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Article

Spectroscopic and Spectrometric Applications for the Identification of Bioactive Compounds from Vegetal Extracts

by
José Daniel Lozada-Ramírez
1,
Ana E. Ortega-Regules
2,
Luis Ricardo Hernández
1 and
Cecilia Anaya de Parrodi
1,*
1
Departamento de Ciencias Químico Biológicas, Universidad de las Américas Puebla, 72810 San Andrés Cholula, Mexico
2
Departamento de Ciencias de la Salud, Universidad de las Américas Puebla, 72810 San Andrés Cholula, Mexico
*
Author to whom correspondence should be addressed.
Appl. Sci. 2021, 11(7), 3039; https://0-doi-org.brum.beds.ac.uk/10.3390/app11073039
Submission received: 18 December 2020 / Revised: 4 February 2021 / Accepted: 3 March 2021 / Published: 29 March 2021
(This article belongs to the Special Issue Application of Spectroscopy in Food Analysis: Volume II)
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Abstract

:

Featured Application

Separation and quantification by chromatographic methods, combined with spectroscopic and spectrometric techniques, are relevant in the characterization and quantification of natural polyphenols and anthocyanins. These compounds have nutraceutical properties, which are very important for the food industry.

Abstract

The use of spectroscopic and spectrometric techniques to isolate, quantify, and characterize bioactive compounds from edible plants has become a common and mandatory activity in food chemistry. As technology advances, diverse methodologies are being applied more frequently, which are coupled most of the time to give the best diagnosis and information of a metabolite of interest. In this paper, we state the different approaches that have been performed by our research group to isolate, identify, and apply the different bioactive organic compounds obtained from some vegetal extracts. Through this review, we show the importance of the use of those analytical tools to evaluate the possible impact of some plants we included on diet for improving human health.

Graphical Abstract

1. Introduction

The need to know the food quality has led researchers to use various analytical methods to determine some principal food constituents. The most commonly used techniques are classified as follows: chromatography, sensors, spectroscopy, spectrometry, and combinations of these techniques [1].
Mass spectrometry is widely used to analyze foods and beverages and is mainly coupled with gas chromatography to identify single compounds and seek contaminants or adulterations. Other techniques involving mass spectrometry (MS) are proton transfer reaction (PTR)-MS, inductively coupled plasma (ICP)-MS, and gas chromatography (GC)–MS or high-performance liquid chromatography (HPLC)-MS. The PTR-MS technique is a quantitative method for determining volatile organic compounds [2] with a reduced fragmentation, which makes this technique easy to interpret. Tandem-MS (MSn), which is useful for identifying compounds, analyzes fragments of fragments [3,4].
Ultraviolet–visible spectroscopy (UV–vis) is a tool for determining the polyphenol content of foods and beverages and study the antioxidant properties and changes related to storage [5].
Infrared spectroscopy (IR), along with other techniques, helps obtain conclusive analysis results. It is a rapid and inexpensive method applied for food product analysis. Of the three regions in which the IR spectrum is divided, the middle (400–4000 cm−1) and near regions (4000–14,000 cm−1), abbreviated as MIR and NIR, respectively, are particularly useful for food analysis.
Over the past two decades, the view on nuclear magnetic resonance spectroscopy has changed from being a purely structural elucidation technique to being an analytical technique with particular usefulness in the field of food [6].
Plants have a highly developed secondary metabolism that produces many nonvital, but essential compounds for adapting to the surrounding environment where they live. These compounds are called secondary metabolites or natural products and have various biological activities, including antibiotic, antifungal, antiviral, herbicide, insecticide, anticancer, antioxidant, and antidiabetic activities [7,8]. Chemically, these substances belong to different types of compounds, such as terpenes, alkaloids, polyketides, flavonoids, and iridoids, among others. Along with other pigments, anthocyanins belonging to the flavonoid type are responsible for imparting color to the plants or products derived from them. In addition, these compounds also possess pharmacological properties (e.g., reducing capillary fragility and permeability and antioxidant, anti-inflammatory, and antiedema activity) [9].
This work presents some vegetal product analyses using chromatographic and spectroscopic and spectrometric techniques to measure, separate, and identify bioactive compounds from their extracts, centering on some works developed by our research group.

2. Discussion

According to Bernhoft [10], the main bioactive compounds found in plants can be classified in (a) glycosides, (b) flavonoids and proanthocyanidins, (c) tannins, (d) mono- and sesqui-terpenoids, and phenylpropanoids, (e) diterpenoids, (f) resins, (g) lignans, (h) alkaloids, (i) furocoumarins and naphtodianthrones, and (j) proteins and peptides.
  • Glycosides
The glycosides comprise a group of diverse compounds attached to mono- or oligosaccharides or uronic acid (Figure 1). These bioactive compounds have been attributed to some beneficial activities in human health, such as anticancer, antimicrobial, antiviral, cardioprotective effects, amongst others. This group is formed by specific secondary metabolites, widely distributed in plants, with the most important being (i) cardiac glycosides, (ii) cyanogenic glycosides, (iii) glucosinolates, (iv) saponins, and (v) anthraquinone glycosides [10].
The identification of glycosides has been a common task due to the importance of these compounds. For this, spectroscopic and spectrometric methods have been applied to isolate, purify, identify, and quantify their presence in samples from diverse vegetal products. For example, the use of IR and UV–vis, nuclear magnetic resonance (NMR), MS, HPLC-UV–vis, and ultra-high-performance liquid chromatography (UPLC)-UV–vis methods have been applied for those purposes in recent years. Table 1 shows some examples of bioactive compounds, including a cardenolide glycoside, isolated from plant sources, their bioactive properties, and the methodologies used for their measuring.
  • Flavonoids and proanthocyanidins
Flavonoids comprise a group of bioactive substances with the presence of phenolic rings. These compounds contain molecules that are recognized for their beneficial effects on human health, associated with their high antioxidant anti-inflammatory, anticarcinogenic, antiviral, antimicrobial activities, amongst others. Several plants exhibit the presence of these bioactive molecules in different structures of their organisms—for example, in fruits, flowers, stems, grains, and barks. Flavonoids group commercially important compounds such as (i) flavones, (ii) isoflavones, (iii) flavonols, (iv) flavanols, (v) flavanones, (vi) flavanonols, (vii) proanthocyanidins, (viii) chalcones, and (ix) anthocyanins (Figure 2).
Due to the diverse biological activities of flavonoids and proanthocyanidins, they have received much attention. Nevertheless, their stability is a challenge for their application as nutraceuticals, cosmetics, pigments, and drugs. Table 1 shows examples of a flavonoid and a proanthocyanidin that have been studied very recently as well as the analytical methods used to isolate and characterize these molecules.
During the last decade, our research group has been working in the extraction, purification, and characterization of anthocyanins (Figure 3), which are flavonoids that have demonstrated ample possibilities for their application as natural pigments, nontoxic food additives, nutraceuticals, and antioxidants. For the above, a detailed description of this research, and references from others related, are described.
Anthocyanin identification and separation from foods are widely performed activities. Individual components must be separated from foods and beverages to evaluate their biological activities. For the specific case of anthocyanins, using HPLC-UV–vis has become the most important approach for identifying and separating these compounds [47,48].
The ultraviolet absorption spectra of these phenolic compounds can be taken advantage of to follow and separate different anthocyanins from foods and beverages using the UV–vis interval (200–750 nm). Chromatographic column techniques are useful in separating anthocyanins from extracts and different anthocyanins based on their retention properties.
A study performed by our research group on the extracts of roselle calyxes (Hibiscus sabdariffa) afforded a chromatogram with 25 different compounds having maximum absorbances in the range of 270–520 nm. From these peaks, we identified 23 compounds employing MSn. The most abundant compounds in the extract comprise chlorogenic acid, 5-O-caffeoylquinic acid, 4-O-caffeoylquinic acid, and the anthocyanins delphinidin-3-O-sambubioside (D3S), delphinidin-3-O-glucoside (D3G), cyanidin-3-O-sambubioside (C3S), Cyanidin-3-O-glucoside (C3G), quercetin-3-O-sambubioside (Q3S), quercetin-3-O-glucoside (Q3G), quercetin-3-O-rutinoside (Q3R), myricetin-3-O-sambubioside (MY3S), quercetin-3-O-rutinosil-7-O-xyloside (Q3R7X), kaempferol-3-O-rutinoside (K3R), quercetin-3-O-(2′-coumaroyl)-sambubioside (Q3(2C)S), quercetin-3-O-(2′-coumaroyl)-rutinoside (Q3(2C)R), and quercetin (unpublished results). In the same way, Mourtzinos et al. [50] obtained the phenolic compound profile by liquid chromatography (LC)–MS, including chlorogenic acid, quercetin, myricetin, caffeic acid, syringic acid, kaemferol, gallic acid, sinapic acid, ursolic acid, ferulic acid, p-coumaric acid, protocatechuic acid, and epicatechin. Differences exist in the composition and abundance of phenolics caused by the differences in the sample origin [51,52].
Spectrophotometric measures with multidiode array detectors must be performed individually or in association with HPLC equipment. This technology allows the analysis of a sample on a broad range of UV–vis wavelengths. Using combined techniques for the separation and identification of phenolic compounds determines the association of the active properties observed on a natural product to a specific substance present on food.
The phenolic compound characterization is an affordable process applying specific techniques. For example, characterization of anthocyanins from roselle calyxes (Hibiscus sabdariffa), blue maize (Zea mays), coffee fruit (Coffea arabica), blueberry (Vaccinium ashei), and from beverages prepared from these products can be carried out using spectroscopic and spectrometric techniques.
The characterization of extracts from vegetal products with anthocyanins implies the measurement of the total phenolic compounds, total monomeric anthocyanins, antioxidant activity, and color assessment. The Folin–Ciocalteu method is used to determine the total phenolic compounds. It quantifies the antioxidant or reductive capacity of the phenolic compounds present in a sample. The method exploits a colorimetric reaction evaluated by UV–vis spectrophotometry due to the formation of a blue chromophore of the phospho-molybdenum-tungstic plus phenolic compound-complex at 765 nm [53,54]. The most common standard used to generate a calibration curve is gallic acid; thus, the phenolic content results are usually expressed as mg gallic acid equivalents (GAE). In our group, we quantified the total phenolic compounds from blueberry (Vaccinium ashei) spray-dried extracts with the Folin–Ciocalteu method. The obtained results represent the precision of the approach—in other words, high linearity, low limit of detection, high limit of quantification, high reproducibility, and excellent accuracy. First, we obtained microcapsules that can retain anthocyanins. A value of 24.92 μmol GAE/g wet weight of blueberry was determined from the fruit slurry before microcapsule preparation. Consequently, we achieved a retention of more than 95% in one of the powders prepared by spray drying. The application of spectrophotometric techniques undeniably enabled the initial quantification following the evolution of the anthocyanin quantities during storage of the food product [55].
The total monomeric anthocyanins can be determined through the pH differential method, which is a simple spectroscopic assay involving anthocyanin transformation when a change in pH is applied. This is used as the standard methodology approved by the Methods Committee on Commodity Foods and Commodity Products as First Action of the Association of Official Agricultural Chemists for anthocyanin quantification [56]. The method is based on a sample of free anthocyanins presenting a particular hue (e.g., red, purple, and blue) at pH 1.0 and turned to colorless at pH 4.5; thus, the difference in absorbance can be measured. Beginning from an acidic pH of 1, individual (nonpolymerized) anthocyanins present colors on the interval of orange to purple due to the presence of its predominant form of the flavylium cation. Turning the pH to neutral (7.0) represents a color change to blue caused by the deprotonation of the flavylium cation to form the quinoidal base of the anthocyanin. On the contrary, the change of pH from 1.0 to less acidic pH of 4.5 implies the change of the flavylium cation form to a carbinol pseudo base as a cause of water introduction. This structure reaches equilibrium with a colorless chalcone structure.
The quality of fresh and processed foods containing anthocyanins can be determined by spectrophotometrically following (520 nm) the anthocyanin evolution during the shelf life of fruit or vegetal juice, pulp from fruits, flowers, seeds, grains, wine, and pigments extracted from vegetables. The expression of the results is related to the main anthocyanin present in the product. For example, the major monomeric anthocyanin in wine is malvidin-3-O-glucoside (M3G). Using the molar absorptivity coefficient (ε) of the evaluated anthocyanin is required. Thus, the results are commonly expressed as mg of M3G/g or mL sample [57].
Another wine illustration implies the spectrophotometric detection and quantification of polymeric anthocyanins. Therefore, the polymeric anthocyanin concentration must be established by mixing a sample of the product with 5% SO2, then measuring the mixture absorbance at 520 nm [58]. The polymeric anthocyanin quantification through this methodology allowed the comparison between the content of polymeric anthocyanins in control wines and wines enzymatically treated with pectinolytic enzymes to improve the release of the bioactive compounds (an increase from 23% to 33%) responsible for the color and beneficial effects on human health [59].
Measuring the color of food products can be spectrophotometrically performed by applying the methodology proposed by the International Commission on Illumination, called the CIEL*a*b* system. The measures require the use of colorimeter equipment usually with color sensor wavelengths of 400 to 720 nm. The color of food products represents a major quality characteristic; thus, it must be assessed by measuring the hue parameters. The term L* represents the clarity or brightness of a sample; hence, L* = 100 represents white, and L* = 0 represents black. In contrast, the a* and b* parameters have positive and negative values, with values a*+ denoting a tendency represented by the red color and a*− by green. Additionally, b*+ is yellow, and b*− is blue. In the laboratory, it is also common to determine the color intensity of a sample as the sum of the absorbances of the sample at 620 (blue color), 520 (red color), and 420 nm (yellow color). Another parameter for determining this is the tone or tint of the sample by calculating the ratio Abs 420/Abs 520 [59].
Studies on color have led to the understanding of the importance of the compounds responsible for providing this characteristic in wines and the importance of their localization within the cell. Spectrophotometrically evaluating the extractability of phenolic compounds, tannins, and anthocyanins from inside the cell wall of a grape cell, where they are protected from degradation, is easy [60]. Additional studies have demonstrated the adherence of anthocyanins to the polysaccharides and proteins of the cell wall, causing a diminishing in the compound content [61]. For this, it is important to determine the chromatic characteristics of wine through the spectrophotometric measure of its color intensity. A member of this research group has been working on analyzing these chromatic properties in wines from Spain by evaluating the effect of enzymatic treatments on anthocyanin extraction through a comparison of the color intensities of treated wine with untreated wine. The results evidenced an increase in the color intensities of treated wine of more than 20% with a total phenolic content of 25% and a total monomeric anthocyanin content of 23%, which are higher than those obtained for untreated wine [62]. Additionally, the usage of a combination of pectolytic enzymes was demonstrated as an alternative for increasing the color intensity in wines by more than 18% [59].
The antioxidant activity is a key parameter for determining the bioactive properties of foods. The antioxidant property of a substance is defined as its capacity to prevent or diminish the oxidation caused by the electron transfer from a donor to an acceptor. The oxidative processes in human beings cause the proliferation of unstable chemical species. These processes alter the normal metabolism and are associated with multiple disorders and illnesses, such as cancer, diabetes, metabolic syndrome, aging, Parkinson’s disease, Alzheimer’s disease, heart disease, and stroke, among others [63,64,65,66]. Several natural antioxidants are well known and alphabetically classified as antioxidants C (carotenoids), E (enzymes), G (glutathione), L (lipids), and P (phenolics) [67]. Many spectrophotometric techniques are useful in antioxidant characterization. At present, the most frequently applied techniques are the 2,2-diphenyl-1-picrylhydrazyl (DPPH) [68] and the 2,2′-azino-bis-(3-ethylbenzothiazoline-6-sulfonic acid (ABTS) radical scavenging assays [69]. Other related methodologies have been reported in the literature [70,71], including ferric-reducing antioxidant power (FRAP) [72], oxygen radical absorption capacity (ORAC) [73], Trolox equivalent antioxidant capacity (TEAC) [74], N,N-dimethyl-p-phenylenediamine (DMPD) [75], and Cu(II) reduction capacity assay (CUPRAC) [76].
DPPH testing is an easy and fast method, which is especially important for lipophilic antioxidants [77]. The approach consists of preparing a methanol solution of DPPH to form the DPPH, a stable radical of purple color that can be spectrophotometrically measured at 515 nm. This radical can accept one hydrogen from the antioxidant to form a yellow-colored DPPH2 that comes from the antioxidant substance, a reaction that causes a diminishing in the absorbance at 515 nm. Meanwhile, the ABTS test uses the green-colored radical ABTS●+ by ABTS oxidation with potassium persulfate. Similar to that observed for DPPH, ABTS●+ stabilizes through the reduction provoked by the antioxidant compound. The result is a colorless solution that can be spectrophotometrically followed at 415 nm [69]. This methodology allows the evaluation of both hydrophilic and lipophilic substances. The results are expressed referring in comparison to the standard scavenger Trolox, a vitamin E analog that serves to construct a calibration curve. Trolox equivalents (TEs) indicate the antioxidant present for both assays [77].
Previous works have dealt with the evaluation of the antioxidant activity of several vegetal products and extracts obtained from them, which is the case of diverse berries [78], grapes [79], wines [80], kiwi [81], tea [82], ginger [83], carrot [84], quinoa [85], maize [86,87], ginkgo [88], and so on. In our laboratory, we have been working on several vegetables to evaluate their antioxidant properties for diverse purposes. This is the case of the evaluation of the antioxidant activity retention of spray-dried blueberry extracts [55]. In this work, we report the high antioxidant activity of blueberry extracts (116.2 TE/g soluble solid of the blueberry extract) following the abovementioned spectrophotometric ABTS assay [89]. The time evolution of the spray-dried extracts from the blueberry is also spectrophotometrically followed. These extracts reach values as high as 101.89–102.22 TE/g ss berry extracts, corresponding to antioxidant activity retentions of more than 87% in some of the prepared capsules. In addition, we reported on the evaluation of phenolic compounds to measure the antioxidant activity of the extracts from pigmented maize (Zea mays), roselle calyxes (Hibiscus sabdariffa), mamey (Pouteria sapota), coffee fruit (Coffea arabica), carrot (Daucus carota), and passion fruit (Passiflora edulis).
A study focused on the antioxidant activity of anthocyanins from Hibiscus sabdariffa L. [90] deals with the measuring of roselle petals’ extracts cultivated in Taiwan. In this work, the antioxidant activity was measured through FRAP, ORAC, and total antioxidant status (TAS) assays. It is noteworthy that the extraction time was positively correlated with the antioxidant activity of the extracts. In this regard, the longer was the extraction the most antioxidant activity of the extracts was detected, no matter the methodology employed. Additionally, there was a linear relationship between all the assays probed in this work. As well, other authors have made evident the reducing capacity of the extracts of roselle attributed to the presence of anthocyanins, either using the ABTS, DPPH, or ORAC methodologies [91,92].
Related to the extraction of anthocyanins from roselle, Cissé et al. [93] established a mathematical model to predict the thermo-degradation kinetics of water-extracted anthocyanins. For this purpose, total monomeric anthocyanins were spectrophotometrically measured using the pH differential method (510 nm). In this way, it was possible to spectrophotometrically follow the degradation of anthocyanins to construct a mass transfer model.
For the pigmented maize, some studies have enabled the identification of anthocyanins present in this product. Lao and Giusti [94] obtained the HPLC profiles of the anthocyanins present in powders from purple maize cobs using a diode array detector (DAD). The results showed the presence of C3G as the major anthocyanin present in this pigmented grain, followed by cyanidin-3-malonylglucoside (C3MG), peonidin-3-O-glucoside (P3G), pelargonidin-3-(6″-malonyl-glucoside) (PG3(6MG)), pelargonidin-3-O-glucoside (PG3G), and peonidin 3-(6″malonyl-glucoside) (P3(6MG)). In this sense, we have been working on the extraction, quantification, and identification of anthocyanins from blue maize from central Mexico (unpublished data). Accordingly, the LC–MS generated from the extracts of two varieties of the blue maize revealed the existence of phenolic compounds with nutraceutical properties in different proportions; hence, the corn varieties can be assigned different beneficial properties because of the different constituent concentrations. The results illustrate the presence of the same anthocyanins, but in different proportions, which was expected considering the different soil compositions in which each crop has grown. It is especially important to determine the fingerprints for each cultivar from the separation, identification, and quantification of some compounds that serve as biomarkers. The combined use of these two powerful analytical tools (i.e., HPLC coupled with mass spectrometry) has enabled the identification of several bioactive compounds from different natural products and derived [95,96,97,98].
Related to the above, Žilić et al. [86] developed a study to isolate phenolic compounds and carotenoids from ten different colored maize genotypes from Mexico, USA, France, Serbia, and the Netherlands but grown in Serbia. In said study, the authors extracted the phenolic acids from the kernels using a mixture of acetone/methanol/water as extractant agent before alkaline hydrolysis with NaOH. Those hydrolysates were extracted with nonpolar solvents and dried with N2. Then, they were dissolved in methanol for HPLC analysis on a C18 column, measuring at 280 nm, and identifying the phenolic acid peaks by comparing retention times and absorption versus standards used to construct a calibration curve. On the other hand, anthocyanins from the samples were analyzed by UPLC (Ultra-high-performance liquid chromatography), through a C18 column, coupled with MS equipped with a heated electrospray interface. The anthocyanins of the mixtures extracted were identified and quantified by comparison with the standards of C3G, PG3G, cyanidin 3,5-diglucoside (C3,5DG), and pelargonidin-3,5-diglucoside (PG3,5DG). Additionally, the total phenolic content was determined following the procedure described by Folin–Ciocalteu, measuring the absorbance at 725 nm and expressing the content as GAE per kg of dry mass. Furthermore, the total flavonoid content was spectrophotometrically determined by measuring the absorbance of the extracts mixed with NaNO2 and reacted with AlCl3 to get flavanoid-aluminum complexes that were measured at 510 nm, after being treated with NaOH and centrifuged, as described previously by Zhishen et al. [99]. The total antioxidant capacity was spectrophotometrically evaluated for the ten maize varieties through the use of two methodologies, ABTS and DPPH. For the ABTS methodology, a solution of ABTS with K2S2O8 was prepared and left standing in the dark overnight to generate the radical ABTS•+. The solution of the radical was adjusted to obtain an absorbance of 0.7 ± 0.02 at 734 nm. For the case of DPPH, the solution was prepared in ethanol and adjusted to an absorbance of 1.0 ± 0.05 at 525 nm. In both cases, the samples were added to ABTS•+ or DPPH to measure the scavenging activity associated with the bioactive compounds extracted from maize. The obtained results were expressed as TE per kg of dry mass by comparison with this analog of vitamin E.
Moreover, the application of anthocyanins in the food industry as pigments and because of its radical scavenging properties has led to the use of maize as a low-cost anthocyanin-rich vegetal source. Similarly, the higher the antioxidant activity is the higher phenolic content. The information above indicates that the use of spectrophotometric and spectrometric methods is required to evaluate the potential use of vegetables as a source of bioactive compounds acting positively in human health.
On the other hand, Urias-Lugo et al. [100] have reported the obtain of anthocyanins from Mexican pigmented maize due to their beneficial properties to health. The extraction of these biologically active compounds can be performed using solvents of different polarities—for example, water, ethanol, methanol, or acetone. In this work, the authors extracted these natural pigments by using acidified and nonacidified ethanol, following the reports previously published [101,102]. The analysis of phenolic acids was performed by HPLC equipped with a PDA using a reverse-phase column. Meanwhile, anthocyanins were analyzed by HPLC with a PDA and identified with HPLC coupled with time-of-flight (TOF)-MS. The analysis and quantification of the maize samples show the presence of C3G as the main anthocyanin. Nevertheless, the presence of two isomers of cyanidin di-succinyl-glucoside (CDSG) (I and II), three isomers of cyanidin-3-(6″malonyl-glucoside) (C3(6MG)) (I, II, and III), cyanidin-3-succinyl-glucoside (C3SG), PG3G, and pelargonidin-3-(6″-malonyl-glucoside) (P3(6MG)). It is important to note the differences observed during the extraction process related to the use of acidified or nonacidified ethanol. These differences imply that some anthocyanins can be isolated and quantified when one extraction method is used but not with the other and vice versa. The above serves to highlight the importance of the method of extraction of biologically active compounds from vegetables. The authors concluded that the extraction with nonacidic ethanol was better than that with acid-ethanol because it contained more anthocyanins.
Another study was conducted to analyze the anthocyanins present in industrial preparations of pigmented maize [103]. This study aimed to analyze the anthocyanins composition of a commercial extract from purple maize, obtained from maceration with nonacidified ethanol. The analysis was developed using HPLC with a PDA detector (C18 column) coupled with a mass spectrometer with ESI interface. The findings show a different pattern of anthocyanins when compared to those reports from [86,100]. For example, C3G is the most abundant anthocyanin, but it is also revealed the presence of PG3G, P3G, C3(6MG), PG3(6MG), P3(6MG), cyanidin-3-(6″-ethyl malonyl-glucoside) (C3(6EMG)), pelargonidin 3-(6″-ethyl malonyl-glucoside) (PG3(6EMG)), and peonidin 3-(6″-ethyl malonyl-glucoside) (P3(6EMG)). From this list, the only PG3G were identified and quantified in the three studies, and PG3(6MG) in two of them [100,103]. Similar results to those obtained for de Pascual-Teresa et al. [103] were previously reported by Fossen et al. [104] from maize cultivated in England, with the presence of C3G, C3(6MG), cyanidin 3-(3″,6″-dimalonylglucoside) (C3(3,6DMG)), P3G, P3(6MG), and peonidin 3-(dimalonylglucoside) (P3(DMG)). Interestingly, in this work is reported the presence of the same anthocyanins but in different proportions from samples of flowers of reed canary grass (Phalaris arundinacea), cultivated in Norway. For the above, it is evident that the use of spectrophotometric and spectrometric instrumentation permits the isolation and quantification of anthocyanins, allowing the identification of these bioactive compounds present in trace quantities. This can be applied in the fingerprinting of cultivars to determine their origin, particularly because, as reported elsewhere [105], the plant variety, geographical and climatic conditions, fertilization, soil, cultivation practices, and fruits’ degrees of ripeness influence the presence of phenolic compound contents.
The quantification, separation, identification, and following of the extract stability by measuring the color and the antioxidant properties of anthocyanins are required activities that carried out with the support of spectroscopic and spectrometric applications. We have also been working on the modification of the previously known phenolic compounds to enhance their chemical stability through biomimetics. Using spectroscopic techniques to identify and quantify these novel compounds is transcendental. For example, anthocyanins can be chemically or enzymatically modified by acylation, glycosylation, and methylation [106,107] to produce more stable compounds. These compounds could be differentiated from the original by identifying, measuring, and quantifying through HPLC–TOF–MS, UV–vis, and HPLC. This is the case of the chemical synthesis of six novel pyranoanthocyanins that were obtained by our research group from anthocyanins delphinidin-3-O-sambubioside (D3S) and C3S, which were extracted and purified from the extracts of roselle calyxes (Hibiscus sabdariffa L.), which is widely used to prepare alcoholic and nonalcoholic refreshing beverages and infusions. These anthocyanins reacted with 4-vinylphenol, acetone, and butanone to synthesize novel pigments, purified and characterized by UV–vis and HPLC, and identified by MS [108]. The original anthocyanins D3S and C3G showed maximum absorptions at 526 and 518 nm, respectively. Nevertheless, the changes provoked by chemical modifications made to different spectra associated with the novel hydroxyphenyl-anthocyanins (λmax 503 and 501 nm, respectively) and to the synthesized methyl-pyranoanthocyanins (λmax 478 and 354, 475 and 340, 480 and 353, and 478 and 338 nm, respectively). The new pyranoanthocyanins have different spectroscopic properties compared with their original phenolics.
Additionally, the search for more stable antioxidant compounds was conducted to the anthocyanin stabilization through the construction of physical barriers, such as the micro- or nanoencapsulation of the phenolic compounds. Through the construction of these polymeric or nanostructure matrices, anthocyanins can endure for long-time periods, and the evolution of their preservation can be followed by spectroscopic means. Furthermore, the specific properties of these antioxidant compounds can be followed during the shelf life of the vegetal, food product, or from the extracts obtained from that vegetal. An example of this is our previous work on the stabilization of blueberry extracts as an anthocyanin source. Blueberry is an important local product consumed as jams and beverages. Unfortunately, blueberry and its anthocyanins responsible for providing color are very unstable. Blueberry extracts were spray-dried using as an encapsulating agent mesquite gum affording a powder to stabilize the color. We proceeded to the powder evaluation in terms of color and anthocyanin content over time of storage. The evaluation consisted of the spectroscopic quantification of the total phenolic content, total anthocyanins, antioxidant capacity, and color [55]. Consequently, the polymeric wall usage was found to be effective in avoiding the losses of phenolics, anthocyanins, and color under different storage conditions (light and temperature).
In terms of stability, our research group conducted another approach to look for the anthocyanin stabilization from coffee husks (Coffea arabica) by using ZnO nanoparticles. Herein, we were able to stabilize anthocyanins from the extracts obtained in this byproduct from the coffee industry. First, ZnO nanoparticles were successfully prepared following a previously described methodology [109] and used to stabilize the mentioned anthocyanins. Atomic absorption spectrometry was used to determine the mass of the anthocyanins coated by the ZnO nanoparticles by comparing the intensity of the signal obtained to a calibration curve previously prepared and convert the intensity into the zinc ion mass. The total mass of ZnO was stoichiometrically calculated and subtracted from the mass of the dried sample, obtaining the mass of the anthocyanins coating the nanoparticles (data unpublished).
Another spectroscopic technique frequently employed is infrared spectroscopy. It is useful to follow the amount and stability of anthocyanins over time. In previous work, anthocyanins from Hibiscus sabdariffa were used to dope titanium dioxide nanotubes and ensure more stability and capability for electrode regeneration. The complexation of these compounds can be measured and quantified using FTIR and UV–vis spectroscopy, determining changes in the absorbance profiles of the nanotubes with or without complexed anthocyanins [110]. The changes registered in the UV–vis spectra of the nanotubes against those complexed with anthocyanins can be followed using roselle extracts as the reference, which contain mainly D3S. Additionally, the infrared spectroscopy revealed the anthocyanin immobilization through the presence of characteristic peaks from 750 to 1700 cm−1. The presence of a band at 1700 cm−1 indicates the presence of organic acids, such as hibiscus acid. The peaks between 1630 and 1440 cm−1 were associated with the alkene and aromatic groups present in the polyphenols. The C–O bonds present in the phenolic group and the sugar moiety of the anthocyanin skeleton appeared from 1040 to 1260 cm−1. Finally, the C–H bonds of the aromatic ring showed bands near 750 cm−1.
In another work, we evaluated the anthocyanin stability from the roselle calyxes when exposed to microwave energies. Examining the thermal stability of the anthocyanins to determine their possibility to react at microwave energies without being degraded, the anthocyanin extracts were heated at different temperatures (30–80 °C) for 20 min. Afterward, the phenolic compound and chroma properties were spectrophotometrically evaluated. The results showed losses in the total phenolic compounds from 9.28 at 60 °C to 11.34% at 80 °C. Meanwhile, color parameters a* and b* decreased, but L* was augmented (lighter colors). The results indicated that the extracts lose their red color by migrating to green (a*) and lose their blue color by turning into yellow (b*), indicating anthocyanin degradation. With the support of spectrophotometric applications, we can conclude from these results that the temperature increase negatively affects the anthocyanin stability, thereby generating negative repercussions on the nutraceutical and colorant features associated with phenolic compounds [111].
More recently, there are reports concerning the chemical stability of anthocyanins from roselle. Due to D3S being an anthocyanin that has been demonstrated to induce apoptosis in human promyelocytic leukemia cells (HL-60), there has been an increasing interest in the study of the extracts of this plant [112]. The process of copigmentation, highly visible during winemaking, occurs because of the chemical association of two or more anthocyanin molecules, but also with proteins, sugars, organic acids, and other molecules. This process allows the formation of new anthocyanins that exhibit new colors and chemical characteristics. For the above, this study was focused on the aqueous extraction of anthocyanins at different temperatures (40, 60, and 80 °C) and at different times of extraction (10, 20, and 30 min) to determine the effect of copigmentation with organic acids such as phytic and chlorogenic, and pH on their stability. Anthocyanin (535 nm), flavonoid (374 nm), and total phenolic (761 nm) concentrations and the antioxidant activity were spectrophotometrically analyzed by the DPPH methodology (517 nm). The results from this study show that anthocyanins from roselle exhibit high thermal stability at 60 °C and also reversible stability in terms of pH changes, measured by spectrophotometric titration, thus preserving the antioxidant activity of the extracts evaluated.
Another bioactive compound that has been studied very recently by our research group is piceatannol, a stilbenoid (a nonflavonoid polyphenol) with antiobesity properties that can be characterized, measured, and quantified using spectrophotometric tools. This nutraceutical was extracted from passion fruit seeds (Passiflora edulis) and quantified through the Folin–Ciocalteu methodology at 765 nm, as described earlier (data unpublished). The antioxidant activity was measured by applying the ABTS radical method expressing its antioxidant capacity as μmol equivalent Trolox.
  • Tannins
Tannins are phenolic polymers of plant origin used in leather tanning, since it binds to the collagen proteins of the skin, increasing its resistance to water, heat, and microorganisms; this property is also responsible for generating astringency when they are consumed. They are often found in barks and other plant tissue. We can find them in food grain such as those of some legumes and fruits, such as grapes, among others [113,114]. There are two categories of tannins: (1) condensates and (2) hydrolysable (Figure 4). Condensed tannins are compounds formed by the union of flavonoid units of the catechin or flavanonols type. While the hydrolyzable tannins are heterogeneous polymers made up of phenolic acids, mainly gallic acid and simple sugars as the central core; these are smaller than condensed tannins and can be easily hydrolyzed with dilute acids. The strong bond that exists between tannins and proteins is the reason for the indigestibility of these compounds and causes them to be considered without nutritional value; in addition, they can cause a decrease in intake, growth rate, and energy obtained through food, especially in populations whose diets are based on legumes [115].
Table 1 shows an example of a bioactive tannin, its source, and the most common spectroscopic and spectrometric methods for its identification and quantification.
  • Terpenes and terpenoids
Terpenes and terpenoids are a group of metabolites widely distributed in nature made up of repeating isoprene units. The compounds of this group comply with the so-called “isoprene rule”, which says that terpenes are made up of an integer number of isoprenes joined “head-to-tail” or “head-to-head”. However, there are exceptions to this rule derived from some rearrangements that can undergo throughout their biosynthesis. Those compounds that do not strictly comply with this rule, but their structures are modified by one or more rearrangements, are known by the name of terpenoids. These compounds can be cyclic or open-chain and are classified according to the number of isoprenic units that form them: monoterpenes (2 units), sesquiterpenes (3 units), diterpenes (4 units), sesterpenes (5 units), triterpenes (6 units), and tetraterpenes (8 units) (Figure 5). Terpenes have shown a wide variety of biological activities such as antimicrobial [116], anti-inflammatory [117], immunomodulatory [118], anticancer [119] activities. Table 1 shows an example of a terpene, its biological activity, the source of this compound, and some common spectroscopic and spectrometric methods used for its identification and quantification.
More recently, we have been working on the extraction and stabilization of other bioactive compounds, particularly in carotenoids from mamey (Pouteria sapota) and carrot (Daucus carota). These compounds can be spectrophotometrically measured from the extracts obtained from the nonpolar extraction with a mixture of solvents hexane-acetone-ethanol. Once extracted, the sample was saponified, and the upper layer was recovered with ethanol to be concentrated in a rotary evaporator. The sample was then analyzed at 450 nm, and the results were compared to a calibration curve prepared using pure β-carotene. Similar to the analysis performed on the anthocyanins, the carotenoid extracts were tested for antioxidant activity to evaluate the potential use of these vegetal products as beneficial foods with excellent results (data unpublished).
As mentioned earlier, Žilić et al. [86] isolated phenolic compounds and carotenoids from ten different colored maize genotypes. The carotenoids from the maize samples were identified and quantified following the methodology proposed earlier [120]. The carotenoids were extracted from the milled grain by adding Na2CO3 and a mixture of methanol/tetrahydrofuran and continuous stirring. The supernatant of the mixture was evaporated and redissolved in the mixture of methanol/tetrahydrofuran to be analyzed by HPLC with a photodiode array detector and a C18 column. The maize samples exhibited the presence of lutein and b-carotene, which were identified by the comparison of the HPLC profiles against the curves previously prepared with the pure standards. As exposed by the authors, the findings of the carotenoid content of maize, particularly provitamin A or b-carotene, reveals the importance of these bioactive compounds in preparing functional foods. One example could be trying to diminish the levels of incidence of vitamin A deficiency, associated with acquired blindness in children, growth retardation, and anemia [121].
  • Resins
Resins are complex mixtures of compounds such as monoterpenes, diterpenes, triterpenes, polysaccharides, fatty acids, and esters. The compound that prevails depends on the type of resin—for example, mono- and diterpenes prevail in copal resin, polysaccharides, proteins, and terpenes in myrrh, mono- and sesquiterpenes, abietic acid, and other organic acids in turpentine. Some of these resins, such as copal, are used in traditional Mexican medicine to cure headaches, diarrhea, and as anti-inflammatory [122] and in some religious rites. Copal resin contains mono- and sesquiterpenes in its volatile part and triterpenes in its nonvolatile part and may also contain lignans [123]. Myrrh essential oil has antifungal properties [124]. Figure 6 shows the structures of two representative resins, curzerene and 13-epi-manool; additionally, Table 1 exhibits one example of a bioactive resin, its source, and the spectroscopic and spectrometric methods used for its analysis.
  • Lignans
Lignans are dimeric phenylpropanoids derived from phenylalanine through cinnamic acid and p-coumaric acid (Figure 7). The monomers of the lignans can be synapic acid, ferulic acid, caffeic acid, p-coumaryl alcohol, coniferyl alcohol, and synapyl alcohol. Ligans such as podophyllotoxin have been used to treat different cancers [125] as well as other lignans [126]. Table 1 shows an example of bioactive lignan, its source, and the spectroscopic and spectrometric methods used for its analysis.
Lignins are formed essentially by oxidative polymerization of various cinnamyl alcohols, corresponding to cinnamic acid. Phenylpropanols are joined to form the polymer by the action of enzymes called peroxidases that catalyze the oxidation of alcohols generating free radicals that combine in non-enzymatic and random processes to give lignin; resulting in a complex and branched structure in all three dimensions. As there is no common repeating unit as in starch, rubber, or cellulose, each lignin molecule can be unique.
  • Alkaloids
Alkaloids are nitrogenous organic compounds found in 20% to 30% of vascular plants. Nitrogen is generally part of a heterocyclic ring. Its name derives from the fact that most of these compounds are alkaline. At the pH where they are generally found in the cell (pH = 5–7), nitrogen is protonated, so the alkaloid is positively charged and is generally soluble in water. Alkaloids are classified according to their basic structures into derivatives of pyrrolidine, tropane, piperidine, pyrrolizidine, quinolizidine, isoquinoline, and indole (Figure 8). Among the bioactivities they possess are those that affect the central nervous system causing different types of reactions, from sedation, hallucination, and even death. However, there are several that are used in medicine as anesthetics [127], in the treatment of cardiovascular diseases [128]; others showed cytotoxic activity in tumor cells [129]. Table 1 summarizes the biological activities of one alkaloid, its source, and methods of identification.
  • Furanocoumarins and naphthodianthrones
Furanocoumarins are heterocyclic compounds that contain a furan ring fused to a coumarin (Figure 9). Furancoumarins such as marmesin are derived from prenylated coumarins and these originate from the ortho-hydroxylation of cinnamic acid, which is rare. Psoralens have been considered to be the phytoalexins that give celery resistance against pathogens, it has also been shown that marmesin (a precursor of psoralens) has antifungal activity in vitro 100 times greater than psoralens. Furthermore, as celery became more susceptible to the pathogen during storage, psoralen levels increased, while marmesin levels decreased. From this, it follows that marmesin is the compound that gives celery resistance against pathogens [130]. Psoralen acts as a skin photosensitizer, causing erythema and darkening of the skin.
On the other hand, naphthodiantrones are compounds that derive from the polyketide biosynthetic pathway to produce a compound with two anthrone structures fused to a naphthalene skeleton (Figure 9). One of the most relevant compounds of this group is hypericin, which is responsible for the antidepressant, anticancer and antiviral activities of different species of the genus Hypericum [131]. Table 1 shows the biological activity, sources, and methods of identification for a furanocoumarin and a naphtodianthrone.
  • Proteins and peptides
Proteins are polymers of amino acids linked by amide bonds called peptide bonds (Figure 10). Proteins can weigh several tens of thousands of daltons and have very varied functions, many of them are specific in an organism, such as the case of enzymes. On the other hand, short chains of amino acids are called peptides or polypeptides. Some organisms can use nonprotein amino acids, known as “rare amino acids” to produce small polypeptides that are toxins such as phalloidin or amanitins, which inhibit RNA polymerase. Amanitins, from Amanita phalloides, are toxins from this fungus that inhibit protein synthesis in mammals; within 6–15 h of ingestion, they cause violent gastroenteritis, fever, tachycardia, hyperglycemia, alteration in electrolyte balance, and liver and kidney dysfunction. They can be lethal. Some of these “rare amino acids” are octopine and nopaline derived from arginine and found in plasmids of Agrobacterium tumefaciens, a tumor-causing pathogen (crown galls) in legumes. Other examples of these amino acids are canavanine, 3,4-dihydroxyphenylalanine, 5-hydroxytryptophan, azetidine-2-carboxylic acid. A characteristic of these “rare amino acids” is that they are very similar to the amino acids used for the biosynthesis of proteins—for example, canavanine with arginine; azetidine-2-carboxylic acid with proline. This means that, in some cases, the toxicity is due to an error in the incorporation of nonprotein amino acid, being mistaken for a protein one, which originates from a nonfunctional protein either because its tertiary structure was modified or because it produced some other change that affects its catalytic property. As extra data, the isoelectric point of canavanine is 8.2, which makes this amino acid much less basic than arginine, whose isoelectric point is 10.8, which could affect the ability of the enzyme to bind to the substrate or catalyze chemical reactions. Table 1 exemplifies a bioactive peptide isolated and characterized recently.
  • Extraction of bioactive compounds from plants
The obtaining of raw material from plants to evaluate the presence of active principles with beneficial effects on human health is a critical task for researchers. Diverse techniques have been used to obtain biologically active molecules from plants. These applications involve the use of solvents capable of interacting due to their chemical properties. This is the case of the use of critical supercritical fluid extraction (SFE) and pressurized liquid extraction (PLE) methodologies, which, in recent years, have gained notoriety for their ample yields in the extraction of bioactive compounds without causing degradation [132]. Other eco-friendly methodologies have been also applied in this regard—for example, the use of eutectic solvents (DESs) for rapid mechano-chemical extraction of bioactive molecules [133]. Table 2 shows some methodologies used for the extraction of bioactive molecules from plants, their fundaments, and some examples of sources.

3. Conclusions

Our group has been working successfully with diverse vegetal extracts rich in polyphenols and anthocyanins, which have nutraceutical properties that are relevant in the food industry. The separation and the quantification of separation by chromatographic methods such as GC and HPLC combined with spectroscopic and spectrometric techniques, such as UV–vis, IR, and MS, are relevant in the characterization and quantification of natural polyphenols, anthocyanins, and synthetic derivatives, as we have shown through several examples.

Author Contributions

All authors contributed equally to this work. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data of this article are available from the corresponding author upon reasonable request.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. The chemical structures for some glycosides.
Figure 1. The chemical structures for some glycosides.
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Figure 2. The general structures for flavonoids and proanthocyanidins.
Figure 2. The general structures for flavonoids and proanthocyanidins.
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Figure 3. The general structure of anthocyanins and most representative molecules with their substituents. Adapted from [49].
Figure 3. The general structure of anthocyanins and most representative molecules with their substituents. Adapted from [49].
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Figure 4. The structures of the main constituents of hydrolyzable tannins and condensed tannins.
Figure 4. The structures of the main constituents of hydrolyzable tannins and condensed tannins.
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Figure 5. Examples of some terpenes and terpenoids.
Figure 5. Examples of some terpenes and terpenoids.
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Figure 6. The chemical structure for curzerene and 13-epi-manool, components of myrrh and copal resins, respectively.
Figure 6. The chemical structure for curzerene and 13-epi-manool, components of myrrh and copal resins, respectively.
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Figure 7. The chemical structure for lignans.
Figure 7. The chemical structure for lignans.
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Figure 8. The chemical structure for some bioactive group of alkaloids.
Figure 8. The chemical structure for some bioactive group of alkaloids.
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Figure 9. The chemical structures for hypericin (a naphthodianthrone) and furanocoumarin.
Figure 9. The chemical structures for hypericin (a naphthodianthrone) and furanocoumarin.
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Figure 10. The chemical representation for a peptide.
Figure 10. The chemical representation for a peptide.
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Table
Table 1. Some bioactive compounds from plants, their properties, and the methodologies used for their identification and quantification.
Table 1. Some bioactive compounds from plants, their properties, and the methodologies used for their identification and quantification.
GroupExampleSourceActivityReferencesMethods
GlycosidesCardenolideNerium oleanderAnti-inflammatory, anticancer[11]IR, UV–vis; HPLC-UV–vis NMR
FlavonoidsSilibininSilybum marianumAnti-inflammatory, anticancer[12,13,14,15]IR; HPLC-UV–vis; LC-MS
ProanthocyanidinsA- and B-typeCranberry, bilberry, curry, cinnamon, teaAnti-inflammatory, anticancer, anti-microbial, hypolipidemic[16,17]IR; NMR; FT-ICR-ESI-MS-MS; UPLC-IM-HR-MS
StilbenoidsResveratrolGrape, apple, berries, pistachios, peanutsAnti-inflammatory, anticancer; anti-microbial, anti-diabetic[18,19]HPLC-UV–vis; UPLC-MS-MS; NMR
TanninsEllagitanninsSorghum, apple, grapeAnti-inflammatory, anticancer, antimicrobial, antiviral[20,21]HPLC-UV–vis; NMR; HPLC ESI-MS-MS
MonoterpenoidsLimoneneQuercus ilexAnti-inflammatory, anticancer[22,23,24]FGC-PTR-MS; NMR
SesquiterpenoidsZerumboneZingiber zerumbetAnti-inflammatory, anticancer, antimicrobial, antipyretic[25,26]GC-MS; IR, NMR; ESI-MS
PhenylpropanoidsCoumarinsArtemisa annuaAnti-inflammatory, anticancer, antimicrobial, antiviral, antiparasitic[27,28]HPLC-UV–vis; LC-ESI-QTOF-MS-MS
DiterpenoidsColumbinJateorhiza columbaAnalgesic, antipyretic[29,30]NMR; LC-MS; UPLC-HR-MS
Tetraterpenoids (Carotenoids)α- and β-caroteneCarrot, cantaloupe, tomatoAntioxidant, chemopreventive[31,32]HPLC-UV–vis; HPLC-ESI-MS-MS; GC-MS
ResinsStytonkinol A and BStyrax benzoinAntimicrobial, antifungal[33,34]IR; UV–vis; NMR
LignansDibenzylbutanePhyllanthus niruriAntiviral, antioxidant[35,36]HPLC–DAD–ESI–QTOF–MS; NMR
AlkaloidsTriangularineAsteraceae familyAnti-inflammatory, antioxidant, antimicrobial, anesthetic[37,38]HPLC-UV–vis: LC-MS-MS; NMR
FurocoumarinesBergamottinGrapefruit, orangeAnticancer[39,40]UV–vis; UPLC-MS-MS
NaphthodianthronesHypericinHypericum triquetrifoliumAnti-inflammatory, anticancer, antimicrobial, antiviral, antidepressant[41,42]UPLC-ESI-MS-MS
PeptidesSesquinVigna sesquipedalisAnticancer[43,44]IR; MALDESI-MS-MS
ProteinsLectinsRicinus communisAntimicrobial[45,46]LC-QTOF-MS-MS
Abbreviations: Diode array detection (DAD); Electrospray ionization (ESI), Flash gas chromatography (FGC), High-resolution (HR), Matrix-assisted laser desorption electrospray ionization (MALDESI), Proton transfer reaction (PTR), Quadrupole time-of-flight (QTOF), and Ultra-high-performance liquid chromatography (UPLC).
Table
Table 2. Extraction techniques for the obtaining of bioactive compounds from plants.
Table 2. Extraction techniques for the obtaining of bioactive compounds from plants.
Method of Extraction and FundamentalsBioactive Compound Plant SourceReference
Maceration extraction (ME):Flavonoid glycosideGinkgo biloba[132,134,135]
The plant material is soaked with solvent in a container and left to stand for a minimum of three days with agitation. The cell wall softens, releasing the desired material.
Soxhlet extraction (SE):Cafestol and kahweol (diterpenes)Coffea arabica[136,137]
The sample is put on a porous filter inside a Soxhlet apparatus chamber. The solvent is heated reaching its boiling point and passes through the matrix extracting the desired compound. The solvent is condensed reaching a volume allowing a siphon effect, thus continuously using the solvent for the extraction.
Ultrasound-assisted extraction (UAE):Resveratrol (flavonoid)Polygonum cuspidatum[138,139]
Waves of high frequencies and longer wavelengths propagating through the medium, causing compression and rarefaction. Bubbles generated are unstable with contracts, collapsing, thus causing cavitation effect that cause cell disruption and improved solvent penetration to the matrix.
Microwave-assisted extraction (MAE):Berberine and palmatine (alkaloids)Berberis jaeschkeana[134,139]
Uses microwave energies that interact with dipoles of polar solvents and samples causing heat and allowing the solvent penetration to the matrix. For nonpolar solvents, heating is poor and there is a transfer of the energy by dielectric absorbing.
High-pressure-assisted extraction (HPAE):Condensed tanninStevia rebaudiana[136,140]
High-applied pressure led to increased solubility and produces an increase in permeability. Solvent penetration into the cell is promoted and more target compounds can permeate the cell membrane, facilitating the extraction process.
Supercritical fluid extraction (SFE):Euglenol, beta-caryophyllene, alpha-humulene (terpenoids)Clove[132,140,141,142]
Uses mainly, CO2 as the solvent, which is fluid at 31 °C and 74 bar, dissolving CO2 soluble compounds from plants. A variant is the use of water (SWE) at 100–374 °C and high pressures to maintain water liquid, allowing to extract polar constituents.
Pulsed electric field extraction (PEFE) and high voltage electrical discharge extraction (HVED):Carotenoids and flavonoidsCitrus fruits[139,143,144]
Pulses of electricity under high-intensity electric fields are applied to the samples. The cell membranes generate pores that allow the release of intracellular components to the media.
Cold plasma extraction (CPE):PolyphenolsWolfberry[139,144,145]
Cold plasma causes cell wall damage, an effect that results in the release of active molecules from the cell.
Rapid solid–liquid dynamic extraction (RSLDE):Phenolic acidsMoringa oleifera[139,146,147]
Uses a solid–liquid extractor working at 8–9 bar. Requires water as a solvent and is based on the principle of pressure/depression.
Eutectic solvent extraction (ESE):Rosin (phenylpropanoid)Rhodiola rosea L.[133,148,149]
Uses environmentally friendly solvents for the extraction of bioactive compounds from plants. This kind of solvents is prepared when two solid compounds are mixed under certain conditions to diminish their melting points to a point low to form a eutectic mixture with specific physicochemical characteristics.
Enzyme-assisted extraction (EAE):
Pretreatment for the extraction that uses enzymes with specific activities, promoting disruption of the cell wall of the plant material to enhance or facilitate the solvent extraction of the biologically active compound.ProanthocyanidinsGrapes[150,151]
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Lozada-Ramírez, J.D.; Ortega-Regules, A.E.; Hernández, L.R.; Anaya de Parrodi, C. Spectroscopic and Spectrometric Applications for the Identification of Bioactive Compounds from Vegetal Extracts. Appl. Sci. 2021, 11, 3039. https://0-doi-org.brum.beds.ac.uk/10.3390/app11073039

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Lozada-Ramírez JD, Ortega-Regules AE, Hernández LR, Anaya de Parrodi C. Spectroscopic and Spectrometric Applications for the Identification of Bioactive Compounds from Vegetal Extracts. Applied Sciences. 2021; 11(7):3039. https://0-doi-org.brum.beds.ac.uk/10.3390/app11073039

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Lozada-Ramírez, José Daniel, Ana E. Ortega-Regules, Luis Ricardo Hernández, and Cecilia Anaya de Parrodi. 2021. "Spectroscopic and Spectrometric Applications for the Identification of Bioactive Compounds from Vegetal Extracts" Applied Sciences 11, no. 7: 3039. https://0-doi-org.brum.beds.ac.uk/10.3390/app11073039

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