Characterization by near infrared spectroscopy of seeds and oils of <i>Amaranthus</i> spp. as a function of cropping systems

Mavaieie, Denilson Paulo da Rosa; Souza, Douglas Correa de; Ramalho, Fernanda Maria Guedes; Mavaieie, Valquíria de Fatima Ferreira; Resende, Luciane Vilela; Guimarães, Renato Mendes

doi:10.1590/0034-737X202370030004

ABSTRACT

Species of the Amaranthus genus are very versatile and have potential for the application in the development of commercial products. The near infrared spectroscopy (NIR) is an efficient tool that can help in the quality control of products, quickly and non-destructive to the sample. The goal of this study was to carry out the distinction of seed and oils of different Amaranthus species using the near infrared spectroscopy. Three species were used: A. viridis L., A. hybridus L. e Amaranthus sp. (commercial). The spectra acquired from the sample using the near infrared spectroscopy were submitted to the partial least squares discriminant analysis (PLS-DA) and to the principal component analysis (PCA). Through PCA, it was possible to differentiate the Amaranthus species both for seeds and oils. Through PLS-DA, it was possible to predict the classes of the species with high degree of correct classification, with 96.67% of correct classifications for seeds and 98.89% for oil. Thus, with the use of the near infrared spectroscopy associated with the multivariate statistical analysis, it is possible to classify the different Amaranthus species, especially when using the oil.

Keywords
non-conventional vegetable; partial least squares discriminant analysis; principal component analysis

INTRODUCTION

With the increasing use of medicinal plants or plants that are considered functional foods, quality control has been of paramount importance when analyzing from the market perspective, to avoid adulteration and control quality according to current regulations (Gobbo-Neto & Lopes, 2007Gobbo-Neto L & Lopes NP (2007) Plantas medicinais: fatores de influência no conteúdo de metabólitos secundários. Química Nova, 30:374-381.). Normally, chromatographic analysis is used to have absolute assurance that it really is the referenced species in terms of its chemical composition. Chromatography is an expensive technique and takes time to perform (Parys et al., 2019Parys W, Pyka-Pajak A & Dołowy M (2019) Application of Thin-Layer Chromatography in Combination with Densitometry for the Determination of Diclofenac in Enteric Coated Tablets. Pharmaceuticals, 12:183.). In this way, the identification of fast and preferably non-destructive techniques that can prove the presence and content of chemical compounds and, in turn, guarantee the quality and origin of the product are desirable.

Of the various techniques available, Near Infrared Spectroscopy (NIR) has shown promise in qualitative and quantitative analysis, being widely used in the area of chemistry of natural products and organic transformations (Lima & Bakker, 2011Lima A & Bakker J (2011) Near-infrared spectroscopy for monitoring peripheral tissue perfusion in critically ill patients. Revista Brasileira de Terapia Intensiva, 23:341-351.). It has advantages because it is a non-destructive technique, performed in a relatively short time (Agelet et al., 2012Agelet LE, Armstrong PR, Clariana IR & Hurburgh CR (2012) Measurement of single soybean seed attributes by near infrared technologies. A comparative study. Journal of Agricultural and Food Chemistry, 60:8314-8322.), with wide acceptance in different fields. Vis-NIR spectroscopy is often used in combination with chemometric and multivariate analyzes that are selected based on the objectives of the study (Sohn et al., 2021Sohn SI, Oh YJ, Pandian S, Lee YH, Zaukuu JLZ, Kang HJ, Ryu TH, Cho WS, Cho YS & Shin EK (2021) Identification of Amaranthus Species Using Visible-Near-Infrared (Vis-NIR) Spectroscopy and Machine Learning Methods. Remote Sens, 13:4149-4162.).

The genus Amaranthus contains about 70 species (Singh, 2017Singh AK (2017) Early History of Crop Introductions into India: II. Amaranthus (L.) spp. Asian Agri-History, 21:319-324.), widely known and consumed around the world. However, it is almost unknown in Brazil for food or medicinal use, it being recognized only as a weed, whose control significantly impacts the production cost of cultures (Jimoh et al., 2022Jimoh MO, Okaiyeto K, Oguntibeju OO & Laubscher CP (2022) A Systematic Review on Amaranthus - Related Research. Horticulturae, 8:239-256.). The most commonly found species in most of the arable areas of Brazil, are A. viridis, A.spinosus, A. deflexus, A. hybridus, A. retroflexus and A. lividus (Bayón, 2022Bayón ND (2022) Identifying the weedy amaranths (Amaranthus, Amaranthaceae) of South America. Advances in Weed Science, 40:e0202200013.). However, studies with the species of widespread occurrence in Brazil are still incipient.

Species of the genus have shown great potential as a source of nutritional and medicinal compounds due to the chemical composition present in leaves, roots, inflorescences, grains and oils. It is rich in bioactive compounds such as phenolic acids, polyphenols, unsaturated fatty acids, glucosinolates, proteins, soluble peptides, flavonoids, squalene, beta-carotene and others (Parveen et al., 2014Parveen M, Chattopadhyay NC & Tah J (2014) Strategy of biometric evaluation of vegetative yield attributes of amaranth cultivars. Bioscience Discovery, 5:70-73.; Silva et al., 2018Silva LF, Souza DC, Resende LV, Nassur RCMR, Samartini CQ & Gonçalves WM (2018) Nutritional Evaluation of Non-Conventional Vegetables in Brazil. Anais da Academia Brasileira de Ciências, 90:1775-1787.; Xavier et al., 2018Xavier JB, De Souza DC, De Souza LC, Guerra TS, Resende LV & Pereira J (2018) Nutritive potential of amaranth weed grains. African Journal of Agricultural Research, 13:1140-1147.; Mir et al., 2018Mir NA, Riar CS & Singh S (2018) Nutritional constituents of pseudo cereals and their potential use in food systems: A review. Trends in Food Science & Technology, 75:170-180.; Xavier et al., 2019aXavier JB, Castro DG, Silva DM, Abreu RAA, Souza DC & Silva MLS (2019a) Eficiência de absorção de nutrientes em Amaranthus spp. Magistra, 30:199-210.). Grains are rich in protein, essential amino acids, fiber, minerals and vitamins and oil (Sá et al., 2020Sá AGA, Moreno YMF & Carciofi BAM (2020) Plant proteins as high-quality nutritional source for human diet. Trends in Food Science & Technology, 97:170-184.). When compared to oil seeds, the oil content in amaranth is low, however it has a high concentration of unsaturated fatty acids and squalene, a potent natural antioxidant, widely used in the cosmetics industry for skin hydration as an emollient in vaccines, in addition to having antitumor activity and cardioprotective (Srivastava, 2017Srivastava R (2017) An updated review on phyto-pharmacological and pharmacognostical profile of Amaranthus tricolor: A herb of nutraceutical potentials. The Pharma Innovation Journal, 6:124-129.). Amaranth seed oil has been suggested as an alternative to animals as a natural source of squalene.

The content and diversity of secondary metabolites present in plants show a strong interaction with the environment. Climatic conditions, the type of cultivation and the species are factors that can change the content and chemical composition of extracts and oils in plant species. In Amaranthus, the NIR technique associated with multivariate analysis was used to determine the chemical composition of leaves and extracts, on postharvest betacyanin degradation, on seed germination in the identification and classification of species (Matzrafi et al., 2017Matzrafi M, Herrmann I, Nansen C, Kliper T, Zait Y, Ignat T, Siso D, Rubin B, Karnieli A & Eizenberg H (2017) Hyperspectral Technologies for Assessing Seed Germination and Trifloxysulfuron-methyl Response in Amaranthus palmeri (Palmer Amaranth). Frontiers in Plant Science, 8:474-787., Silva et al., 2018Silva LF, Souza DC, Resende LV, Nassur RCMR, Samartini CQ & Gonçalves WM (2018) Nutritional Evaluation of Non-Conventional Vegetables in Brazil. Anais da Academia Brasileira de Ciências, 90:1775-1787.; Silva et al., 2019Silva LF, Souza DC, Xavier JB, Samartini CQ & Resende LV (2019) Avaliação nutricional de caruru (Amaranthus spp.). Agrarian, 12:411-417.; Xavier et al., 2019bXavier JB, Andrade DB, Castro DG, Guimarães GC, Resende LV & Guimarães RM (2019b) Morphological, chemical and physiological characterization of Amaranthus spp. Seeds. Journal of Seed Science, 41:478-487.; Silva et al., 2021Silva LF, Souza, DC, Nassur RCMR, Bittencourt WJM, Resende LV & Gonçalves WM (2021) Nutritional characterisation and grouping of unconventional vegetables in Brazil. The Journal of Horticultural Science & Biotechnology, 96:508-513., Sohn et al., 2021Sohn SI, Oh YJ, Pandian S, Lee YH, Zaukuu JLZ, Kang HJ, Ryu TH, Cho WS, Cho YS & Shin EK (2021) Identification of Amaranthus Species Using Visible-Near-Infrared (Vis-NIR) Spectroscopy and Machine Learning Methods. Remote Sens, 13:4149-4162.). Studies using NIR to characterize Amaranth oil are scarce.

Therefore, the aim of this work was to evaluate the efficiency of near-infrared (NIR) spectroscopy in determining the chemical composition of oil and seed from different cultivation systems and the technical potential to distinguish Amaranth species.

MATERIAL AND METHODS

The experiment was performed with seeds of Amaranthus obtained from UFLA’s (Federal University of Lavras) germplasm collection of non-conventional vegetables in Lavras, Minas Gerais (21º14’S, 45º00’W and altitude of 918 m). The climate of the region is Cwa (mesothermal) with dry winter and rainy summer, according to the Köppen classification (Álvares et al., 2013Álvares CA, Stape JL, Sentelhas PC, Gonçalves JLM & Sparovek G (2013) Koppen’s climate classification map for Brazil. Meteorologische Zeitschrift, 22:711-728.).

The test was arranged in the field in a randomized block design (RBD) with three replications, in a factorial scheme 2x3, [planting systems (organic and conventional) Amaranthus species (A. viridis L., A. hybridus L. and Amaranthus sp. -commercial species)]. The materials were identified through exsicattes by EPAMIG (Agricultural Research Company of the State of Minas Gerais), being recorded and included in the EPAMIG Herbarium of Minas Gerais (PAMG) herbarium collection number 58002, 58003 and 57999, respectively.

The seeds were directly sown in the field in the spacing of 0.5m x 0.5m, and, later, the thinning was performed with density of 40,000 plants per hectare without the use of irrigation. Following soil analysis, the correction of acidity and the fertilizing were performed in accordance with the recommendation for the culture (Brasil, 2013Brasil - Ministério da Agricultura, Pecuária e Abastecimento (2013) Manual de Hortaliças Não Convencionais. Brasília, MAPA/ACS. 99p.).

In the organic cultivation system, dolomitic limestone, chicken manure (before seeding) and organic compost (40 days after seeding) were used. The application of plant extracts of Ricinus communis L., with insecticidal and fungicidal principles, was carried out for the phytosanitary control (Xavier et al., 2018Xavier JB, De Souza DC, De Souza LC, Guerra TS, Resende LV & Pereira J (2018) Nutritive potential of amaranth weed grains. African Journal of Agricultural Research, 13:1140-1147.). In the conventional cultivation system, dolomitic limestone, urea, simple superphosphate and potassium chloride were used. The cultivation and the phytosanitary control were performed in accordance with the needs of the culture (Brasil, 2013Brasil - Ministério da Agricultura, Pecuária e Abastecimento (2013) Manual de Hortaliças Não Convencionais. Brasília, MAPA/ACS. 99p.).

The border effect was taken into consideration in order to avoid the influence of the neighbor portions on the treatments. Besides, a physical barrier was used with the maize culture to avoid crossing among species once polyploidy interspecific hyperbridization is common in these species, and hide their characteristics (Olusanya, 2017Olusanya AC (2017) A multi-species assessment of genetic variability in Nigerian Amaranthus accessions: potential for improving intra-and interspecies hybridization breeding. Archives of Agronomy and Soil Science, 64:621-625.).

After harvesting, the drought and processing of seed was performed manually. Then, they were packed in multi-layer Kraft paper and stored in cold chamber (10 °C and 40% of relative air humidity). For the obtaining and quantification of oil, four replications were employed for each treatment. The oil was extracted from the seeds of different Amaranthus spp. species in accordance with the Vasconcelos et al. (2018)Vasconcelos MC, Oliveira AS, Granja JAA, Costa JC & Guimarães RM (2018) Diferenciação de cultivares de girassol por espectroscopia no infravermelho próximo e análise multivariada, utilizando sementes e óleo. Revista Brasileira de Ciências Agrarias, 13:e5582. methodology. One hundred and fifty grams of dry and crushed seed were used per treatment.

The spectra of the seeds and oils were acquired in the near infrared (NIR) using a spectrometer based at the Fourier transform (Bruker, model MPA) alongside the OPUS_Spectroscopy software version 7.0. The spectra were collected from the range of 9.995 cm^-1 and 4.000 cm^-1 directly in the surface of each portion of the seed samples through optical fiber and oil in a cuvette. The spectra in NIR were registered in diffuse reflection mode with spectral resolution of 8 cm^-1 using 32 sweeps for the background (reference spectrum) and 16 sweeps per sample. Thus, a spectrum was registered for each sample totaling 66 spectra from seed with conventional fertilizing (3 species x 22 replications), 34 from seeds with organic fertilizing (3 species x 15 replications), and 45 from organic oils (3 species x 15 repetitions).

The spectra collected from seeds and oils were selected in the wavelength in the range of 9.995 cm^-1 and 4.000 cm^-1 and submitted to the principal component analysis (PCA) and to the partial least squares discriminant analysis (PLS-DA). The analyzes were performed using Chemoface version 1.61 (Nunes et al., 2012Nunes CA, Freitas MP, Pinheiro ACM & Bastos SC (2012) Chemoface: a novel free user-friendly interface for chemometrics. Journal of the Brazilian Chemical Society, 23:2003-2010.).

The principal component analysis was performed with the objective of verifying the similarities among the samples analyzed. This analysis was performed with treated (first derivative, multiplicative scatter correction, standard normal variate and normalization) and non-treated spectra, and a two-dimensional graph was generated for score plot.

The PLS-DA was performed in order to generate predictive models for classification of the three species of seeds in the cultivation conditions (six classes) and its respective extracted oils (six classes). The adequate number of latent variables was defined by cross-validation. The models generated were evaluated by the number and percentage of hits in the predicted classes.

RESULTS

Near infrared spectroscopy

Spectruns collected in the NIR was registered for the seeds (Figure 1A) and for the oil (Figure 1B) of each Amaranthus species in the different cultivation systems with each spectrum representing the average of various samples. There was a similar spectrum pattern regarding absorbance peaks. In the entire wavelength range adopted, the spectra of oil and seed showed similar absorption bands among species and different among seeds and oils, regardless of the cultivation system.

In the seeds, the absorbance peaks were concentrated in the range between 7044 and 5077 cm^-1 (Figure 1A). The spectra of the species from the organic cultivation system showed higher absorbance peaks when compared to the conventional system, except for A. hybridus. In the oil, the absorbance peaks were concentrated in the range between 6060 and 4000 cm^-1. In this case, the species A. viridis and A. hybridus presented the highest absorbance peaks in the conventional system while Amaranthus sp. (commercial) showed more intense bands in the organic system. However, evidencing the greater interaction between the near infrared radiation and the probable functional groups of the A. species (Figure 1B) making evident the greater interaction between the near infrared radiation and the probable functional groups of the A. species (Figure 1B).

Using the Practical Guide and Spectral Atlas for Interpretive Near-Infrared Spectroscopy (Workman Júnior & Weyer, 2012Workman J & Weyer L (2012) Practical Guide and Spectral Atlas for Interpretive Near Infrared Spectroscopy. 2º ed. Boca Raton, CRC Press. 326p.), it was possible to infer about the identification of chemical functional groups (Table 1) present in the grains and oils of the species in the different cultivation systems. There was a specific absorption band at certain wavelengths corresponding to compounds such as aliphatic hydrocarbons, polysaccharides, water and lipids in addition to aromatic hydrocarbons and proteins in the oil.

Principal Components Analysis – PCA

After the construction of the calibration models, the factorial distribution of the spectra through NIR was carried out based on the PCA analysis in order to detect differences among the species and cultivation systems.

The principal components analysis (PCA) was carried out starting from the seeds spectra (Figure 1) aiming at evaluating the spectral similarity in the behavior of the species and the similarities among the cultivation systems of the materials studies. In order to focus on the most interesting answers, only the results of the analyzes with the spectra without treatments were presented.

The PCA scores for the three species of Amaranthus seeds in the organic and conventional systems were plotted in the two-dimensional graph (Figure 2A) in which the sum of the principal component 1 (PC1) and principal component 2 (PC2) explain 99.95% of the data variation. In the PCA that only used the conventional (Figure 2B) and the organic (Figure 2C) cultivation system, the sum of PC1 and PC2 obtained explanation of 99.99% and 99.97% of the data variation, respectively.

Figure 1
Average of the spectra obtained through spectroscopy in the near infrared in the different Amaranthus species and cultivation systems using (A) seeds and (B) oils.

After the analyzes with all the treatments in different cultivation systems (Figure 2A), PCA clearly separated the species A. viridis in the conventional system, A. viridis in the organic system and A. hybridus in the organic system. These results showed that the spectral range allowed the separation of species in their respective cultivation systems. An exception can be observed in the overlapping of the spectra of A. hybridus cultivated in the conventional system and Amaranthus sp. (commercial) in the organic cultivation. This shows that there is a spectral similarity between these two materials.

For the oil, the principal components analysis (PCA) of the spectra was carried out without treatment (Figure 3A) and treated (Figure 3B). In the graph of the scores (Figure 3A) of the PCA using spectra without treatment of the oils of different species of Amaranthus, the first principal component (PC1) explained 97.97% of the total data variation. The second principal component (PC2) explained only 1.84% of the variation, and the sum of both explains 99.74% of the data variation.

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Table 1
Correlation spectrum-structure by near infrared spectroscopy for the different cultivation seeds of Amaranthus seed and oil

Figure 2
Principal Components Analysis (PCA) of the spectra without treatment in seeds of different Amaranthus species in different cultivation systems: conventional and organic (A), conventional cultivation (B) and organic (C).

Figure 3
Principal component analyzes of the spectra without treatment (A) and treated by the Multiplicative Scatter Correction (B) of oils of different Amaranthus species and cultivation systems.

For the oil samples of the different Amaranthus species with treated data (Figure 3B), PC1 explained 99.64% of the total data variation. PC2 explained only 0.31% of the variation in a total of 99.95% of total data variation.

According to the PCA results for the spectra not treated (Figure 3A) for the oils extracted from the seeds, it was not possible to distinguish the species clearly. Therefore, it was possible verify a grouping of almost all the species in the different cultivation systems except Amaranthus sp. (commercial) with grouped separately. However, with the spectra treatment through the Multiplicative Scatter Correction (Figure 3B) it was possible to increase the visualization and distinguish the species in the conventional cultivation system more prominently.

Classification of the different Amaranthus species by PLS-DA

The spectra obtained from the seeds of the different species of Amaranthus were also differentiated when associated with PLS-DA, proving the efficiency of the technique. The validated models generated by the PLS-DA were presented through the number and hit percentage (Table 2).

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Table 2
Classification of the different Amaranthus species and cultivation system through PLS-DA starting from the spectra without treatments measured in the seeds

Of the 90 samples of Amaranthus seeds, 87 were correctly classified, with 96.67% of correct classifications (Table 2). For the species A. viridis and Amaranthus sp. originating from conventional cultivation and A. hybridus and Amaranthus sp from the organic system, 100% accuracy was obtained in the classifications, which corroborates the results of PCA (Figure 3), where most of these species do not mixed with

each other in the different systems. In the other species the error observed was only two. Therefore, such models are considered satisfactory. These results corroborate with the PCA (Figure 2).

Regarding the oil, the classification of species according to the cultivation system by PLS-DA and cross-validation, obtained 98.89% success (Table 3). Almost all species obtained 100% hits.

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Table 3
Classification of the different Amaranthus species in different convention (c) and organic (o) cultivation systems through PLS-DA starting from spectra without treatments measured in oil

DISCUSSION

Near infrared spectroscopy

As observed (Figure 1), both the grains and the oil of the different species, regardless of the cultivation system, showed a similar spectral pattern in relation to the absorbance peaks, but different between the grains and the oil (Figures 1A, 1B), that is, along the adopted wavelength range, both the oil and grain spectra showed different absorption bands in the NIR, however similar among the species.

Using the Practical Guide and Spectral Atlas for Interpretive Near-Infrared Spectroscopy (Workman Júnior & Weyer, 2012Workman J & Weyer L (2012) Practical Guide and Spectral Atlas for Interpretive Near Infrared Spectroscopy. 2º ed. Boca Raton, CRC Press. 326p.), it was possible to infer about the chemical functional groups of the different treatments. According to the spectral correlation, absorption bands were verified in the number of waves corresponding to aliphatic hydrocarbons, polysaccharides, water and lipids, in the grains. Similar compounds were identified in the oil, in addition to aromatic hydrocarbons, proteins and methylene hydrocarbons. Xavier et al. (2019b)Xavier JB, Andrade DB, Castro DG, Guimarães GC, Resende LV & Guimarães RM (2019b) Morphological, chemical and physiological characterization of Amaranthus spp. Seeds. Journal of Seed Science, 41:478-487. identified in seeds of the same species, in addition to the groups observed in this study, aromatic amines and ovalbumin. These differences may be due to the degree of absorption is proportional to the concentration of functional groups in the sample (Curran et al., 1992Curran PJ, Dungan JL, Macler BA, Plummer SE & Peterson DL (1992) Reflectance spectroscopy of fresh whole leaves for the estimation of chemical concentration. Remote Sensing of Environment, 39:153-166.) or to sound noise from the device itself or from the environment (Sohn et al., 2021Sohn SI, Oh YJ, Pandian S, Lee YH, Zaukuu JLZ, Kang HJ, Ryu TH, Cho WS, Cho YS & Shin EK (2021) Identification of Amaranthus Species Using Visible-Near-Infrared (Vis-NIR) Spectroscopy and Machine Learning Methods. Remote Sens, 13:4149-4162.).

Amaranth seed is composed of aliphatic hydrocarbons, lipids, present in the form of triglycerides constituted by unsaturated fatty acids (Marzzoco & Torres, 2017Marzzoco A & Torres BB (2017) Bioquímica básica. 4ª ed. Rio de Janeiro, Guanabara Koogan. 335p.). They are present in the embryo, endosperm and reserve tissue (Carvalho & Nakagawa, 2012Carvalho NM & Nakagawa J (2012) Sementes: Ciência, tecnologia e produção. 5ª ed. Jaboticabal, FUNEP. 588p.). Among the substances belonging to this group is squalene. Studies have proven the beneficial effect of squalene in the cosmetics and pharmaceutical industry (Lozano-Grande et al., 2018Lozano-Grande MA, Gorinstein S, Espitia-Rangel E, Dávila-Ortiz G & Martínez-Ayala AL (2018) Plant sources, extraction methods, and uses of squalene. International Journal of Agronomy, 2018:1829160.). Rats fed with Amaranthus showed reduced cholesterol and this effect was attributed to the presence of squalene (Shin et al., 2004Shin DH, Heo HJ, Lee YJ & Kim HK (2004) Amaranth squalene reduces serum and liver lipid levels in rats fed a cholesterol diet. British Journal of Biomedical Science, 61:11-04.). The aromatic hydrocarbons identified in the oil are the chemical group of antioxidant substances such as complex phenolic compounds such as anthocyanins, flavonoids (flavones and flavonols), isoflavonoids (isoflavones) and tannins. In the oil, the chemical group related to proteins was detected, an important food reserve of the seeds, they constitute important components of the protoplasm and are essential for the formation of new tissues. Polysaccharides were also detected, which belong to carbohydrates that are reserve substances. Amaranth is considered a pseudocereal rich in carbohydrates and low in lipids (Marcos Filho, 2015Marcos Filho J (2015) Fisiologia de sementes de plantas cultivadas. 2ª ed. Londrina, Abrates. 660p.). Vasconcelos et al. (2018)Vasconcelos MC, Oliveira AS, Granja JAA, Costa JC & Guimarães RM (2018) Diferenciação de cultivares de girassol por espectroscopia no infravermelho próximo e análise multivariada, utilizando sementes e óleo. Revista Brasileira de Ciências Agrarias, 13:e5582., correlated the different wavelengths of the spectra to functional groups and, finally, types of compounds in sunflower seeds and oil, as performed in this study.

Principal Components Analysis – PCA

Changes in NIR spectra are often too small to be noticed by the human eye, hence it is often used in combination with various chemometric and multivariate analysis (Sohn et al., 2021Sohn SI, Oh YJ, Pandian S, Lee YH, Zaukuu JLZ, Kang HJ, Ryu TH, Cho WS, Cho YS & Shin EK (2021) Identification of Amaranthus Species Using Visible-Near-Infrared (Vis-NIR) Spectroscopy and Machine Learning Methods. Remote Sens, 13:4149-4162.). Pre-processing techniques are proposed as one of the initial steps in data analysis with the aim of optimizing the results obtained by spectroscopy. For grains, PCA performed with untreated data (Figures 2A, 2b and 2C) considering the two cropping systems together, allowed the separation of species within each cropping system, except for A. Hybridus (conventional) and Amaranthus sp. (organic) (Figure 2A). Considering each system individually, the technique was more efficient in separating the species in the organic system (Figures 2B and 2C). This makes evident that the NIR was sensitive to differences among Amaranthus species.

For oil, considering the untreated data, there was an overlap of groups among some species in the PCA. According to Souza et al. (2017)Souza M, Kuhnen S, Kazama DCS, Kurtz C, Trapp T, Júnior VM & Comin JJ (2017) Predição dos teores de compostos fenólicos e flavonoides na parte aérea das espécies Secale cereale L., Avena strigosa L. e Raphanus sativus L. por meio de espectroscopia no infravermelho próximo (NIR). Química Nova, 40:1074-1081. this overlap may indicate, at first, a similarity in the chemical composition of the species. For the data treated in both cropping systems, the species were grouped separately, clearly demonstrating the difference in the chemical composition of the species as a function of the cropping system. In the organic cropping system (Figure 2B), it was possible to observe that oil Amaranthus sp. differed from the others, which may be related to the typical presence of specific chemical structures in this region. This fact is proven in a conventional system with the same species in which some scores migrated to the same region of the graph (Figure 3B). In Amaranthus the near infrared (NIR) has been successfully used in determination of the chemical composition, in the germination of seeds, in the response to herbicides and in the discrimination of species, where the spectra were obtained from leaves and seeds. However, studies with obtaining NIR spectra in oil are scarce. However, the use of NIR has provided promising results in the analysis of oils from other oilseed species. Monferrere et al. (2012)Monferrere GL, Azcarate SM, Cantarelli MÁ, Funes IG & Camiña JM (2012) Chemometric characterization of sunflower seeds. Journal of Food Science, 77:1018-1022. were successful in differentiating among sunflower species based on oil content by applying PCA in NIR spectra. Souza et al. (2017)Souza M, Kuhnen S, Kazama DCS, Kurtz C, Trapp T, Júnior VM & Comin JJ (2017) Predição dos teores de compostos fenólicos e flavonoides na parte aérea das espécies Secale cereale L., Avena strigosa L. e Raphanus sativus L. por meio de espectroscopia no infravermelho próximo (NIR). Química Nova, 40:1074-1081. applied this analysis in the spectra obtained by NIR generating a model that allowed the detection of differences in the composition of phenolic and flavonoid compounds in Raphanus sativus L., Secale cereale L. and Avena strigosa L. The technique of near infrared spectroscopy was sufficiently accurate to determine the moisture content and protein content of rice and wheat grain (Li et al., 2013Li R, Kawamura S, Fujita H & Fujikawa S (2013) Near-infrared Spectroscopy for Determining Grain Constituent Contents at Grain Elevators. Engineering in Agriculture, Environment and Food, 6:20-26.), biochemical evaluation of sorghum grains for food, feed and fuel without destruction, and complex chemical analysis (Ejaz et al., 2021Ejaz I, He S, Li W, Hu N, Tang C, Li S, Li M, Diallo B, Xie G & Yu K (2021) Sorghum Grains Grading for Food, Feed, and Fuel Using NIR Spectroscopy. Frontiers in Plant Science, 12:720022.); On the other hand, the PCA scores of first 2 main components showed that none of the spectral pre-processing treatment (SNV, 1st and 2nd derivative) provided discrimination between soybean cultivars and detection of physicochemical changes of stored soybean (Bazoni et al., 2017Bazoni CHV, Ida EI, Barbini DF & Kurozawa LE (2017) Near-infrared spectroscopy as a rapid method for evaluation physicochemical changes of stored soybeans. Journal of Stored Products Research, 73:01-06.).

Classification of the different Amaranthus species by PLS-DA

This technique was efficient to separate the different species according to the cultivation system, with a high percentage of correct answers. These results agree with Xiaobo et al. (2010)Xiaobo Z, Jiewen Z, Povey MJW, Holmes M & Hanpin M (2010) Variables selection methods in near-infrared spectroscopy. Acta Analytica Chimica, 667:14-32. who stated that the NIR-PLS-DA technique allows a faster analysis of spectral variations, in the prediction of the chemical composition of each sample. Vasconcelos et al. (2018)Vasconcelos MC, Oliveira AS, Granja JAA, Costa JC & Guimarães RM (2018) Diferenciação de cultivares de girassol por espectroscopia no infravermelho próximo e análise multivariada, utilizando sementes e óleo. Revista Brasileira de Ciências Agrarias, 13:e5582. were successful using NIR-PLS-DA spectra in the separation of sunflower seeds. This technique was efficient to classify viable and nonviable soybean seeds (Kusumaningrum et al., 2017Kusumaningrum D, Lee H, Lohumi S, Mo C, Kim MS & Cho BK (2017) Non-destructive technique for determining the viability of soybean (Glycine max) seeds using FT-NIR spectroscopy. Science of food and Agriculture, 98:1734-1742.).

In all analyzes carried out, the effect of the cropping system was clear. The composition of the oil and the grain generated different spectra depending on the cultivation systems, as verified in the PCA clusters. Passion fruit cultivation in the organic system increased the content of chemical compounds in this plant (Ramaiya et al., 2021Ramaiya SD, Lee HH, Xiao YJ, Shahbani NS, Zakaria MH & Bujang JS (2021) Organic cultivation practices enhanced antioxidant activities and secondary metabolites in giant granadilla (Passiflora quadrangularis L.). PLoS ONE, 16:e0255059.). Organic fertilizers increased the production of active compounds in rice (Siavoshi & Laware, 2013Siavoshi M & Laware SL (2013) Organic Fertilizers Role on Antioxidant Enzymes in Rice (Oryza sativa L.). International Journal of Farming and Allied Sciences, 2:1337-1342.).

CONCLUSION

Through the analysis of principal components, it is possible to differentiate the different species of Amaranthus when using the spectra oil and seeds, in function of the different cultivation systems.

The PLS-DA model provided, with a high percentage of correct answers, the classification of species according to the oils and seeds of the different species. With the use of NIR, the oil showed more expressive results than the seed.

Near infrared spectroscopy of oils and seeds can be used to quick identify the different species of Amaranthus in different cropping systems.

1
This work is part of the first author’s Doctoral Thesis.

AKNOWLEDGEMENTS, FINANCIAL SUPPORT and FULL DISCLOSURE

The authors thank the funding agencies CAPES, CNPQ and FAPEMIG for financial support for research in this paper. We took the opportunity to inform you that there was no conflict of interest.

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Publication Dates

Publication in this collection
16 June 2023
Date of issue
May-Jun 2023

History

Received
01 Mar 2022
Accepted
20 Sept 2022

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] 1
This work is part of the first author’s Doctoral Thesis.

Spectral Range (cm^-1)	Functional Group	Material Type
Seed
4297	C-H (.C-H & CH2)	Polysaccharide
4668	C-H/C = O associated lipid (.RC = CH & RC = O)	Lipids
5173	O-H (.O-H & HOH)	Polysaccharide
5675	C-H Methylene (.CH2) (Symmetric)	Aliphatic Hydrocarbons
6874	O-H of water	Water
8309	C-H Methyl (.CH3)	Aliphatic Hydrocarbons
Oil
4378	C-H Starch (.C-H & CH2)	Polysaccharide
4571	N-H/C-N/C = O	Proteins
4664	C-H/C = O associated lipid (.RC = CH & RC = O)	Lipid
5667	C-H Methylene (.CH2) (Symmetric)	Aliphatic Hydrocarbons
5786	C-H Methylene (.CH2)	Methylene Hydrocarbons
7052	C-H Aromatic C-H	Aromatic Hydrocarbons
7167	C-H Methyl C-H, linear associated aliphatic CH3 (CH2)N CH3	Aliphatic Hydrocarbons
8240	C-H Methylene (.CH2)	Aliphatic Hydrocarbons

Treatment	NIR Prediction						Total number	Total hits	% Correct
Treatment	1	2	3	4	5	6	Total number	Total hits	% Correct
1	22	-	-	-	-	-	22	22	100,00
2		20	1		1		22	20	90,91
3			22				22	22	100,00
4	1			7			8	7	87,50
5					8		8	8	100,00
6						8	8	8	100,00
Total							90	87	96,67

Brasil

Brasil

Characterization by near infrared spectroscopy of seeds and oils of Amaranthus spp. as a function of cropping systems1 1 This work is part of the first author’s Doctoral Thesis.

ABSTRACT

INTRODUCTION

MATERIAL AND METHODS

RESULTS

Near infrared spectroscopy

Principal Components Analysis – PCA

Classification of the different Amaranthus species by PLS-DA

DISCUSSION

Near infrared spectroscopy

Principal Components Analysis – PCA

Classification of the different Amaranthus species by PLS-DA

CONCLUSION

AKNOWLEDGEMENTS, FINANCIAL SUPPORT and FULL DISCLOSURE

REFERENCES

Publication Dates

History

Characterization by near infrared spectroscopy of seeds and oils of Amaranthus spp. as a function of cropping systems¹ 1 This work is part of the first author’s Doctoral Thesis.