PEQUI FLOUR APPLIED IN THE PREPARATION OF FOOD PASTA

Pasta products are generally formulated based on wheat flour, and the insertion of other vegetable raw materials, such as pequi fruit, can provide increased nutritional value, along with differentiated technological and sensory characteristics. Thus, the aim of this study was to produce pasta with different levels of substitution of wheat flour with pequi pulp flour, to determine its proximate composition and to evaluate its technological and sensory properties. Pastas were produced with 5%, 10% and 15% of wheat flour being substituted by pequi pulp flour, and there was also a control group. Technological analyses (cooking time, volume expansion, water absorption, cooking loss, color difference and chromaticity), chemical analyses (moisture, ash, lipids, proteins and total carbohydrates) and sensory tests (acceptance and intention consumption) were carried out. The main results showed that pequi flour promoted an expansion in volume and water absorption in the product; raw and cooked pasta had more intense colors; moisture, ash and lipid content was increased by using pequi flour; and the sensory test scores for the samples with pequi were high in relation to the control samples, with the formulations with the highest content of pequi flour being the best evaluated. It is concluded that the pastas with pequi flour are promising products for the food industry.


INTRODUCTION
Pastas are obtained by using wheat flour and/ or flour derived from other cereals, legumes, roots or tubers, and result from a mechanical kneading process; when these pastas contain only wheat flour, they can be called pasta (noodles), and are called "mixed" when they contain wheat flour and other flours of vegetable species (BRASIL, 2005b). When vegetable flours are applied, in addition to the usual wheat flour, it is possible to increase the nutrient content of pasta; studies have shown an increase in the content of dietary fiber, ash, protein and lipids in pasta to which chia, amaranth and corn pericarp flour is added, for example (JUNQUEIRA et al., 2017;OLIVEIRA et al., 2015;SANTOS et al., 2015). Recent studies have exposed the importance of creating pasta with functional properties such as antioxidant activity, a reduction of the glycemic response and a reduction of oxidative stress (KHAN et al., 2015;LU et al., 2018;PASQUALONE et al., 2016). As for the technological quality of the pasta, products with a fast starch gelatinization capacity, low cooking losses, and high mass and volume yields are expected (DEL BEM et al., 2012;FERREIRA et al., 2016;KRISHNAN et al., 2012;OLIVEIRA et al., 2015;PADALINO et al., 2015;PIWINSKA et al., 2015).
Therefore, in view of the objectives of producing pasta with nutritional wealth and technological qualities, a fruit that can be processed into flour and used in these products is pequi (Caryocar brasiliense), typical of the Cerrado (PINTO et al., 2016). Its fresh mesocarp (pulp) in natura has a considerable content of ash (0.67% to 0.70%), lipids (13.54% to 26.15%), proteins (1.94% to 3.73%) and fiber (8.28% insoluble fiber and 3.11% soluble fiber) (ALVES et al., 2014;RIBEIRO et al., 2014). Fresh pequi is a source of iron and phosphorus, and presents a high content of copper, zinc and magnesium, minerals that are essential for proper functioning of the human body (ALVES et al., 2014;BRASIL, 2005cBRASIL, , 2012GONÇALVES et al., 2011). In addition, the pulp has a rich fatty acid profile, which consists of 51.10% to 64.63% monounsaturated fatty acids, with an emphasis on oleic acid, and 11.50% to 16.90% polyunsaturated fatty acids, with a predominance of linoleic acid (RIBEIRO et al., 2014). This unsaturated fraction is related to human health, through the prevention or reduction of the risks of coronary problems and metabolic disorders (FARVID et al., 2014;MOREIRA et al., 2016;THANDAPILLY et al., 2017). This lipid fraction also contains dissolved carotenoid pigments (MENDONÇA et al., 2017), such as β-carotene and β-cryptoxanthin, which are precursors of vitamin A (CARDOSO et al., 2013). Nascimento et al. (2017) produced flour from this fruit through freeze-drying of the pulp, obtaining a product with a high concentration of nutrients. In addition, studies on the sensory evaluation of products made using pequi have obtained good acceptance, the preferred or better evaluated formulations being those with the highest concentrations of pequi (ANDRADE et al., 2009;RODRIGUES et al., 2016), results that reinforce the possibility of developing food with this fruit. In this sense, the research aimed to produce pasta with different levels of partial substitution of wheat flour with pequi pulp flour (5%, 10% and 15%), determine its proximate composition and evaluate its technological and sensory properties.

MATERIAL AND METHODS
The study was conducted at the Plant Products Technology Laboratory and at the Food Technology Laboratory of the Instituto de Ciências Agrárias (ICA) of the Universidade Federal de Minas Gerais (UFMG). For preparation of the formulations, ingredients were obtained from the local market in Montes Claros, paying attention to the expiration date and integrity of the packaging. The pequis came from the same municipality in the 2016/2017 harvest.

Pequi flour production
Ripe, healthy and injury-free fruits were used. These fruits were washed in running water, brushed and left in 100 mg L −1 sodium hypochlorite solution for 30 min, and then bleached in water at 90 °C for 5 min. After cooling in an ice bath, the pyrenes and the pulp of the pequis were removed manually.
The pulp was sanitized in 50 mg L −1 sodium hypochlorite solution for 30 min, then fragmented and dehydrated in a dryer with air circulation at 60 °C for 6 h, followed by cooling to room temperature. The initial moisture content of the pequi pulp was 62%, and the moisture content of the flour was 15% after the pulp dehydration process was completed. Then, the dehydrated material was ground in a domestic multiprocessor (Philips Walita model RI 7625), placed in a hermetically sealed amber glass container and stored at 7 °C for 48 h until its application in the production of pasta.

Pasta making
Four formulations were elaborated (Table 1), one being the control (without pequi flour) and three with partial substitution of wheat flour with pequi flour (5%, 10% and 15%). The preparation started by mixing and homogenizing the ingredients in an electric mixer; afterwards, the pasta was manually shaped, stored in the refrigerator for 10 min and passed in a cylinder until a thickness of 3 mm was reached. Then, the pasta was cut into strips 5 mm wide by 120 mm long. Subsequently, the fresh pasta was dried in an oven with air circulation at 60 °C for 5 h, packed in low density polyethylene bags and stored at 7 °C. The number after the letter P indicates the percentage (5%, 10% and 15%) substitution of wheat flour with pequi flour in pasta.

Centesimal composition
The analyses used to determine the proximate composition of the cooked pasta at the optimum cooking time were based on the Official Methods of Analysis (AOAC, 2016), with the exception of the analysis of lipids (BLIGH; DYER, 1959). To quantify proteins, the Kjeldahl method was used and the nitrogen conversion factor considered was 5.7. The amount of total carbohydrates was obtained by difference [100% − (% ash + % proteins + % lipids)]. The results were expressed on a dry basis.

Cooking tests
For technological tests of cooking time, volume expansion, water absorption and loss of soluble solids (cooking loss), the American Association of Cereal Chemists (AACC, 2000) methodology no. 16-50 was followed, with modifications.

Cooking time
Cooking time was determined by cooking 10 g of sample in 140 mL of distilled water; a small amount of mass was pressed between glass plates every 30 s until the white center disappeared (gelatinization of starch). This parameter was expressed in minutes of cooking.

Volume expansion
In beakers containing 50 mL of distilled water, raw pasta of each formulation was placed to measure the volume displacement; afterwards, the pasta was cooked for its optimal cooking time, and the displaced water volume was again measured. The volume expansion was given by the number of times the pasta expanded after cooking according to equation 1.

Water absorption
Evaluation of the water absorption potential of the pasta was carried out by cooking it in 100 mL of boiling water for the optimal cooking time and subsequently draining excess water. The mass was measured before and after cooking the pasta to obtain the volume of water the product absorbed in relation to its initial mass through equation 2.

Loss of soluble solids (cooking loss)
From the water absorption analysis, 25 mL aliquots of the remaining cooking water were removed for drying in an oven at 105 °C in a measuring vessel until constant weight. The loss of soluble solids was obtained by equation 3.
where VW = volume of water (mL); mr = mass of the residue (g); va = volume of the aliquot (mL); and mrp = mass of the raw pasta (g).

Color analysis
The difference (equation 4) and the color saturation or chromaticity of the pasta before and after cooking (equation 5) were measured by a Volume expansion = Displaced volume after cooking (cm³) Displaced volume raw (cm³) Water absorption = Mass after cooking (g) Mass raw (g) Loss of soluble solids % = VW * mr * 100 va * mrp (1) (3) ( 2) portable Konica Minolta colorimeter with the CIELAB system defined by the coordinates L* (black/white coordinate), a* (coordinate red/green) and b* (yellow/blue coordinate).
where ΔL* = difference of the L* coordinate before and after cooking; Δa* = difference of the a* coordinate before and after cooking; and Δb* = difference of the b* coordinate before and after cooking.

Sensory tests
The sensory tests, consumption intention and acceptance, were conducted at the Food Technology Laboratory at ICA/UFMG, having previously been approved by the UFMG Human Research Ethics Committee (90758318.2.0000.5149).
The formulations prepared were cooked for their optimum cooking time (according to the results obtained in cooking tests); 100 g of pasta was cooked in 1.4 L of water with 7 g of salt, the only spice added, so that the perception of the real taste of the pasta would not be altered. Sixty untrained tasters were served the four samples on white plastic plates, coded with three numbers chosen at random, and a glass of water for use in the tasting interval of each sample. During the tests, the tasters also received an Informed Consent Form (ICF) for research with human beings and filled out a questionnaire to collect identification data, eating habits and knowledge about the product.
The consumption intention test was performed using a 7-point hedonic scale: from 1 "I would never eat", through 4 "I would eat occasionally" to 7 "I would always eat" (INSTITUTO ADOLFO LUTZ -IAL, 2008). The acceptance test evaluated how much the judges liked or disliked the characteristics of appearance, texture, flavor and global acceptance of the pastas through a 9-point hedonic scale: from 1 "I disliked extremely", through 5 "I neither liked nor disliked" to 9 "I liked extremely" (IAL, 2008).

Experimental planning and statistical analysis
The design chosen to conduct the experiment was completely randomized (CR), containing three replicates, and the data are presented as the mean ± Color difference = ΔL 2 + Δa* 2 + Δb* 2 Chroma = a* 2 +(b*) 2 standard deviation. The results of chemical, technological and sensory analyses were analyzed statistically with Sisvar software, where they were subjected to analysis of variance (ANOVA), and to Tukey's test at 5% probability when significant (FERREIRA, 2011). Table 2 shows the percentage moisture in the dehydrated pastas, that is, before the cooking process in water, as well as the centesimal composition of the cooked pastas. It is noted that the moisture content of the raw pasta decreased as wheat flour was replaced by pequi flour, which may be due to the initial moisture content of these raw materials, and thus the highest moisture content was 8.28% (control pasta); followed by 7.06% (P5); and the lowest levels, 6.69% (P10) and 6.47% (P15), which were not significantly different from each other. This moisture content was slightly lower than that found in dehydrated noodle-type pasta containing dehydrated ora-pro-nobis, 10.47% (ROCHA et al., 2009); and in pasta with 30% of the solid ingredients being mixed flour with different levels of beans and rice in partial replacement of wheat flour, which ranged from 10.70% to 10.98% (MINGUITA et al., 2015). Moisture is a variable considered in food preservation; dehydrated products and those with a low moisture content, such as the pastas in this work, may have a longer shelf life because, for example, they do not have a high water content favorable for growth of microorganisms (REIS et al., 2017). Therefore, all the pastas produced in this work can have good storage stability.

Centesimal composition
The cooked pasta with the highest moisture content was the P10 treatment (75.59%), which differed significantly from the control formulation (72.32%), which had the lowest content. In the study by Howard, Hung and McWatters (2011), cooked pasta with substitution of 50%, 40% and 30% of semolina for peanut flour presented a moisture content of 63.41%, 64.40% and 64.84%, respectively, and in the sensory analysis performed, the evaluators considered that these had moisture levels close to the ideal. In the present study, the pasta produced showed a moisture difference of around 10% compared to the masses in the study by Howard, Hung and McWatters (2011), that is, they may possibly also have good sensory acceptance regarding moisture content.
Regarding the ash content, the percentage increased as greater additions of pequi flour were made to the pasta. The P15 treatment had a content (1.86%) significantly higher than the values found in the other treatments, being more than twice as much as that evaluated in the control pasta (0.82%). Such results are justified by the richness of mineral residue of pequi pulps, between 0.85% and 1.48% on a dry basis, as reported by Alves et al. (2014) and Cordeiro et al. (2013), while the wheat flour used in the formulations was type 1, which should have a maximum of 0.80% ash on a dry basis (BRASIL, 2005a). Additionally, an interesting fact was exposed by Gonçalves et al. (2011) who reported that even after a long cooking time (40 min), pequi pulp remains as a source of minerals, highlighting that calcium, phosphorus, magnesium, manganese and sulfur are not leached into the cooking water. Therefore, it is suggested that the pastas in the present work can retain a large part of this mineral content of the pequi pulp, since the pulp used in the formulations was in the dehydrated form (higher concentration of nutrients), and the longest cooking time (13.33 min) is short in relation to the maximum cooking time of the pulp so that it remains a source of minerals.
The substitution of 10% and 15% of wheat flour with pequi flour caused an increase in the lipid content in the pasta, and these treatments, P10 (3.70%) and P15 (3.93%), did not differ statistically from each other and resulted in a higher lipid content than treatment P5 (1.07%) and the control (1.01%), which presented statistically equal values. From the nutritional point of view, this elevation of the lipid content is important, because it is known that the lipid fraction of pequi is rich in unsaturated fatty acids and may contain 56.98% oleic acid (omega 9) and essential fatty acids, with 3.48% linoleic acid (omega 6) and 2.09% linolenic acid (omega 3) (AGUILAR et al., 2012). Regarding these fatty acids, the literature addresses some of their functionalities, such as preventing metabolic disorders and improving heart health when consuming foods with high levels of oleic acid (MOREIRA et al., 2016;THANDAPILLY et al., 2017); reduced risk of coronary heart disease correlated with consumption of linoleic acid (FARVID et al., 2014); and the participation of linolenic acid in brain development to control cognitive functions (GRAYSON et al., 2014).
The formulations did not differ statistically in terms of protein content. An explanation is the possible similarity that can be found between the protein content of wheat flour on a dry basis, from 12.47% to 16.83% (CHANG; FLORES, 2004;VIEIRA et al., 2015), and the pulp of pequi on a dry basis, which can vary from 5.02% to 14.70% (ALVES et al., 2014;RIBEIRO et al., 2014) depending on edaphoclimatic conditions, which influence the composition of the fruit.
The percentage of total carbohydrates was high for all treatments, and this characteristic is common in pastas. In the literature, the content of this component varies between 73.07% and 86.67% (dry basis) in uncooked dehydrated pastas (FERREIRA et al., 2016;OLIVEIRA et al., 2015;ROCHA et al., 2009). It is noticed that this value is directly related to the increase in the products' lipid content, since the control and P5 formulations had the highest levels of total carbohydrates, 88.79% and 87.28%, respectively, and also the lowest levels of lipids; and formulations P10 and P15 had lower amounts of total carbohydrates, 83.72% and 84.02% respectively, and the highest amounts of lipids.
It is also important to mention that within this fraction of total carbohydrates is dietary fiber, and the pequi pulp has a high content of this nutrient (from 7.99% to 14.06% on a wet basis) according to the studies by Cordeiro et al. (2013) and Ribeiro et al. (2014) and based on the Technical Regulation on Complementary Nutritional Information (BRASIL, 2012). Fiber has local benefits such as the control of Table 2. Moisture content of raw (uncooked) pastas and centesimal composition of cooked pastas (%). 1 Different letters in the same row indicate a significant difference at 5% significance using Tukey's test. 2 Values expressed as mean ± standard deviation (except total carbohydrates); all results are on a dry basis (except the percentage of moisture). 3 The number after the letter P indicates the percentage (5%, 10% or 15%) substitution of wheat flour with pequi flour in pastas. 4 Raw pasta is the pasta only dehydrated, before cooking in water.  Table 3 shows the results for the technological properties of pasta: cooking time, volume expansion, water absorption, cooking loss, color difference and chroma of the raw and cooked pasta. Cooking times (Table 3) for treatments P15 (13.06 min) and P10 (13.33 min) were longer and statistically equal, followed by treatment P5 (11.67 min) and the control (7.39 min) with shorter times. These results indicate that the addition of pequi flour increased the cooking time of the pastas. Observing data from the literature, in a study with pastas in which wheat flour was partially replaced by chia flour (OLIVEIRA et al., 2015) and in another with gluten-free spaghetti based on sorghum, rice and potatoes (FERREIRA et al., 2016), the cooking times were high, as found here for pasta with pequi flour. Even so, it is understood that the advantages of replacing wheat flour with flours from some other vegetable species are in the differentiation of sensory characteristics and in the addition of nutritional and functional value to pastas (BIERNACKA et al., 2017;DEL BEM et al., 2012;KAUR et al., 2013;OLIVEIRA et al., 2015).

Cooking tests
The control pasta did not differ from treatment P5, both presenting the lowest values of volume expansion when compared to pastas P15 (3.98 times) and P10 (4.03 times), which presented values significantly higher and equal to each other. For the variable water absorption, the highest value was obtained for formulation P10 (5.08%), followed by P5 (4.64%) and finally by P15 (4.01%) and the control (3.08%), the latter not differing statistically. In general, volume expansion is related to the absorption of water (OLIVEIRA et al., 2015;SURASANI et al., 2019); in fact, the results showed that the formulations P10 and P5 with pequi flour showed greater expansion of volume and greater water absorption, the same not happening for the P15 treatment. A possible explanation for the low water absorption of P15 may be that 15% pequi flour exceeded the limit for better water absorption by the pasta, because this flour had a visually larger granulometry than wheat flour and, according to Kaur et al. (2013), flours with larger grain sizes absorb less water than flours with finer particles. Thus, due to the swelling that occurs in the fibers (CUI et al., 2019), the expansion in volume of the pasta increased as the pequi flour content increased; however, inclusion of 15% pequi flour may have reduced excessively the amount of wheat flour and, therefore, there was little water absorption, in addition to a possible discontinuity in the gluten network, which reduces the water absorption capacity (PADALINO et al., 2015).
Studies by Piwinska et al. (2015) showed that pasta containing oat powder (4%, 8%, 12%, 16% and 20%) with a high fiber content had increased swelling rates (amount of water absorbed); the same occurred in pastas produced by Oliveira et al. (2015), which contained chia flour with 37.44% dietary fiber, presenting significantly higher water absorption and volume expansion than the values obtained for the control pasta; finally, pasta with 50% and 60% potato flour plus 10% oat, wheat or rice bran, which tends to have a higher fiber content, also showed higher water absorption than the control pasta (KRISHNAN et al., 2012). Thus, it is suggested that treatments with pequi (P5 and P10) showed this high expansion in volume possibly due to the high amount of dietary fiber in this fruit, from 16.18% to 31.37% on a dry basis (CORDEIRO et al., 2013;RIBEIRO et al., 2014), while refined wheat flour contains only 0.52% to 3.18% dietary fiber on a dry basis (CHANG;FLORES, 2004;VIEIRA et al., 2015).
For the variable cooking loss, formulations with pequi flour, P5 (9.55%), P10 (11.00%) and P15 (10.04%), showed significantly higher values compared to the control (5.91%). In addition, the possible increase in the pasta's fiber content due to the addition of pequi flour may have led to a situation similar to what occurred in the study by Padalino et al. (2015), who showed that whole wheat pasta with higher amounts of fiber had a greater loss of soluble solids (starch) compared to whole wheat pasta with a lower fiber content, and suggested that this may be a consequence of the interference of this nutrient in the starch and gluten network.
In agreement with our results, other studies with replacement of gluten-based flours by glutenfree flours also show this type of difference in the loss of soluble solids: 7.70% and 7.90% loss of soluble solids in pastas made from a mixture of wheat semolina with chickpeas and wheat semolina with peas, respectively, against only 4.00% loss in pasta containing only wheat semolina (DEL BEM et al., 2012); in pasta with substitution of 30%, 40% and 50% of wheat semolina for peanut flour the losses increased, being 5.96%, 6.61% and 7.27%, respectively (HOWARD; HUNG; McWATTERS, 2011); and in pasta with a formulation of 70% sweet potato flour (two varieties) and 27% wheat flour the losses were 13.05% and 14.00% (KRISHNAN et al., 2012). Thus, it is believed that with an increase of pequi flour in the pasta, there was an increase in the fiber content, which caused this greater loss of product solids.

Color analysis
The incorporation of pequi flour directly influenced the color (difference in color and chroma) of the elaborated pasta.
For the first aspect, it was observed that the use of pequi flour made the color difference between the pasta before and after cooking more evident, since before cooking these pastas had more intense colors because of the carotenoid pigments of this fruit (VILAS BOAS et al., 2012;NASCIMENTO et al., 2017), and after cooking these became clearer. This is also explained by the absorption of water, since in dehydrated raw pasta the color becomes more visible and from the cooking and incorporation of water these characteristic color pigments are also diluted.
In the case of the chroma variable, the raw pasta with the highest purity or color saturation was treatment P15 (55.77), which differed statistically from the other treatments, P10 (45.27) and P5 (45.92), and the control with less saturation of color (17.99), that is, the treatments with pequi flour reflected in greater chromaticity. And even when the pastas were evaluated after cooking, the samples with pequi flour had more intense colors than the control sample, with P15 showing the highest chromaticity value.
Despite the dilution of carotenoids in the pasta after cooking and their probable partial degradation, it is noteworthy that the incorporation of ingredients with carotenoids in food formulations is nutritionally important, as they have several functions, such as anti-inflammatory and antioxidant properties, and prevention of cardiovascular and ocular diseases and some cancers (EGGERSDORFER; WYSS, 2018;WOODSIDE et al., 2015).

Sensory analysis
The data for acceptance and consumption intention tests are shown in Table 4. The best results for consumption intention were found for treatments P15 (4.23) and P10 (4.28) with high scores between "I would eat occasionally" -grade 4 -and "I would eat often" -grade 5; followed by treatment P5 (3.63), and the control with the lowest score (3.16), the latter sitting between "I would rarely eat" -grade 3 -and "I would eat occasionally" -grade 4. The pastas produced with the highest levels of pequi flour showed higher scores for all attributes evaluated in the acceptance test. In summary, in terms of appearance, all treatments with pequi flour had scores higher than for the control pasta and were not significantly different from each other. For the texture attribute, sample P15 with a higher content of pequi flour was the best evaluated and differed statistically from the control sample. In terms of flavor, higher scores were obtained for samples P15 and P10 (higher concentration of pequi flour) than for the control pasta. And finally, in the global evaluation, the samples with pequi did not present significant differences between themselves, with higher marks than those attributed to the control pasta.
It is possible that the way of preparing the pasta had a strong influence on the sensory evaluation, resulting in not-so-high scores, because in the data collection questionnaire 71.93% of the participants stated that they prefer to consume pasta served with sauces (white, tomato, carbonara, Bolognese). However, even though the pastas in this work were served with no type of sauce, those made with higher concentrations of pequi pleased most of the tasters, since the pastas best evaluated in all acceptance criteria were P10 and P15, with marks between 6 -"I liked it slightly" -and 7 -"I liked it regularly". According to the questionnaire, 71.67% of the participants have the habit of consuming fruits from the Cerrado; this may represent one of the reasons why pequi formulations were more accepted and preferred. Although the questionnaire did not ask exactly about the consumption of pequi, to avoid the occurrence of an expectation error during the sensory evaluation, it is known that this is one of the main Cerrado fruits consumed in regional dishes (PINTO et al., 2016).
As in this work, the literature shows that the substitution of wheat flour or the addition of substances of different vegetable species in pasta can improve the sensory parameters of this product, or keep them elevated when the control pasta is already well evaluated. As an example, Armellini et al. (2018) showed that pasta plus saffron extract had higher acceptance scores than the control pasta for all evaluated parameters, while Biernacka et al.
(2017) produced pasta with different concentrations of locust bean fiber, presenting scores statistically equal to that of the control pasta, which received an evaluation close to "I liked it extremely". Focusing on the sensory results disclosed for products made with pequi, Rodrigues et al. (2016) and Andrade et al. (2009) carried out work on developing seasoning tablets and buffalo mozzarella with pequi flavor, respectively; the formulations with higher percentages of pequi were classified as better or preferred by the evaluators, as happened in this work.

CONCLUSIONS
In nutritional terms, pequi flour decreased the moisture content of raw pastas, which is beneficial in terms of stable storage, and increased the content of mineral residues and lipids in the cooking pastas. From the technological aspect, pequi flour caused an expansion in volume and water absorption, in addition to more intense colors in raw and cooked pastas. With regard to the sensory issue, pasta with pequi showed higher acceptance and intention to consume. In view of these results, considering all nutritional, technological and sensory aspects, it is concluded that pastas with higher levels (10% and 15%) of pequi flour showed the best results, pequi being a promising product for the food industry that seeks healthy innovations and sensory quality.