Journal of Food Measurement and Characterization. 2018;12(4):2349-2357. DOI: 10.1007/s11694-018-9851-z
  47. 47. Sawaya WN, Khatchadourian HA, Safi WM, AL-Muhammad HM. Chemical characterization of prickly pear pulp, Opuntia ficus-indica, and the manufacturing of prickly pear jam. International Journal of Food Science and Technology. 1983;18(2):183-193
  48. 48. El-Samahy SK. El-Mansy HA. Bahlol HE. El-Desouky, AI. Ahmed AE. Thermal process time and sensory evaluation for canned cactus pear nectar. Journal of the Professional Association for Cactus Development. 2008;10(1)85-107
  49. 49. Atef AM, Abou-Zaid N, Ibrahim I, Ramadan MT, Nadir A. Quality evaluation of sheets, jam and juice from prickly pear and melon blends. Life Scinces Journal. 2013;10(2):200-208
  50. 50. Sáenz C, Estévez AM, Sepúlveda E, Mecklenburg P. Cactus pear fruit: A new source for a natural sweetener. Plant Foods for Human Nutrition. 1998;52(2):141-149
  51. 51. Bustos OE. Alcoholic beverage from Chilean Opuntia Ficus. American Journal of Enology and Viticulture. 1981;32(3):228-229
  52. 52. Cho I, Huh C, Kim Y. 신안산 손바닥선인장의 첨가비율 및 부위별에 따른 약주의 품질특성. Korean Journal of Food Preservation. 2010;17(1):36-41
  53. 53. Inglese P, Basile F, Schirra M. Cactus pear fruit production. In: Nobel S, editor. Cacti: Biology and uses. Berkeley and Los Angeles, California: University of California Press; 2002. pp. 163-184
  54. 54. Gallegos-Vazquez C, Mendez-Gallegos S, Mondragon-Jacobo C. Producción sustentable de la tuna en San Luis Potosí. 2013
  55. 55. Timpanaro G, Foti VT. The structural characteristics, economic performance and prospects for the Italian cactus pear industry. Journal of the Professional Association for Cactus Development. 2014;16(January):32-50
  56. 56. Losada HR, Vieyra JE, Luna L, Cortés J, Vargas JM. Economic Indicators, Capacity of the Ecosystem of Prickly Pear Cactus (Opuntia megacantha) and Environmental Services in Teotihuacan, México to Supply Urban Consumption. Journal of Agriculture and Environmental Sciences. 2017;6:85-91. DOI: 10.15640/jaes.v6n1a9
  57. 57. Basile F, Foti VT, Timpanaro G. Comparative economic analyses between conventional and eco-compatible cactus pear cultivation in Italy. Acta Horticulturae. 2002;581:47-61. DOI: 10.17660/ActaHortic.2002.581.2
  58. 58. Cortez-García RM, Ortiz-Moreno A, Zepeda-Vallejo LG, Necoechea-Mondragón H. Effects of cooking methods on phenolic compounds in Xoconostle (Opuntia joconostle). Plant Foods for Human Nutrition. 2015;70:85-90. DOI: 10.1007/s11130-014-0465-2
  59. 59. Hernández F, Noguera-Artiaga L, Burló F, Wojdyło A, Carbonell-Barrachina ÁA, Legua P. Physico-chemical, nutritional, and volatile composition and sensory profile of Spanish jujube (Ziziphus jujuba Mill.) fruits. Journal of the Science of Food and Agriculture. 2016;96:2682-2691. DOI: 10.1002/jsfa.7386
  60. 60. García-Cruz L, Dueñas M, Santos-Buelgas C, Valle-Guadarrama S, Salinas-Moreno Y. Betalains and phenolic compounds profiling and antioxidant capacity of pitaya (Stenocereus spp.) fruit from two species (S. pruinosus and S. stellatus). Food Chemistry. 2017;234:111-118. DOI: 10.1016/j.foodchem.2017.04.174
  61. 61. Elfalleh W. Total phenolic contents and antioxidant activities of pomegranate peel, seed, leaf and flower. Journal of Medicinal Plants Resource. 2012;6(32):4724-4730. DOI: 10.5897/jmpr11.995
  62. 62. Zorgui L, Ayed-Boussema I, Ayed Y, Bacha H, Hassen W. The antigenotoxic activities of cactus (Opuntia ficus-indica) cladodes against the mycotoxin zearalenone in Balb/c mice: Prevention of micronuclei, chromosome aberrations and DNA fragmentation. Food and Chemical Toxicology. 2009;47:662-667. DOI: 10.1016/j.fct.2008.12.031
  63. 63. Zourgui L, Golli E El, Bouaziz C, Bacha H, Hassen W. Cactus (Opuntia ficus-indica) cladodes prevent oxidative damage induced by the mycotoxin zearalenone in Balb/C mice. Food and Chemical Toxicology 2008;46(5):1817-1824
  64. 64. Sánchez GF. Pontencial del cultivo de la chumbera (Opuntia ficus-indica (L.) Miller) para la obtención de biocombustibles. Madrid, Spain: Doctoral dissertation, Universidad Politécnica de Madrid; 2012
  65. 65. Pérez Cadena R, Arana Cuenca A, Alejandro Lizardi M, Alejandro Medina S, Espinosa T, Martínez A, et al. Selección de una variedad de cladodio de nopal (Opuntia ficus-indica) con potencial para la obtención de bioetanol. In: XVI Congreso Nacional de Biotecnología y Bioingeniería. Guadalajara, Jalisco, México; 2015
  66. 66. Villabona A, Paz I, Martinez J. Characterization of Opuntia ficus-indica for using as a natural coagulant. Revista Colombiana de Biotecnología. 2013;XV(1):137-144
  67. 67. Costa RG, Beltrão Filho EM. Ramos do Egypto Queiroga RDC, Suely Madruga M, Nunes de Medeiros a, de Oliveira CJB. Chemical composition of milk from goats fed with cactus pear (Opuntia ficus-indica L. miller) in substitution to corn meal. Small Ruminant Research. 2010;94(1-3):214-217. DOI: 10.1016/j.smallrumres.2010.08.001
  68. 68. Vieira EL, Batista ÂMV, Guim A, Carvalho FF, Nascimento AC, Araújo RFS, et al. Effects of hay inclusion on intake, in vivo nutrient utilization and ruminal fermentation of goats fed spineless cactus (Opuntia fícus-indica Mill) based diets. Animal Feed Science and Technology. 2008;141(3-4):199-208
  69. 69. Otálora MC, Carriazo JG, Iturriaga L, Nazareno MA, Osorio C. Microencapsulation of betalains obtained from cactus fruit (Opuntia ficus-indica) by spray drying using cactus cladode mucilage and maltodextrin as encapsulating agents. Food Chemistry. 2015;187:174-181
  70. 70. Saénz C, Tapia S, Chávez J, Robert P. Microencapsulation by spray drying of bioactive compounds from cactus pear (Opuntia ficus-indica). Food Chemistry. 2009;114(2):616-622. DOI: 10.1016/j.foodchem.2008.09.095
  71. 71. Nobel PS, Pimienta-Barrios E, Hernández JZ, Ramírez-Hernández BC. Historical aspects and net CO2 uptake for cultivated Crassulacean acid metabolism plants in Mexico. The Annals of Applied Biology. 2002;140(2):133-142
  72. 72. Nobel PS, Valenzuela-Tapia A, Zañudo-Hernández J, Pimenta-Barrios E, Rosas-Espinoza VC. Young daughter cladodes affect CO2 uptake by mother cladodes of Opuntia ficus-indica. Annals of Botany. 2004;95(2):363-369
  73. 73. Escobar-Alvarado LF, Vaca-Mier M, Rojas-Valencia MN. Hydrocarbon degradation and lead solubility in a soil polluted with lead and used motor oil treated by composting and phytoremediation. Bulletin of Environmental Contamination and Toxicology. 2018;100(2):280-285. DOI: 10.1007/s00128-017-2211-6
  74. 74. Bañuelos GS, Lin ZQ. Cultivation of the Indian fig Opuntia in selenium-rich drainage sediments under field conditions. Soil Use and Management. 2010;26:167-175

Written By

Francisca Hernández García, Lucia Andreu Coll, Marina Cano-Lamadrid, David López Lluch, Ángel A. Carbonell Barrachina and Pilar Legua Murcia

Submitted: 20 December 2019 Reviewed: 05 March 2020 Published: 31 March 2020