Ultrasonication for tomato pectinmethylesterase inactivation: effect of cavitation intensity and temperature on inactivation

Raviyan, Patcharin; Zhang, Z.; Feng, Hao

doi:10.1016/j.jfoodeng.2004.09.028

Cited by 156 publications

(90 citation statements)

References 26 publications

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“…Enzyme inactivation generally increases with increasing ultrasound power, ultrasound freqency, exposure time, amplitude level, cavitation intensity, processing temperature and processing pressure, but decreases as the volume being treated increases [34,35,41,46].…”

Section: Enzyme Inactivationmentioning

confidence: 99%

“…Since then, it has been proven that ultrasound is an effective method in the inactivation of enzymes when it is used alone or with temperature and pressure. There are many enzymes inactivated with ultrasound such as glucose oxidase [32], peroxidase [17,33], pectin methyl esterase [34], protease and lipase [35], watercress peroxidase [36] and polyphenoloxidase [15]. Table 2 summarizes the ultrasound application on enzymes.…”

Section: Enzyme Inactivationmentioning

confidence: 99%

“…The ultrasound stability of individual proteins varies between the enzymes [35,41,44,45] and also depends on ultrasound treatment conditions [34], the composition of treatment medium, treatment pH, and whether they are bound (e.g., membrane-bound proteins) or free (e.g., cytoplasmic proteins). Enzyme inactivation generally increases with increasing ultrasound power, ultrasound freqency, exposure time, amplitude level, cavitation intensity, processing temperature and processing pressure, but decreases as the volume being treated increases [34,35,41,46].…”

Section: Enzyme Inactivationmentioning

confidence: 99%

“…Raviyan, et al [34] indicate that when sonication is combined with heat, tomato pectin methylesterase is inactivated effectively compared to thermal treatment at the same temperature. Also, it was concluded that the thermosonication treatment is more effective in inactivation of a number of enzymes including the pectinmethylesterase, polygalacturonase and peroxidase than heat treatment [17, 48,49].…”

Section: Enzyme Inactivationmentioning

confidence: 99%

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Use of ultrasound in food preservation

Ercan¹,

Soysal²

2013

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Ultrasound is versatile and innovative technology due to its wide range of application and increase in knowledge and research studies. It is used in food industry for many purposes including analysis methods and food processings such as freezing, cutting, drying, tempering, homogenization, degassing, antifoaming, filtration and extraction. Ultrasound can be used as a promoter or alternative to food processing. There may be numereous advantages of using ultrasound for food processing such as effective mixing, increased mass transfer, reduced energy, reduced temperature and increased production rate. Due to the elimination of microorganisms and enzymes without destroying nutrients of foods, ultrasound can be used as an alternative method to thermal treatments in the food preservation. Additionally, low power ultrasound is thought to be an attractive nonthermal method due to overcome problems which occur during heat treatments such as physical and chemical changes, nutritional loss and change in organoleptic properties. This review summarizes mechanism, operation and latest potential applications of ultrasound in the food preservation.

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Section: Enzyme Inactivationmentioning

confidence: 99%

Section: Enzyme Inactivationmentioning

confidence: 99%

Section: Enzyme Inactivationmentioning

confidence: 99%

Section: Enzyme Inactivationmentioning

confidence: 99%

See 2 more Smart Citations

Use of ultrasound in food preservation

Ercan¹,

Soysal²

2013

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“…La presencia de PME provoca que en las bebidas de estos frutos se formen dos fases, una de ellas clara en la parte superior y otra turbia en la parte inferior dejando un aspecto visible indeseado en el producto final; sin embargo, para reducir la actividad PME en alimentos con alto contenido de pectina una alternativa es la pasteurización (Cinquanta et al, 2010;Anthon et al, 2002), con la cual, se logra reducir a niveles aceptables  10% la actividad enzimática residual, factor problema en la calidad de jugos (Osorio et al, 2008;Carbonell et al, 2006), sin embargo los jugos comerciales conservados por pasteurización sometidos a temperaturas altas y tiempos prolongados, reducen también componentes deseables como nutrientes, color, aroma y textura que se destruyen en diferentes porcentajes, resultando en pérdidas significativas de calidad (Tribess y Tadini, 2006;Raviyan et al, 2005), de ahí la importancia de optimizar el tratamiento térmico aplicado mediante la aplicación de diseños experimentales, que permitan conservar al máximo los atributos de calidad del jugo (Montgomery y Runger, 2003). Aspectos técnicos que aún no han sido abordados en la Uchuva y que de alguna manera potencializarían la posible industrialización de este importante fruto de las zonas andinas, donde el fruto se produce.…”

Section: Introductionunclassified

Inactivación Térmica de Pectinmetilesterasa en Jugo de Uchuva (Physalis peruviana L.)

2014

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ResumenSe analiza la posibilidad de procesamiento industrial de la uchuva (Physalis peruviana L.). Para ello se estudió el efecto de la pasteurización sobre la reducción en la actividad de la pectinmetilesterasa y sobre las características sensoriales del jugo de uchuva. Se aplicaron dos diseños experimentales para el proceso térmico: el primero con temperaturas entre 60 y 90 °C y tiempos de exposición entre 20 y 60 s y el segundo con temperaturas entre 70 y 80 °C y tiempos entre 10 y 30 s. El jugo fue pasteurizado en tubos capilares para micro hematocrito. La actividad enzimática residual fue evaluada mediante espectrofotometría UV-VIS a 620 nm. Las propiedades sensoriales (acidez, color, olor y sabor), se avaluaron mediante panel entrenado (n=15). Como resultado, el punto óptimo de pasteurización se encontró a una temperatura de 80 °C por 10 s con una actividad enzimática residual del 9,32%. Con estos tratamientos térmicos no se apreciaron cambios sensoriales significativos (P>0.05) entre el jugo pasteurizado y el jugo natural.Palabras claves: pasteurización, pectinmetilesterasa, capilares, espectrofotometría, uchuva. Thermal Inactivation of Pectinmethylesterase in Cape Gooseberry Juice (Physalis peruviana L.) AbstractThe possibility of industrial processing of cape gooseberry (Physalis peruviana L.) is analyzed. To do this, the effect of pasteurization on reduction in pectinmethylesterase activity and sensory characteristics of gooseberry juice was determined. Two experimental designs were applied to the thermal process: the first with temperatures between 60 °C and 90 °C and exposure times between 20 s and 60 s and the second with temperatures between 70 °C and 80 °C and times between 10 s and 30 s. The juice was pasteurized in micro hematocrit capillary tubes. The residual enzyme activity was evaluated by spectrophotometry at 620 nm UV-VIS. The sensory properties such as acidity, color, smell and taste, were valued by trained panel (n = 15). As a result the optimum pasteurization was found at a temperature of 80 °C for 10 s with a residual enzyme activity of 9.32%. With these heat treatments, no significant sensory changes (P> 0.05) were observed between pasteurized juice and natural juice.

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