Fatty acid profile, mineral content and bioactive compounds of cocoa spreads supplemented with baru almonds (Dipteryx alata Vog.) ; Perfil de ácidos grasos, contenido mineral y compuestos bioactivos de untables de cacao suplementados con almendra baru (Dipteryx alata Vog.)

The present study aimed to perform a chromatographic and spectrophotometric characterization of the bioactive compounds, antioxidants, phenolics, profile of fatty acids and minerals in spreads supplemented with different contents of baru almonds. The addition of baru almonds (P1 treatment) enhanced the concentrations of vitamin C, antioxidants, gallic acid, calcium, magnesium, sulfur, manganese and oleic acid. In contrast, the absence of this oil in P3 treatment resulted in an increase in the concentrations of vanillin, p-coumaric acid, ferric acid, o-coumaric acid, linoleic acid and saturated and polyunsaturated fatty acids. When the tannin, beta-carotene/linoleic acid, trans-cinnamic acid, monounsaturated fatty acids, hypocholesterolemic and hypercholesterolemic fatty acid contents and atherogenic and thrombogenic indices were evaluated, no significant (p > 0.05) differences were detected between treatments.


INTRODUCTION
Brazil is recognized worldwide for the plant biodiversity of its forests, boasting hundreds of species that provide edible seeds, nuts, and almonds. These foods stand out due to their sensory characteristics, making them suitable for the development of new products with economic potential (Carvalho et al., 2012).
The baru almond (Dipteryx alata Vog.) is an oleaginous native of the Cerrado biome and stands out due to its high nutrient density, its high market value and because it is part of an abundant genetic heritage, but it is not well studied. Previous studies demonstrated the presence of important chemical/ bioactive compounds in this almond, such as monounsaturated fatty acids (linoleic and oleic), boron, zinc, copper, manganese, magnesium, antioxidant molecules, polyphenols (catechin, rutin and gallic acid, caffeic acid, chlorogenic acid, o-coumaric and trans-cinnamic acid), sterols and vitamins C and E (alpha and gamma tocopherols) (Lemos et al., 2012;Pinelli et al., 2015;Lemos et al., 2016;Campidelli et al., 2019;Campidelli et al., 2020).
The in vivo effect of the baru almond has been previously tested, and it has been proven that consumption can reduce adiposity, improve lipid profile, and increase antioxidant enzyme activity (Souza et al., 2016). These characteristics, along with its chemical properties (cited above), can minimize the incidence of different metabolic disorders, making the baru almond a health-effective food.
Due to recent evidence supported by scientific trials, cocoa is also a beneficial food for consumer health. Its high content in bioactive compounds has positive effects on improving lipid function, digestion, kidney function, and heart function, as well as anemia and mental fatigue. These benefits can be achieved due to its antioxidant, anti-inflammatory and antiplatelet action (Dilliinger et al., 2000;Herbello-Hermelo et al., 2018).
Among other options, oilseeds and cocoa products are also used in hazelnut spreads, and are extensively consumed due to their high acceptability. A disadvantage of these spreads is that they contain high concentrations of sugar and low percentages of oilseeds, harming the consumer who wishes to obtain health benefits. In addition, hazelnuts are included in the major food groups responsible for triggering food allergies (Holzhauser et al., 2002); a practical alternative would be to replace them. The baru almond is a potential substitute for hazelnut due to its chemical composition and additional physiological health benefits.
The agri-food sector monitors changes in the nutritional landscape and is interested in developing new products which are specific to meeting individual needs. Moreover, the search for information that explains how these products are beneficial is a new goal to be achieved. Nonetheless, research into the effectiveness of these new products is limited and to our detriment, there is a distribution of products below the initial quality proposed.
The present study aimed to make a chromatographic and spectrophotometric characterization of bioactive compounds, antioxidants, phenolics, fatty acids and mineral profile in spreads comprising differing contents of baru almonds.

Reagents, materials and experimental design
All chemicals, reagents and solvents used were of analytical or high-performance liquid chromatography (HPLC) grade and obtained from Sigma-Aldrich (St. Louis, MO, USA). Deionized water (>18 MΩ.cm) was obtained from a Milli-Q system (Millipore, Brussels, Belgium).
Baru almonds were obtained from the Cerrado biome, located in the city of Barra do Garças-MT, during the harvest season (between August and September, 2016). The baru almond has the following centesimal composition (g/100g): 6.63 moisture, 22.96 protein, 31.73 lipid, 14.44 dietary fiber and 1.55 ashes.
Three spread formulations were developed with different baru almond contents, as follows: 35% baru almond spread (P1); spreads with 17.5% baru and 17.5% hazelnut (P2); and control spread with 0% baru almond and 35% hazelnut (P3) ( Table 1). The choices of the ingredients used in the processing of the spreads was made through previous tests (for example focus group) that aimed to match the sensorial and technological characteristics. As for the experimental design, this was completely randomized with three replicates. Three independent batches were used for each treatment.

Spread processing
The drying of baru almonds and hazelnuts in an air circulation oven (Marconi®, MA0351, Piracicaba, Brazil) was carried out at 105 °C for 30 min. Thereafter, both oilseeds were ground in a home processor (Philipis Walita®, RI7632, Varginha, Brazil) for 5 min. Then, in the same processor, the remaining ingredients (Erythritol, coconut oil, skim powdered milk, cocoa 100%, polydextrose, whey, emulsifier and flavoring - Table 1) were added and homogenized with the oleaginous seeds for a further 3 min. The obtained spread was packed in transparent polyethylene packages and stored at 12 °C in temperature controlled chambers (Eletrolab®,EL202,Sao Paulo,Brazil). Thereafter, the analytical determinations described below were performed in triplicate.

Determination of bioactive compounds
We evaluated the total content of phenolic compounds, tannins and vitamin C. The hydroalcoholic extract was prepared according to the methodology adapted from Milardovic et al., (2005), except for vitamin C, which followed the methodology proposed by Roe;Kuether (1943).
The total phenolic compounds were also evaluated using diazonium salt Fast Blue BB, with standard gallic acid (0.096-0.024 mg·mL −1 ) for the calibration curve. The extract (0.5 mL) was added to 0.10 mL of Fast Blue BB reagent (0.1%) and 0.10 mL of NaOH (5%). After 60 min of the reaction in the dark at room temperature, the absorbance was measured using a UV-visible spectrophotometer (Varian Cary®,50,Campinas,Brazil) at 420 nm. The results were expressed in mg gallic acid equivalents (GAE) per 100 g −1 (Palombini et al., 2016).
In order to quantify antinutritional compounds, the tannin content was measured by the colorimetric method according to the Association of Official Analytical Chemists (AOAC, 1990). The method was based on the intensity of the blue color produced in reducing the Folin-Denis reagent for phenols, and was then measured using a UV-visible spectrophotometer (Varian Cary®, 50, Campinas, Brazil) at 760 nm. The results were expressed as equivalents of catechin.
The analysis of vitamin C content was carried out according to the 2.4-dinitrophenylhydrazine colorimetric method and measured using a UV-visible spectrophotometer (Varian Cary®,50,Campinas,Brazil) at 520 nm and the results were expressed as equivalents of ascorbic acid (Roe;Kuether, 1943).
The antioxidant activity was evaluated by the DPPH• (2.2-diphenyl-1-picrilhidrazil radical) scavenging method, and measured using a UV-visible spectrophotometer (Varian Cary®,50,Campinas,Brazil) at 517 nm (Milardovic et al., 2005). The scavenging activity of the DPPH radical was expressed as the inhibition percentage (% I), where Ac is the control absorbance and Aam the sample absorbance, according to the equation: % I = (Ac -Aam) / Ac × 100 %. The minimum concentration of sample that inhibited 50% DPPH radical (IC 50 ) in the reaction medium was obtained by a linear regression using concentration versus percentage inhibition values.
The antioxidant activity determination by β-carotene/linoleic acid was conducted according to the methodology described by Miller (1971) and read at 470 nm using a UV-visible spectrophotometer (Varian Cary®,50,Campinas,Brazil). The results were expressed as a percentage of inhibition of oxidation.

Individual identification of phenolic compounds by high-performance liquid chromatography with diode-array detection (HPLC-DAD)
The statements for the individual identification of phenolic compounds were prepared following the methodology described by Lemos et al., (2012). Quantification and identification of these phenols were performed in liquid chromatography (HPLC-DAD/UV-Vis) (Shimadzu Corp. ®, model Shimadzu, Kyoto, Japan). The mobile phase consisted of 2% (v/v) acetic acid in deionized water (mobile Phase) and 70:28:2 (v/v) methanol/water/ acetic acid (mobile phase B), and phenolics were detected at 280 nm. Phenolic compounds were identified by the comparison of retention times with standards (gallic acid, catechin, chlorogenic acid, caffeic acid, vanillin, p-coumaric acid, ferulic acid, m-coumaric acid, o-coumaric acid, trans-cinnamic acid, quercetin and rutin). The results were expressed as mg of phenolic compound in 100 g of fresh weight.

Profile of fatty acids by CG-FID
For the fatty acid profile analysis, lipids from spreads were extracted according to the procedures described by Folch et al., (1957). The analysis was performed by gas chromatography on a Shimatzu CG 2010 chromatograph (Agilent Technologies Inc., Palo Alto, CA, USA), equipped with a flame ionization detector, split injection at the rate of 1:50 and capillary column SPTM-2560 Supelco, 100 m × 0.25 mm × 0.20 μm (Supelco Inc., Bellefonte, PA, USA). The initial temperature of the column was 140 °C, which was maintained for 5 min, changing to 240 °C with increments of 4 °C, held for 30 min for a total of 60 min. The injector and detector were kept at a temperature of 260 °C and helium was used as the carrier gas. The fatty acids identified were compared to the retention times presented by the chromatographic pattern SupelcoTM37 FAME Mix (Supelco Inc., Bellefonte, PA, USA) and were expressed in percentage (%) of the total fatty acids. They were then grouped as saturated fatty acids (SFA), monounsaturated fatty acids (MUFAs) and polyunsaturated fatty acids (PUFAs). The atherogenic index (AI) and thrombogenic index (TI) were determined in accordance with that specified by Ulbricht and Southgate (1991) The ratio of hypocholesterolemic and hypercholesterolemic fatty acids (h/H) was calculated according to the formula described by Santos-Silva (2002) and shown in Eq.

Mineral composition
The mineral analysis described by the Sarruge and Haag method (Sarruge;Haag, 1974) was used in nitric-perchloric acid digestion at 50 °C for 10-15 min and then at 100 °C to digest all material. Then, the content levels of boron, sulfur, phosphorus, potassium, calcium, magnesium, zinc, copper, manganese and iron were quantitatively evaluated using an atomic absorption spectrophotometer (Perkim Elmer®, 3110, Wellesley, United States) at 248.3 nm. The data were described in mg·100g −1 .

Statistical analysis
The results were subjected to an analysis of variance (ANOVA), and tests for comparison of averages (Tukey's 5% probability of error). Statistical calculations were performed using the program Râ version 5.0. The differences were considered significant when p < 0.05. The principal components analysis (PCA) was used to comprehend the similarity among the edible coatings in relation to key nutritional parameters by the program Chemoface (Nunes et al., 2012).

Determination of bioactive compounds
The content of total phenolic compounds, tannins, vitamin C, DPPH• and beta-carotene/linoleic acid from food spreads prepared with different baru almond contents are described in Table 2.
Of the bioactive compounds listed in Table 2, it was possible to observe that the P1 treatment presented a higher content of vitamin C (P1 -24.37 mg·100 g −1 , P2 -19.80 mg·100 g −1 and P3 -18.25 mg·100 g −1 ) and a higher antioxidant activity (p < 0.05) as measured by DPPH• (P1 -9.83 g of DPPH sample·g −1 , P2 -11.87 g of DPPH sample·g −1 and P3 -19.45 g of DPPH sample·g −1 ). As the baru almond was the main raw material in this treatment, it is worth mentioning that this oleaginous product provided an enhancement in the bioactivity of these molecules (when compared to other treatments). When evaluating the P2 treatment, it was found that P1 did not present a statistical difference (p < 0.05) when total phenolic compounds were evaluated by the two methods (method Folin Ciocalteau: P1 -343.60 mg·100 g −1 GAE, P2 -346.66 mg·100 g −1 GAE and P3 -225.89 mg·100 g −1 GAE; method Fast Blue: P1 -46.80 mg·100 g −1 GAE, P2 -45.05 mg·100 g −1 GAE and P3 -33.26 mg·100 g −1 GAE), indicating that the use of a mix containing 50% of baru almond and 50% of hazelnut favors the presence of these substances. On the other hand, when the presence of tannins and antioxidant capacity measured by beta-carotene/linoleic acid were evaluated, no significant difference was detected among treatments (p < 0.05).
In reference to the results obtained for total phenolic compounds (measured by the Folin Ciocalteau method), these substances were high in the developed spreads. It was possible to verify that, when compared to P1, treatment with P3 gave a decrease of 34.25% in these molecules, indicating that the inclusion and exclusion of baru almonds (P1 and P3, respectively) may have reduced the presence of phenolic compounds (p < 0.05). The obtained values of phenolic compounds in other oilseeds show an average content of 32, 46, 47, 137 and 239 mg·100 g −1 for pine nuts, macadamia, nuts, almonds, cashew nuts and brazil nuts, respectively (Kornsteiner et al., 2006). The developed spread had higher amounts of phenolic compounds than the baru almond itself, because according to Fráguas et al., (2014) it has 228.24 mg of phenolic compounds in 100 g. The drying process of oilseeds, which provides exposure and increases the availability of these compounds (Lemos et al., 2012), as well as the connection with other substances such as cocoa, which stands out for its considerable presence of polyphenols (308 mg·100g −1 ) (Giacometti et al., 2016), may contribute to the increase in these molecules. Pinelli et al., (2015) found 86.16 mg/100 g of phenolic compounds in cookies made from 100% de-fatted baru almond flour. The removal of fat as well as the roasting process resulted in a considerable reduction in the presence of these bioactive molecules.
A similar behavior was observed when using the Fast Blue BB method, where P1 and P2 were statistically similar (p < 0.05) and differed from P3 (p < 0.05). However, this method provided a reduction in the detection of phenolic substances. This evidence is attributed to the fact that this procedure is specific and unique in the quantification of phenols, since the reagents used do not complex with other substances, like proteins, sugars or other reducing compounds such as ascorbic acid (as in the method of Folin Ciocalteau) (Naczk;Shahidi et al., 2004). Despite providing a lower result regarding the presence of phenolic compounds, this methodology has been verified to be more accurate because it provides the exclusive dosage of these compounds.
Tannins were observed in considerable amounts in all the spreads and no statistical difference was detected (p > 0.05), indicating that the type of oleaginous seed (baru almond and hazelnut) also contributed to the presence of these molecules. According to Campidelli et al., (2020) and Efraim et al., (2011), baru almonds, hazelnuts and cocoa, which were the major ingredients in all the spreads, are considerable sources of this element. Efraim et al., (2011) explained that cocoa seeds contain a complex series of procyanidins, formed from the condensation of individual units of catechins or epicatechins (called monomers) which are responsible for the formation of tannins in this food. Tannin compounds are considered a potent antioxidant and have antimutagenic and anticancer properties (Chu et al., 2016). These substances are beneficial when consumed in correct dosages and research confirms that the bioactivity of these compounds is attributed primarily to their ability to minimize the action of free radicals through the interception of active oxygen. Pinelli et al., (2015), when developing a cookie with 100% defatted baru almond flour, found 37.32 mg·100g −1 of tannins. The high temperature, to which these products were subjected, could potentially be responsible for the minimization of these molecules.
Since they belong to a group of phenolic compounds, they present high reactivity and are associated with the prevention of diseases related to oxidative stress. Delfino and Canniatti-Brazaca (2010) explained that the abundant consumption of this substance must be controlled, since there is compromise in the use of minerals and proteins causing anti-nutritional effects. However, since oilseed consumption generally does not occur in natural form (mainly due to the sensorial aspect it presents in this condition), the process of drying them (which was the primary stage of processing) becomes an important step in the development of sensory aspects and reduction in unhealthy substances.
It was found that P1 presented the highest content of vitamin C. In addition, P2 and P3 were not statistically different (p < 0.05). The absence of baru almonds (in P3) caused a 25% reduction in this element (when compared to P1), indicating that this oleaginous seed can contribute directly to the presence  , 2000). According to this same recommendation, these substances, when ingested at the appropriate dosages, may provide physiological benefits to the body of a normal adult individual since ascorbic acid is a preventive antioxidant. In addition to being an important natural antioxidant, vitamin C acts as a co-factor of several enzymes in the human body. Due to their inability to synthesize vitamin C, humans need to acquire this substance through diet, and a lack of vitamin C may result in diseases such as scurvy and pernicious anemia (Traber;Stevens, 2011). With regard to the means obtained for antioxidant capacity, it was considered that there was sequestering activity of DPPH• with a statistical difference in all treatments (p < 0.05). However, it was observed that P1 hads higher values, because the lower the IC 50 , the greater the antioxidant activity of the compound (Pelvan et al., 2018). Due to treatments P2 and P3 having lower amounts of baru almonds (when compared to P1), they demonstrated a respective reduction of 20.75% and 97.89% antioxidant capacity. This reduction may be compatible with the antioxidant composition of hazelnuts. In addition, the interaction of this oleaginous seed with cocoa, which has high antioxidant activity (Hernández-Hernández et al., 2018), allowed for the quantification of antioxidants in these spreads (even if values below P1).
Some compounds do not react with free DPPH• due to being lipophilic and are therefore difficult to characterize. The total antioxidant activity was also measured by the beta-carotene/linoleic acid system and the results for this determination can be classified as: (i) high levels (> 70%); ii) intermediate (40-70%) and iii) low (< 40%) in the inhibition of oxidation, according to Hassimoto et al., (2005). All the developed spreads demonstrated high levels and no statistical difference (p < 0.05) in lipophilic antioxidants, showing that both oleaginous seeds contributed to the presence of these substances. These results are important because oxidative processes (which are precursors of several chronic noncommunicable diseases) can be avoided by the use of antioxidant substances that have the property of preventing or reducing the triggering of unwanted reactions (Dillinger et al., 2000). According to Campidelli et al., (2020), baru almonds exhibited 91.7% protection, demonstrating that much of the antioxidant capacity of pastes comes from them.
Among the phenols identified by HPLC, rutin, catechin and gallic acid, which have antioxidant capacity, were the major phenolics present in the spreads. It was found that some of the components present in the spreads (gallic and caffeic acid) showed increased mean values (p < 0.05) through the addition of baru almonds (P1 treatment) and one of the possible explanations is associated with the fact that this is an oleaginous source of phenolic substances. Campidelli et al., (2020), evaluated the profile of phenolic compounds in baru almonds, and found that rutin, gallic acid and caffeic acid were the major compounds in this profile. A significant increase (p < 0.05) in ferulic acid, vanillin, rutin and an unpublished quantification of p-coumaric acid in P3 treatment was also observed and this result was attributed to the use of hazelnuts in this formulation. According to Pelvan et al., (2018) this oleaginous seed is also a source of these components. Regarding trans-cinnamic acid, no significant difference (p < 0.05) was observed between the treatments, indicating that the use of baru almonds and hazelnuts may also contribute to the inclusion of these elements in the spread.
The results obtained are not only due to the presence of baru almonds and hazelnuts, but also through the inclusion of cocoa, which in turn is also considered a source of phenolic substances (Hernández-Hernández et al., 2018). The authors affirm that the presence of phenolic compounds in cocoa confered antioxidant properties, and prevented the formation of free radicals which act in the process of the development of non-transmissible chronic degenerative diseases (Hernández-Hernández et al., 2018). The high presence of these substances in foods is important because they are able to attribute health benefits due to the broad spectrum of medicinal properties they present and has been found that processed spreads can be considered food sources of phenolic compounds. Żyżelewicz et al., (2018) investigated the profile of phenolic compounds in chocolates made with 100% cocoa liquor and also found gallic acid as the Mean values (in quadruple, n = 4). Values followed by different letters in the same line show differences by Tukey's test at 95% significance (p < 0.05); 2 Treatments: P1 (100% almond baru and 0% hazelnuts), P2 (50% almond baru and 50% hazelnuts) and P3 (0% almond baru paste 100% hazelnuts); ns: not significant at the level (p> 0.05); P: p-value. major compound (325.73 mg. 100 g −1 ), followed by epicatechin (192.31 mg·100 −1 ). The superiority of these results over those obtained in this study is due to the fact that the cocoa used was 100% pure, thus increasing its bioactivity.

Profile of fatty acids by CG-FID
The determination of the fatty acid profile present in food spreads supplemented with different levels of baru almonds is shown in Table 4.
The Dietary Guidelines for Americans (2016) states that the daily intake of MUFAs should be at least 33 g −1 (for a 2000 kcal diet) and, in this regard, the intake of 100 g −1 of spread corresponding to P1, P2 and P3 can respectively provide 1.8, 1.5 and 0.9 times this recommendation. Research indicates that oilseeds are sources of these compounds and both baru almonds and hazelnuts contributed (p < 0.05) to this profile. Ingestion of these fats is recommended by experts as there is scientific evidence that proves they can reduce the risk of cardiovascular disease, be effective in weight loss and contribute to lowering low-density lipoprotein (LDL) levels in the blood without affecting high-density lipoprotein (HDL) levels (Lottenberg, 2009).
As for saturated fatty acids, undecanoate was the major one and P3 was the treatment with highest averages (p < 0.05). Hazelnut and cocoa, which are rich in this type of fatty acid (Lottenberg, 2009), were probably responsible for the elevation of saturated fatty acids in this treatment.
For a balanced intake of fatty acids, which are essential for health, the ratio between MUFA and SFA should be at least 0.45 and in this regard, was found that the P1, P2 and P3 spreads are respectively 4.33, 2.62 and 1.42 higher than this recommendation. In relation to this profile, it is estimated that the spreads may be effective in controlling the traditional risk factors for atherosclerotic cardiovascular disease (Lottenberg, 2009). The PUFA/SFA ratio should be as high as possible, preferably greater than 0.4. To this end, no treatment reached the recommendation; however, P1, P2 and P3 obtained 0.52, 0.55 and 0.77% of it, respectively. This result was expected as baru almonds are not a matrix rich in polyunsaturated fatty acids (Campidelli et al., 2020).
As for the atherogenic index (AI), thrombogenic index (TI) and (h/H) fatty acids, which indicate the potential for stimulation of platelet and coronary aggregation, the values obtained for P1, P2 and P3 were similar in all treatments (p > 0.05).
Although there is no established parameter for these indices, lower results for AI and TI, along with higher results for h/H lessen the chance of coronary changes and make food healthier. This is due to the higher concentration of antiatherogenic fatty acids (Turan et al., 2007). Foods such as cheese and meat, which are substantial sources of fatty acids, have IA, IT and h/H ratios of 2.32, 3.11, 1.23 and 0.54, 1.15, 1.76, respectively. Compared to spreads, they demonstrate superiority and better cardiovascular protection. Żyżelewicz et al., (2018) found oleic (34.10%), linoleic (3.02%) and stearic (35.93%) acids as the major fatty acids in chocolates made with 100% cocoa liquor.

Mineral composition
The determination of the mineral composition of phosphorus, calcium, magnesium, sulfur, manganese, zinc, boron, copper and iron present in food spreads supplemented with different levels of baru almonds, as well as the mineral RDI, are shown in Table 5.
As can be observed, all treatments showed a significant difference (p < 0.05) for the analyzed minerals, showing that the variations in baru almonds and hazelnuts provided changes in these elements. It was found that the higher the baru almond content in the spread (P1), the higher the concentrations of phosphorus, calcium, magnesium, sulfur, manganese, zinc, boron and iron. Campidelli et al., (2019), analyzed the mineral composition of baru almonds, and found that they contained much higher amounts boron, magnesium, copper and manganese than the daily recommendation.
With regard to the phosphorus, iron and boron present in the P2 treatment, these elements are significantly (p < 0.05) similar to the P1 treatment, indicating that the use of 50% baru almonds and 50% hazelnuts can provide the same result as using only baru almonds.
Regardless of the oleaginous seed used, all almonds presented high levels of minerals (Institute of Medicine, 2000) because the consumption of 100 g allows for the ingestion of quantities superior to the 30% that the reference RDI advocates.
Concentrations of phosphorus, calcium, magnesium, sulfur, manganese, zinc, boron, copper and iron may provide 5, 2, 5, 2, 15, 5, 5, 27 and 8 times this recommendation, respectively, suggesting that the spread developed developed has a high mineral composition. It is thus established that the consumption of these products should be

Principal components analysis and hierarchical cluster analysis
Due to the relatively high number of variables studied, a principal component analysis (PCA) was performed to elucidate the characteristics related to these variables, correlating them and grouping them with the treatments used (P1, P2 and P3). Figure 1 shows the PCA results for bioactive compound and phenolic compound profiles. The first two main components explained 100% of the total variation between treatments for these compounds, and the first component explained 88.37% of this variation.
The spatial separation of the formulations shows that the formulation of the spreads with different contents of baru almonds differed with respect to bioactive compounds and phenolic compounds. Moreover, formulation P3 presented higher values for vanillin variables, p-coumatic ferrulic, DPPH, and rutin. Formulation P1 presented higher values for the variables beta-carotene/linoleic acid,

CONCLUSIONS
The addition of baru almonds (P1 treatment) enhanced the concentrations of vitamin C, antioxidants, gallic acid, calcium, magnesium, sulfur, manganese and oleic acid. In contrast, the absence of this oil in the P3 treatment increased the concentrations of vanillin, p-coumaric, ferric, o-coumaric, linoleic acid and saturated and polyunsaturated fatty acids. When tannins, beta-carotene/linoleic acid, trans-cinnamic acid, monounsaturated fatty acids, hypocholesterolemic and hypercholesterolemic fatty acids content and atherogenic and thrombogenic indices were evaluated, no significant (p > 0.05) differences were detected between treatments.