학술논문
Estudio de la relación estructura-propiedadproceso en cinco variedades de patata (Solanum tuberosum) durante el proceso de fritura
Document Type
Dissertation/Thesis
Author
Source
TDX (Tesis Doctorals en Xarxa)
Subject
Language
Spanish; Castilian
Abstract
Las propiedades de los alimentos están en función de su estructura y los cambios generados por el procesamiento. Sin embargo, resulta imposible predecir las alteraciones que sufre un alimento a lo largo de la cadena de producción; más si se desconocen cómo se encuentran relacionadas las propiedades y la estructura de un alimento. Por tanto, es necesario desarrollar modelos capaces de predecir dichos comportamientos a lo largo de los procesos de producción. Estos nuevos modelos deben ser capaces de predecir los cambios en las propiedades del alimento debido a que utilizan relaciones simplificadas y no tienen en cuenta el efecto del proceso sobre la estructura y sobre las propiedades macroscópicas. Conscientes de este hecho, la presente tesis genera una propuesta con el interés de aportar avances en el conocimiento e interpretación de las relaciones estructura-propiedad-proceso de tejidos vegetales en cinco variedades de patata (variedad Única, variedad Liberteña, variedad Yungay, variedad Amarilis y variedad Huevo de Indio). La investigación tuvo como objetivo identificar y analizar las características microestructurales de 5 variedades de patata (Solanum tuberosum) en material fresco y en un proceso de fritura usando un arreglo factorial de temperatura (170 – 180 – 190)°C y tiempo (1.0 – 2.5 – 4.0) minutos, se midió dos tipos de características, las primeras de tipo microestructural (área, perímetro, longitud de eje mayor, longitud de eje menor, redondez, elongación y compactación) y la segunda de tipo fisicoquímico (L*, a*, b*. ∆E, concentración de acrilamida, porcentaje de grasa, porcentaje de humedad y textura). Para ello se implementó un software de caracterización microestructural de patata, desarrollando algoritmos para el procesamiento y análisis de imágenes y para la clasificación de características estructurales con el software Matlab (versión 2019a), obteniendo como indicadores la distribución estadística de los parámetros de tamaño y forma de cada uno de los elementos estructurales del tejido vegetal en estudio. Se generó los histogramas de los parámetros de compactación, elongación, redondez, longitud de eje mayor, longitud de eje menor, perímetro y áreas celulares para los valores de las patatas fritas de las variedades estudiadas, donde se pudo observar que el tamaño y forma de las curvas es similar para los parámetros de área, perímetro, longitud de eje mayor, longitud de eje menor y compactación. Se evaluó el efecto sobre las características microestructurales en función a variedades de patata, temperatura y tiempo de fritura donde se determinó que la variedad de patata es la que ejerce un mayor efecto significativo en los parámetros microestructurales de área, perímetro, longitud de eje mayor, longitud de eje menor, redondez, y compactación (p<0.05). El tiempo es la segunda variable con un elevado efecto, siendo significativo (p<0.05) para los parámetros microestructurales de área, perímetro, longitud de eje mayor, longitud de eje menor y compactación. Finalmente, la temperatura solo ejerce un efecto significativo (p<0.05) en los parámetros de redondez y elongación. Los coeficientes de determinación (R2) para las respuestas área, perímetro, longitud de eje mayor, longitud de eje menor, redondez, elongación y compactación son 73.1%, 73.9%, 73.4%, 71.8%, 71.3%, 77.1% y 81.3%. De la misma forma se evaluó el efecto de las variedades de patata, temperatura y tiempo de fritura sobre las características fisicoquímicas, encontrándose los coeficientes de determinación (R2) para las respuestas L*, a*, b*, ∆E, acrilamida, grasa y humedad son 76.13%, 86.9%, 82.5%, 78.3%, 94.2%, 96.4% y 98.6% respectivamente. Los valores son bastante altos para las superficies de respuesta e indicaron que los modelos cuadráticos ajustados representaron valores en el rango de 71,1% al 81.3% de la varianza en los datos experimentales, que resultaron ser significativos. Para observar la relación entre los parámetros microestructurales y fisicoquímicos se usó una correlación de Pearson donde observamos que las correlaciones entre las variables fisicoquímicas evaluadas generan correlaciones de media a fuerte, de la misma forma sucede entre las variables del tipo microestructural. Pero al evaluar las correlaciones entre variables fisicoquímicas y microestructurales podemos encontrar que en la mayoría alcanzan valores bajos y medios de correlación, siendo la variable elongación la que menos correlación tiene con variables del tipo fisicoquímico y las variables de longitud de eje mayor, longitud de eje menor, perímetro y áreas celulares los que tienen una mayor correlación lineal con las variables fisicoquímicas. Finalmente, se realizó una espectroscopía Raman con el objetivo de evaluar la presencia de aceite y su influencia en los cambios del proceso de fritura, encontrando que el contenido de aceite dentro del núcleo y la corteza de la patata frita depende de la variedad de la patata.
The properties of foods depend on their structure and the changes generated by processing. However, it is impossible to predict the alterations that a food undergoes along the production chain, even more so if the relationship between the properties and structure of a food is unknown. Therefore, it is necessary to develop models to predict these behaviors throughout the production process. These new models must be able to predict changes in food properties because they use simplified relationships and do not consider the effect of the process on the structure and macroscopic properties. Being aware of this fact, this thesis proposes to contribute to the knowledge and interpretation of the structure-property-process relationships of plant tissues in five potato varieties (Única, Liberteña, Yungay, Amarilis, and Huevo de Indio). The objective of the research was to identify and analyze the microstructural characteristics of 5 varieties of potato (Solanum tuberosum) in fresh material and a frying process using a factorial arrangement of temperature (170 - 180 - 190°C) and time (1.0 - 2.5 - 4.0 minutes). Two types of characteristics were measured: the first of microstructural type (area, perimeter, major axis length, minor axis length, roundness, elongation, and compaction); and the second of physicochemical type (L*, a*, b*. ∆E, acrylamide concentration, fat percentage, moisture percentage, and texture). For this purpose, potato microstructural characterization software was implemented, developing algorithms for image processing and analysis, and for the classification of structural characteristics with Matlab software (version 2019a), obtaining the statistical distribution of the size and shape parameters of each of the structural elements of the plant tissue under study as indicators. Histograms of the parameters of compaction, elongation, roundness, major axis length, minor axis length, perimeter, and cell areas were generated for the values of the fries of the varieties studied, where it could be observed that the size and shape of the curves are similar for the parameters of area, perimeter, major axis length, minor axis length, and compaction. The effect on the microstructural characteristics was evaluated according to potato variety, temperature, and frying time, where it was determined that the potato variety has the greatest significant effect on the microstructural parameters of area, perimeter, major axis length, minor axis length, roundness, and compaction (p<0.05). Time is the second variable with a high effect, being significant (p<0.05) for the microstructural parameters of area, perimeter, major axis length, minor axis length, and compaction. Finally, the temperature only has a significant effect (p<0.05) on the parameters of roundness and elongation. The coefficients of determination (R2) for area, perimeter, major axis length, minor axis length, roundness, elongation, and compaction responses are 73.1%, 73.9%, 73.4%, 71.8%, 71.3%, 77.1%, and 81.3%, respectively. In the same way, the effect of potato varieties, temperature, and frying time on physicochemical characteristics was evaluated, finding that the coefficients of determination (R2) for L*, a*, b*, ∆E, acrylamide, fat, and moisture responses are: 76.13%, 86.9%, 82.5%, 78.3%, 94.2%, 96.4%, and 98.6%, respectively. The values are quite high for the response surfaces and indicate that the fitted quadratic models accounted for values ranging from 71.1% to 81.3% of the variance in the significant experimental data. A Pearson correlation was used to observe the relationship between the microstructural and physicochemical parameters, where medium to strong correlations were found to be generated between the physicochemical variables evaluated. The same happens between the microstructural variables, but, when evaluating the correlations between physicochemical and microstructural variables, it was found that most of them reach low and medium correlation values, being the elongation variable the least correlated with physicochemical variables; and the major axis length, minor axis length, perimeter, and cellular areas variables, the ones that have a higher linear correlation with physicochemical variables. Finally, Raman spectroscopy was performed to evaluate the presence of oil and its influence on the changes in the frying process, revealing that oil content within the core and rind of the fried potato depends on the potato variety.
The properties of foods depend on their structure and the changes generated by processing. However, it is impossible to predict the alterations that a food undergoes along the production chain, even more so if the relationship between the properties and structure of a food is unknown. Therefore, it is necessary to develop models to predict these behaviors throughout the production process. These new models must be able to predict changes in food properties because they use simplified relationships and do not consider the effect of the process on the structure and macroscopic properties. Being aware of this fact, this thesis proposes to contribute to the knowledge and interpretation of the structure-property-process relationships of plant tissues in five potato varieties (Única, Liberteña, Yungay, Amarilis, and Huevo de Indio). The objective of the research was to identify and analyze the microstructural characteristics of 5 varieties of potato (Solanum tuberosum) in fresh material and a frying process using a factorial arrangement of temperature (170 - 180 - 190°C) and time (1.0 - 2.5 - 4.0 minutes). Two types of characteristics were measured: the first of microstructural type (area, perimeter, major axis length, minor axis length, roundness, elongation, and compaction); and the second of physicochemical type (L*, a*, b*. ∆E, acrylamide concentration, fat percentage, moisture percentage, and texture). For this purpose, potato microstructural characterization software was implemented, developing algorithms for image processing and analysis, and for the classification of structural characteristics with Matlab software (version 2019a), obtaining the statistical distribution of the size and shape parameters of each of the structural elements of the plant tissue under study as indicators. Histograms of the parameters of compaction, elongation, roundness, major axis length, minor axis length, perimeter, and cell areas were generated for the values of the fries of the varieties studied, where it could be observed that the size and shape of the curves are similar for the parameters of area, perimeter, major axis length, minor axis length, and compaction. The effect on the microstructural characteristics was evaluated according to potato variety, temperature, and frying time, where it was determined that the potato variety has the greatest significant effect on the microstructural parameters of area, perimeter, major axis length, minor axis length, roundness, and compaction (p<0.05). Time is the second variable with a high effect, being significant (p<0.05) for the microstructural parameters of area, perimeter, major axis length, minor axis length, and compaction. Finally, the temperature only has a significant effect (p<0.05) on the parameters of roundness and elongation. The coefficients of determination (R2) for area, perimeter, major axis length, minor axis length, roundness, elongation, and compaction responses are 73.1%, 73.9%, 73.4%, 71.8%, 71.3%, 77.1%, and 81.3%, respectively. In the same way, the effect of potato varieties, temperature, and frying time on physicochemical characteristics was evaluated, finding that the coefficients of determination (R2) for L*, a*, b*, ∆E, acrylamide, fat, and moisture responses are: 76.13%, 86.9%, 82.5%, 78.3%, 94.2%, 96.4%, and 98.6%, respectively. The values are quite high for the response surfaces and indicate that the fitted quadratic models accounted for values ranging from 71.1% to 81.3% of the variance in the significant experimental data. A Pearson correlation was used to observe the relationship between the microstructural and physicochemical parameters, where medium to strong correlations were found to be generated between the physicochemical variables evaluated. The same happens between the microstructural variables, but, when evaluating the correlations between physicochemical and microstructural variables, it was found that most of them reach low and medium correlation values, being the elongation variable the least correlated with physicochemical variables; and the major axis length, minor axis length, perimeter, and cellular areas variables, the ones that have a higher linear correlation with physicochemical variables. Finally, Raman spectroscopy was performed to evaluate the presence of oil and its influence on the changes in the frying process, revealing that oil content within the core and rind of the fried potato depends on the potato variety.