Effect of blanching on physicochemical characteristics of potato flour

Nascimento, Revenli Fernanda do; Canteri, Maria Helene G

doi:10.1590/S0102-053620180406

ABSTRACT

Offering new products obtained from potatoes is a market opportunity which may increase and motivate the consumption of this tuber. It also can contribute for waste reduction and ensure market for growers. Thus, we aimed to produce potato flour and to evaluate the effect of blanching on the physiochemical characteristics of this product after 3-month storage at room temperature. Potatoes cultivar Agata were used to make unblanched and blanched flour, through thermal treatment at 97°C for 5 min. The unblanched potato flour presented significantly smaller contents of moisture (p= 0.006), proteins (p= 0.001) and soluble fibers (p= 0.024), as well as color alteration. However, it presented higher phenolic compound content (23.77%). The blanched potato flour presented similar nutritional quality compared with the raw potato flour, and also longer shelf life, since dehydration can reduce about 95% of the initial moisture content of the potato. The thermal treatment (blanching) improved the supply of proteins and soluble fibers of the final product, as well as prevented enzymatic browning reaction which would result in color alteration of the product. The treatment reduced total phenolic compound content, though.

Keywords:
Solanum tuberosum; color; physicochemical properties; phenolic compounds; thermal treatment

RESUMO

A oferta de novos produtos a partir da batata é uma oportunidade de mercado que pode aumentar e incentivar o consumo deste tubérculo, contribuir para a redução do desperdício e garantir mercado para os agricultores. Desta forma, o presente trabalho teve por objetivo produzir uma farinha de batata e avaliar o efeito do branqueamento sobre as características físico-químicas desse produto após três meses de armazenamento em temperatura ambiente. Para o desenvolvimento do trabalho, batatas da cultivar Ágata foram utilizadas para produção de farinha não branqueada e branqueada, por meio de tratamento térmico 97°C por 5 min. A farinha de batata não branqueada apresentou teores significativamente menores de umidade (p= 0,006), proteínas (p= 0,001) e fibras solúveis (p= 0,024), bem como alteração da coloração. No entanto, apresentou conteúdo de composto fenólicos superior em 23,77%. A farinha de batata branqueada apresentou qualidade nutricional semelhante à batata in natura, associada ao prolongamento da vida útil, visto que a desidratação pode reduzir cerca de 95% da umidade inicial da batata. O tratamento térmico (branqueamento) melhorou o aporte de proteínas e fibras solúveis do produto final, bem como impediu a reação de escurecimento enzimático que levaria à alteração da cor da farinha, no entanto, reduziu o teor de compostos fenólicos totais.

Palavras-chave:
Solanum tuberosum; tratamento térmico; propriedades físico-químicas; compostos fenólicos; cor

Potato (Solanum tuberosum) is one of the most consumed vegetables and it is accessible to all social classes. This food can be easily prepared and it has a high nutritional value (Lovat et al., 2016LOVAT, C; NASSAR, AMK; KUBOW, S; LI, XQ; DONNELLY, DJ. 2016. Metabolic biosynthesis of potato (Solanum tuberosum L.) antioxidants and implications for human health. Critical Reviews in Food Science and Nutrition 56: 2278-2303.). For these reasons, potato has become the third most important food crop worldwide, third only to wheat and rice (Yamdeu et al., 2016YAMDEU, JHG; GUPTA, PH; PATEL, NJ; SHAH, A; TALATIJ, G. 2016. Effect of storage temperature on carbohydrate metabolism and development of cold-induced sweetening in Indian potato (Solanum tuberosum L.) varieties. Journal of Food Biochemistry 40: 71-83.). In 2017, Brazil produced over 4.2 million tons of potatoes, with an increase of 9.3% comparing with the previous year, showing an average yield of 30.8 t ha^-1 (IBGE, 2017IBGE. 2017. Brazilian Institute of Geography and Statistics. Rio de Janeiro: IBGE. 93p.).

During harvest, commercialization and processing, great quantities are lost causing substantial economic loss for growers and waste of precious food, because of inefficient post-harvest management, mechanical injuries, market demands for lighter color tubers after washing and with the minimum of external defects, bad distribution and inappropriate storage facilities (Rafiq & Ghosh, 2017RAFIQ, SM; GHOSH, BC. 2017. Effect of potato incorporation on the physico-chemical, textural and sensory properties of processed cheese. Journal of Food Measurement and Characterization 11: 776-780.). Guerra et al. (2014GUERRA, AMN; FERREIRA, JBA; COSTA, ACM; TAVARES, PRF. 2014. Causas de perdas pós colheita em cenoura e batata no mercado varejista de Santarém-PA. Revista Tecnologia e Ciência Agropecuária 8: 61-68.) noticed that 13.12% of potatoes commercialized in retail market, in Santarem-PA, were discharged since they showed some kind of damage; 73% of theses damages were considered mechanic damages. Besides these, potato tubers have limited lifespan, resulting in large losses due to delays in retail sales, since in Brazil most of the production is destined to fresh consumption.

Thus, the supply of new products made from fresh potatoes is a great market opportunity to be exploited in order to increase and motivate the consumption, besides contributing to reduce waste and to ensure growers’ market (Rafiq & Ghosh, 2017RAFIQ, SM; GHOSH, BC. 2017. Effect of potato incorporation on the physico-chemical, textural and sensory properties of processed cheese. Journal of Food Measurement and Characterization 11: 776-780.). Potato flour production is a simple process that, differently from potato starch, corresponds to the starch product extracted from this tuber; the flour is elaborated using the whole potato tubers, in some formulations even the potato peel is used (ANVISA, 1978ANVISA. 1978. Agência Nacional de Vigilância Sanitária: Resolução - CNNPA nº 12, de 1978. p 21-24.). Therefore, besides aggregating value to tubers which would be discarded, potato flour provides the consumer market with a new product with nutritional quality of the fresh potato, associated with longer shelf life. Additionally, this flour can be used both as food to be consumed directly and raw material for other product preparation, such as loaves of bread, cakes, appetizers, cookies, among others (Lovat et al., 2016LOVAT, C; NASSAR, AMK; KUBOW, S; LI, XQ; DONNELLY, DJ. 2016. Metabolic biosynthesis of potato (Solanum tuberosum L.) antioxidants and implications for human health. Critical Reviews in Food Science and Nutrition 56: 2278-2303.).

Thermal treatment (blanching) before the processing of potato tubers aims to inactivate enzymes and microorganisms which cause deterioration, in order to increase quality and useful life of processed foods during storage. One of the main inactivated enzymes through blanching is polyphenoloxidase (PPO), which causes enzymatic browning of fruits and vegetables, responsible for changes in texture, color, odor, taste and nutritional quality (Araújo, 2008ARAÚJO, JMA. 2008. Química de alimentos. Viçosa: UFV. P 389-391.).

Given the above, this work aims to produce potato flour and evaluate the effect of blanching on physicochemical characteristics of this product.

MATERIAL AND METHODS

The authors used 2.2 kg of potatoes cultivar Agata (raw material), from the November (planting) to January (harvest) of 2017 season, cultivated by growers in the Region of Campos Gerais do Paraná. Washed tubers were provided by a vegetable processing company of Parana State, after 7-day storage at 9-10°C controlled temperature and 80-85% relative humidity.

In order to produce unblanched flour (UB), 1.1 kg of potatoes were washed, peeled, grated and then taken into a dryer with forced air circulation at 45ºC for 24 hours, or until reaching constant mass and then, crushed in a blender until obtaining a fine and homogeneous powder. To produce blanched flour (BC), after being washed, the rest of potatoes was immersed into water at 97°C for 5 min and cooled in water-ice bath (4°C). Afterwards, BC followed the same process used to obtain UB flour.

Blanched and unblanched flours were stored in airtight bottles, in a dry, dark place, at room temperature during three months.

Physicochemical analysis

Physicochemical analyses were carried out in laboratories of Departamento de Alimentos of UniversidadeTecnológica Federal do Paraná, Campus Ponta Grossa, Brazil. Humidity, ashes, proteins, lipids and fibers (insoluble and soluble) were analyzed following the methodology suggested by AOAC (2005)AOAC. 2005. Official methods of analysis of AOAC international. Washington: AOAC., methods 925.10, 923.03, 945.18-B, 922.06 and 991.43, respectively. Analyzes were performed in triplicate. Carbohydrate content (%) was determined by difference, 100 - (ash + lipid + protein + fiber).

Total phenolic compounds were determined using Folin-Ciocalteu method according to the methodology by Lombardo et al. (2013LOMBARDO, S; PANDINO, G; MAUROMICALE, G. 2013. The influence of growing environment on the antioxidant and mineral content of “early” crop potato. Journal of Food Composition and Analysis32: 28-35.) with the following modifications: to extract total phenolic compounds 5 mg of sample were mixed with ethanol (10 mL 80% v/v), remaining at 24-hour rest. Then, the authors extracted 0.3 mL of the supernatant from each extract obtained and 3.3 mL of Folin-Ciocalteu (10% v/v) were added and 2.4 mL of sodium carbonate (7,5% m/v). Absorbance was measured at 760 nm using a UV-Vis spectrophotometer (Femto 800 XI). Phenolic compound content was determined based on a standard calibration curve generated with known amounts of tannic acid (TAN)/g dry weight of potato flour (Figure 1).

Figure 1
Standard calibration curve generated using tannic acid. Ponta Grossa, UTFPR, 2018.

The evaluation of the instrumental color was carried out directly in the potato flour, with the aid of a colorimeter (Hunter Lab Ultra Scan Pro). CIE L* a* b* color-space coordinates and C* index were evaluated. L* value represents luminosity of color stimulation, ranging from zero (black) to 100 (white), a* ranging from green (-60) to red (+60), b* ranging from blue (-60) to yellow (+60) and C* representing chroma relating to color intensity (Buckley & Giorgianni, 2015BUCKLEY, RR; GIORGIANNI, EJ. 2015. Encyclopedia of color science and technology. Berlin Heidelberg: Springer. p 1-9.).

Statistical analysis

Statistical treatments of these data were performed using SPSS 23^® software. Levene and Kolmogorov-Smirnov tests were applied in order to verify variance homogeneity and normal distribution of data, respectively.

Considering that no homogeneous data was noticed (Levene’s test: p>0.05), as well as no normal data was verified either (Kolmogorov-Smirnov’s test: p>0.05), variance analysis (ANOVA) was performed to differentiate groups considering 95% confidence level (p≤0.05) using a completely randomized design, with three replicates. The results were expressed as averages ± standard deviation.

RESULTS AND DISCUSSION

Potato flour yields, UB and BC, were from 8 to 9%, respectively (p= 0.005), possibly the highest yield of BC flour is associated to the highest moisture content. Santos (2009SANTOS, AP. 2009. Farinha de batata (Solanum tuberosum L.): obtenção, caracterização físico-química, funcional, elaboração e caracterização de sopas desidratadas. Itapetinga: UESB. 105p(MSc. thesis).) reported in his study yield of 13% for flour made with Agata potato, higher comparing with this study probably due to higher moisture content of the final product.

Moisture content of BC potato flour was significantly superior (p= 0.006) comparing with UB flour, probably due to the water absorbed by the potato used for producing the first flour during thermal treatment (Table 1). Higher value was reported by Kaur et al. (2016KAUR, A; KOCHHAR, A; PRASAD, P. 2016. Nutritional evaluation of value added products using potato flour. International Journal of Health Sciences and Research 6: 466-472.) for flour made using potato cultivar Kufri Pukhraj, which showed 13.07% moisture. Santos (2009SANTOS, AP. 2009. Farinha de batata (Solanum tuberosum L.): obtenção, caracterização físico-química, funcional, elaboração e caracterização de sopas desidratadas. Itapetinga: UESB. 105p(MSc. thesis).) mentioned moisture content of approximately 90% for raw potato cultivar Agata. Thus, this information allowed inferring that the dehydration process used in this study could produce flours with a reduction of initial moisture content of about 95%, which is extremely relevant to ensure longer shelf life, since water activity above 0.9 contributes to bacteria development, and above 0.7 to development of molds and yeasts, as well as intensifies the enzymatic activity (Schultz, 2016SCHULTZ, C. 2016. Water activity as related to microorganisms in the manufacturing environment. General Internal Medicine and Clinical Innovations1: 1-2.).

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Table 1
Physiochemical characterization of potato flours. Ponta Grossa, UTFPR, 2018.

Values found for ash contents are related to mineral content in potato flour, considering that the main minerals found were potassium, phosphorus, calcium, iron and magnesium (Shin et al., 2015SHIN, EH; BAIK, MY; KIM, HS. 2015. Comparison of physicochemical properties of starches and parenchyma cells isolated from potatoes cultivated in Korea. Food Science and Biotechnology 24: 955-963.). UB and BC potato flours studied in this experiment had not presented significant differences for mineral content (p= 0.065), showing 6.95 and 6.91%, respectively. Leivas et al. (2013LEIVAS, CL; COSTA, FJOG; ALMEIDA, RR; FREITAS, RJS; STERTZ, SCS; SCHNITZLER, E. 2013. Structural, physico-chemical, thermal and pasting properties of potato (Solanum tuberosum L.) flour. Journal of Thermal Analysis and Calorimetry 111: 2211-2216.) reported an average of 4.56% of minerals in potato flour made from cultivar Agata. Mineral content variation in potatoes may be attributed to conditions of growing and fertilization, as this crop is highly influenced by nutrients added to soil (Zörba et al., 2014ZÖRBA, C; SENBAYRAMB, M; PEITER, E. 2014. Potassium in agriculture - Status and perspectives. Journal of Plant Physiology171:656-669.). Quadros et al. (2009QUADROS, DA; IUNG, MC; FERREIRA, SMR; FREITAS, RJS. 2009. Composição química de tubérculos de batata para processamento, cultivados sob diferentes doses e fontes de potássio. Ciência e Tecnologia de Alimentos 29: 316-323.) carried out a study which showed that potato tubers tend to increase ash content when potassium dose is increased during fertilization.

In relation to proteins, BC potato flour showed larger quantity (p= 0.001) when comparing to UB flour. According to Escaramboni et al. (2013ESCARAMBONI, E; SILVA, DF; N NETO, PO. 2013. Influência da temperatura na atividade de amilase e protease de Rhizopus oligosporus cultivado por fermentação em estado sólido. Biochemistry and Biotechnology Reports 2: 285-288.), the proteases, which hydrolyze peptide bonds of the proteins, lose their catalytic activity at temperatures above 70°C. Thus, remaining proteolytic enzymes and still active in UB potato flour may have caused the reduction of this component. Similar result found in BC potato flour was reported by Garmus et al. (2009GARMUS, TT; BEZERRA, JRMV; RIGO, M; CÓRDOVA, KRV. 2009. Elaboração de biscoitos com adição de farinha de casca de batata (Solanum tuberosum L.). Revista Brasileira de Tecnologia Agroindustrial 3: 56-65.) for potato peel flour, which showed 2.46% proteins.

Potatoes are considered to be a low-fat food, generally between 0.02 and 0.96%, depending on the cultivar (Leivas et al., 2013LEIVAS, CL; COSTA, FJOG; ALMEIDA, RR; FREITAS, RJS; STERTZ, SCS; SCHNITZLER, E. 2013. Structural, physico-chemical, thermal and pasting properties of potato (Solanum tuberosum L.) flour. Journal of Thermal Analysis and Calorimetry 111: 2211-2216.). Corroborating this statement, potato flours showed in this study 0.69% and 0.62% (p= 0.337) for UB and BC flour, respectively. Virmond et al. (2014VIRMOND, EP; KAWAKAMI, J; VONCIK, KS; CÓRDOVA, KRV; SLOMPO, PJH. 2014. Características físico-químicas de cultivares de batata sob cultivo orgânico. Ambiência10: 31-42.), studying physicochemical characteristics of flour made of potatoes, cultivar Agata, Atlantic and BRS Clara, reported 0.09%, 0.09% and 0.11% of lipids, respectively.

The value found for insoluble fibers in UB potato flour (6.28%) was higher (p= 0,002) than in BC flour (4.06%), whereas the opposite was found for soluble fibers (p= 0.024), with average contents of 1.33% for UB flour and 1.82% for BC flour. According to Araújo (2008ARAÚJO, JMA. 2008. Química de alimentos. Viçosa: UFV. P 389-391.), enzymatic browning reaction results from phenolic compound oxidation caused by PPO and peroxidase (POD) enzymes, resulting in quinone formation, which rapidly condenses into dark insoluble pigments called melanins. Thus, PPO and POD enzymes which remain in UB flour, probably caused melanin formation, which could be quantified as insoluble fibers, increasing the content of this compound in the flour in this study. Due to the enzymatic inactivation by thermal treatment, the pectinolytic enzymes, which degrade pectin, soluble fiber present in fruits and vegetables, also lose their activity. That is the reason why, active enzymes in flour without any thermal treatment could have reduced the soluble fibers. Nascimento & Canteri (2016NASCIMENTO, RF; CANTERI, MHG. 2016. Modificação das fibras dietéticas no armazenamento de vegetais sem tratamento térmico. Revista Brasileira de Produtos Agroindustriais 18: 423-426.) reported similar results for UB and BC sweet potato flour, which showed 15.08% and 7.17% of insoluble fibers and 2.46% and 4.13% of soluble fibers, respectively.

Thermal treatment did not significantly affect (p= 0.09) carbohydrate content of the studied flours, with an average of 81%. This high carbohydrate content is mainly due to the presence of starch, 60-80% (Murniece et al., 2011MURNIECE, I; KARKLINA, D; GALOBURDA, R; SANTARE, D; SKRABULE, I; COSTA, HS. 2011. Nutritional composition of freshly harvested and stored Latvian potato (Solanum tuberosum L.) varieties depending on traditional cooking methods. Journal of Food Composition and Analysis 24: 699-710.). Similar results were mentioned by Leivas et al. (2013LEIVAS, CL; COSTA, FJOG; ALMEIDA, RR; FREITAS, RJS; STERTZ, SCS; SCHNITZLER, E. 2013. Structural, physico-chemical, thermal and pasting properties of potato (Solanum tuberosum L.) flour. Journal of Thermal Analysis and Calorimetry 111: 2211-2216.), 82.49% and 80.84% of carbohydrates in flours made using potato cultivars Agata and Cristina, respectively. Trancoso-Reyes et al. (2016)TRANCOSO-REYES, N; OCHOA-MARTÍNEZ, LA; BELLO-PÉREZ, LA; MORALES-CASTRO, J; ESTÉVEZ-SANTIAGO, R; OLMEDILLA-ALONSO, B. 2016. Effect of pre-treatment on physicochemical and structural properties, and the bioaccessibility of β-carotene in sweet potato flour. Food Chemistry 200: 199-205. found 87% of carbohydrates in sweet potato flour, higher values comparing with the ones reported for potato flour.

Potatoes are a good source of phenolic compounds: the main ones are phenolic acids and flavonoids, including flavonols and anthocyanins (Akyol et al., 2016AKYOL, H; RICIPUTI, Y; CAPANOGLU, E; CABONI, MF; VERARDO, V. 2016. Phenolic compounds in the potato and its byproducts: an overview. International Journal of Molecular Sciences 17: 835-853.). Total phenolic compound content in UB potato flour was higher (p= 0.001) than in BC flour, probably the thermal process used corroborate the reduction of total phenolic, since quantity and stability of these compounds are differently associated with processing thermal conditions (Lemos et al., 2014LEMOS, M; ALIYU, M; HUNGERFORD, G. 2014. Influence of cooking on the levels of bioactive compounds in purple majesty potato observed via chemical and spectroscopic means. Food Chemistry 173: 462-467.; Siroha & Sandhu, 2017SIROHA, AK; SANDHU, KS. 2017. Effect of heat processing on the antioxidant properties of pearl millet (Pennisetum glaucum L.) cultivars. Journal of Food Measurement and Characterization 11: 872-878.). Moreover, the absence of phenylalanine-ammonia-lyase (PAL), which can be inactivated by thermal processing could also have collaborated with the reduction of total phenolic compounds in BC potato flour, taking into consideration that such enzyme is involved in total phenolic processing metabolism (Cantos et al., 2002CANTOS, E; TUDELA, JÁ; GIL, MI; ESPÍN, JC. 2002. Phenolic compounds and related enzymes are not rate-limiting in browning development of fresh-cut potatoes. Journal of Agricultural and Food Chemistry 50: 3015-3023.). The mechanical stress caused by the processing in cellular tissue of the plants results in an increase of the activity of the enzyme PAL (Palharini et al., 2015PALHARINI, MCA; SANTOS, CAJP; SIMIONATO, EMRS; KODAWARA, RK; KLUGE, RA. 2015. Dióxido de cloro no controle da microbiota e do escurecimento enzimático de vagem minimamente processada. Horticultura Brasileira33: 181-188.), causing an increase in the concentration of phenolic compounds (Cantos et al., 2002CANTOS, E; TUDELA, JÁ; GIL, MI; ESPÍN, JC. 2002. Phenolic compounds and related enzymes are not rate-limiting in browning development of fresh-cut potatoes. Journal of Agricultural and Food Chemistry 50: 3015-3023.).

L* value of UB potato flour was smaller (p= 0,001) than in BC flour (Table 2), showing that this flour remained darker, in relation, mainly, to the presence of PPO and POD enzymes, which are responsible for the enzymatic browning reaction, which lead to formation of dark compounds (Araújo, 2008ARAÚJO, JMA. 2008. Química de alimentos. Viçosa: UFV. P 389-391.). Although both flours present color closer to red, the authors noticed that a* value of UB flour was higher (p= 0.001) than in BC, possibly due to enzymatic browning, since this reaction initiated with reddish color (Lovatto et al., 2012LOVATTO, MT; BISOGNIN, DA; TREPTOW, RO; STORCK, L; GNOCATO, FS; MORIN JUNIOR, G. 2012. Processamento mínimo de tubérculos de batata de baixo valor comercial. Horticultura Brasileira 30: 258-265.). Identically, b* and C* values of UB flour was higher (p= 0.002) than BC flour, showing that this flour remained yellow and with higher color intensity. According to Goyeneche et al. (2014GOYENECHE, R; AGÜERO, MV; ROURA, S; SCALA, KD. 2014. Application of citric acid and mild heat shock to minimally processed sliced radish: color evaluation. Postharvest Biology and Technology 93: 106-113.), these results are related to browning reaction.

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Table 2
Instrumental color evaluation of potato flours. Ponta Grossa, UTFPR, 2018.

Process of producing potato flour, besides aggregating value to tubers which would be discarded, provides a new product with nutritional quality of fresh potato, associated with longer shelf life, considering that dehydration may reduce 95% of potato initial moisture. Additionally, blanching process improved the supply of proteins and soluble fibers of the final product, as this thermal treatment is able to inactivate enzymes, such as proteases and pectinases, besides PPO and POD; prevented enzymatic browning reaction which would result in color alteration of flour; however, this process reduced total phenolic compound content.

ACKNOWLEDGEMENTS

The authors thank Coordination of Improvement of Higher Education Personnel (CAPES)for the financial support for postgraduate studies in the area of Production Engineering.

REFERENCES

AKYOL, H; RICIPUTI, Y; CAPANOGLU, E; CABONI, MF; VERARDO, V. 2016. Phenolic compounds in the potato and its byproducts: an overview. International Journal of Molecular Sciences 17: 835-853.
ANVISA. 1978. Agência Nacional de Vigilância Sanitária: Resolução - CNNPA nº 12, de 1978 p 21-24.
AOAC. 2005. Official methods of analysis of AOAC international Washington: AOAC.
ARAÚJO, JMA. 2008. Química de alimentos Viçosa: UFV. P 389-391.
BUCKLEY, RR; GIORGIANNI, EJ. 2015. Encyclopedia of color science and technology Berlin Heidelberg: Springer. p 1-9.
CANTOS, E; TUDELA, JÁ; GIL, MI; ESPÍN, JC. 2002. Phenolic compounds and related enzymes are not rate-limiting in browning development of fresh-cut potatoes. Journal of Agricultural and Food Chemistry 50: 3015-3023.
ESCARAMBONI, E; SILVA, DF; N NETO, PO. 2013. Influência da temperatura na atividade de amilase e protease de Rhizopus oligosporus cultivado por fermentação em estado sólido. Biochemistry and Biotechnology Reports 2: 285-288.
GARMUS, TT; BEZERRA, JRMV; RIGO, M; CÓRDOVA, KRV. 2009. Elaboração de biscoitos com adição de farinha de casca de batata (Solanum tuberosum L.). Revista Brasileira de Tecnologia Agroindustrial 3: 56-65.
GOYENECHE, R; AGÜERO, MV; ROURA, S; SCALA, KD. 2014. Application of citric acid and mild heat shock to minimally processed sliced radish: color evaluation. Postharvest Biology and Technology 93: 106-113.
GUERRA, AMN; FERREIRA, JBA; COSTA, ACM; TAVARES, PRF. 2014. Causas de perdas pós colheita em cenoura e batata no mercado varejista de Santarém-PA. Revista Tecnologia e Ciência Agropecuária 8: 61-68.
IBGE. 2017. Brazilian Institute of Geography and Statistics Rio de Janeiro: IBGE. 93p.
KAUR, A; KOCHHAR, A; PRASAD, P. 2016. Nutritional evaluation of value added products using potato flour. International Journal of Health Sciences and Research 6: 466-472.
LEIVAS, CL; COSTA, FJOG; ALMEIDA, RR; FREITAS, RJS; STERTZ, SCS; SCHNITZLER, E. 2013. Structural, physico-chemical, thermal and pasting properties of potato (Solanum tuberosum L.) flour. Journal of Thermal Analysis and Calorimetry 111: 2211-2216.
LEMOS, M; ALIYU, M; HUNGERFORD, G. 2014. Influence of cooking on the levels of bioactive compounds in purple majesty potato observed via chemical and spectroscopic means. Food Chemistry 173: 462-467.
LOMBARDO, S; PANDINO, G; MAUROMICALE, G. 2013. The influence of growing environment on the antioxidant and mineral content of “early” crop potato. Journal of Food Composition and Analysis32: 28-35.
LOVAT, C; NASSAR, AMK; KUBOW, S; LI, XQ; DONNELLY, DJ. 2016. Metabolic biosynthesis of potato (Solanum tuberosum L.) antioxidants and implications for human health. Critical Reviews in Food Science and Nutrition 56: 2278-2303.
LOVATTO, MT; BISOGNIN, DA; TREPTOW, RO; STORCK, L; GNOCATO, FS; MORIN JUNIOR, G. 2012. Processamento mínimo de tubérculos de batata de baixo valor comercial. Horticultura Brasileira 30: 258-265.
MURNIECE, I; KARKLINA, D; GALOBURDA, R; SANTARE, D; SKRABULE, I; COSTA, HS. 2011. Nutritional composition of freshly harvested and stored Latvian potato (Solanum tuberosum L.) varieties depending on traditional cooking methods. Journal of Food Composition and Analysis 24: 699-710.
NASCIMENTO, RF; CANTERI, MHG. 2016. Modificação das fibras dietéticas no armazenamento de vegetais sem tratamento térmico. Revista Brasileira de Produtos Agroindustriais 18: 423-426.
PALHARINI, MCA; SANTOS, CAJP; SIMIONATO, EMRS; KODAWARA, RK; KLUGE, RA. 2015. Dióxido de cloro no controle da microbiota e do escurecimento enzimático de vagem minimamente processada. Horticultura Brasileira33: 181-188.
QUADROS, DA; IUNG, MC; FERREIRA, SMR; FREITAS, RJS. 2009. Composição química de tubérculos de batata para processamento, cultivados sob diferentes doses e fontes de potássio. Ciência e Tecnologia de Alimentos 29: 316-323.
RAFIQ, SM; GHOSH, BC. 2017. Effect of potato incorporation on the physico-chemical, textural and sensory properties of processed cheese. Journal of Food Measurement and Characterization 11: 776-780.
SANTOS, AP. 2009. Farinha de batata (Solanum tuberosum L.): obtenção, caracterização físico-química, funcional, elaboração e caracterização de sopas desidratadas Itapetinga: UESB. 105p(MSc. thesis).
SCHULTZ, C. 2016. Water activity as related to microorganisms in the manufacturing environment. General Internal Medicine and Clinical Innovations1: 1-2.
SHIN, EH; BAIK, MY; KIM, HS. 2015. Comparison of physicochemical properties of starches and parenchyma cells isolated from potatoes cultivated in Korea. Food Science and Biotechnology 24: 955-963.
SIROHA, AK; SANDHU, KS. 2017. Effect of heat processing on the antioxidant properties of pearl millet (Pennisetum glaucum L.) cultivars. Journal of Food Measurement and Characterization 11: 872-878.
TRANCOSO-REYES, N; OCHOA-MARTÍNEZ, LA; BELLO-PÉREZ, LA; MORALES-CASTRO, J; ESTÉVEZ-SANTIAGO, R; OLMEDILLA-ALONSO, B. 2016. Effect of pre-treatment on physicochemical and structural properties, and the bioaccessibility of β-carotene in sweet potato flour. Food Chemistry 200: 199-205.
VIRMOND, EP; KAWAKAMI, J; VONCIK, KS; CÓRDOVA, KRV; SLOMPO, PJH. 2014. Características físico-químicas de cultivares de batata sob cultivo orgânico. Ambiência10: 31-42.
YAMDEU, JHG; GUPTA, PH; PATEL, NJ; SHAH, A; TALATIJ, G. 2016. Effect of storage temperature on carbohydrate metabolism and development of cold-induced sweetening in Indian potato (Solanum tuberosum L.) varieties. Journal of Food Biochemistry 40: 71-83.
ZÖRBA, C; SENBAYRAMB, M; PEITER, E. 2014. Potassium in agriculture - Status and perspectives. Journal of Plant Physiology171:656-669.

Publication Dates

Publication in this collection
Oct-Dec 2018

History

Received
17 Oct 2017
Accepted
11 Sept 2018

Este é um artigo publicado em acesso aberto sob uma licença Creative Commons

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Determinations	UB	BC	p
Moisture (%)	3.25±0.11	4.48±0.38	0.006
Ashes (%)	6.95±0.83	6.91±0.48	0.065
Proteins (%)	1.70±0.01	2.40±0.06	0.001
Lipids(%)	0.69±0.08	0.62±0.07	0.337
Insoluble fibers (%)	6.28±0.36	4.06±0.42	0.002
Soluble fibers (%)	1.33±0.21	1.82±0.10	0.024
Carbohydrates (%)	83.02±1.04	80.67±1.50	0.090
Total phenolic compounds (TAN/g)	1.43±0.01	1.09±0.02	0.001

Coordinates	UB	BC	p
L*	46.72±0.02	55.29±0.01	0.001
a*	2.69±0.03	1.24±0.02	0.001
b*	8.20±0.01	6.09±0.03	0.002
C*	8.63±0.01	6.22±0.03	0.002

Brasil