Uso de etileno no desverdecimento da tangerina Poncã produzida nas regiões Norte e Zona da Mata de Minas Gerais. / Ehylene degreening treatment of 'Poncã' tangerine in the North and Zona da Mata of Minas Gerais.

Costa, Marcio Gama dos Santos da

25 September 2009

Made available in DSpace on 2015-03-26T13:39:34Z (GMT). No. of bitstreams: 1 texto completo.pdf: 1636884 bytes, checksum: c966934c707a7e6bf40bfe5aee85e5a1 (MD5) Previous issue date: 2009-09-25 / Fundação de Amparo a Pesquisa do Estado de Minas Gerais / The objective of this work was to promote the degreening, without losing internal fruit quality, of Poncã tangerine from two regions of Minas Gerais. Two experiments were carried out. In the first, the fruits were harvested from a commercial orchard in the northern region, and the second experiment used fruits from Zona da Mata. Fruits were harvested when showing minimum attributes of 35% juice, 9 ° Brix and soluble solids/tritable acidity ratio of 9.5. Then the fruits were packed in airtight boxes, which were exposed for 24, 48 and 96 h to different concentrations of ethylene gas: 0, 5, 10, 20 and 40 μL.L-1, at 20 + 1 °C and 90 + 5% relative humidity, respectively. Every 24 h, the boxes were opened for renewal of internal atmosphere, by reapplying the gas until treatment end. A post-treatment phase of 96 h duration took place at the end of each exposure time, when the fruits were kept in ethylene-free atmosphere, in cold chamber, at the same temperature and relative humidity used during the exposure to ethylene. During this phase, the fruits were evaluated every 24 h, and the difference in skin color, Hue angle of the peel, total chlorophyll and carotenoid content, soluble solids content, tritable acidity and SS/TA ratio of juice, solute leakage, CO2 production and loss of fruit fresh mass. In the first experiment, the fruits showed stronger degreening with increasing time of exposure to ethylene, most markedly for 96 h. After this exposure time, the Hue angle increased from 96.1o, in the first assessment days, to 82.3o, at the end of 96 h, which was lower than values observed in naturally degreened fruits. Fruits exposed for 24 h showed evolution of the yellow peel color similar to the untreated ones. It was observed that fruits left to ripe on the plant showed non-homogeneous peel degreening. The fruits exposed to ethylene for 96 h showed no visual signs of loss of commercial quality, although there was increased solute leakage from the peel during the treatment. Soluble solids content, tritable acidity and SS/TA ratio remained unchanged throughout the assessment period. The synthesis of total carotenoids in the peel was low, from 6.0 μg/cm2, in control fruits at the end of evaluations, to a maximum of 8.2 μg/cm2, in fruits exposed to ethylene for 96 h. This synthesis was insufficient to reach the orange color, therefore, the degreening of fruit peel was due, almost exclusively, to chlorophyll degradation. In the second experiment, the fruits showed yellowing of the peel stronger than fruits of the first experiment. The exposure time of 96 h proved to be the most efficient in promoting the fruit degreening in comparison with other times. Color evolution was quite similar between the control and fruits treated for 24 and 48 h. Fruits of all treatments had very low synthesis of total carotenoids in the peel, changing from 7.3 μg/cm2 in control fruits to 9.2 μg/cm2, maximum value observed in fruits exposed to ethylene for 96 h. Even in fruits showing the strongest yellowing, there was little participation of new synthesized carotenoids in the composition of the final color. Fruits fully developed in the plant reached the maximum degreening, becoming orange, the typical color of the species. Thus, for fruits produced in the Zona da Mata region, the post-harvest degreening with ethylene is only justified to anticipate the harvest, since the region has favorable climate to natural degreening. However, for fruits produced in northern Minas Gerais, where the high temperatures prevailing throughout the year impair the natural degreening, the postharvest use of ethylene may serve to obtain a more uniform peel color. / The objective of this work was to promote the degreening, without losing internal fruit quality, of Poncã tangerine from two regions of Minas Gerais. Two experiments were carried out. In the first, the fruits were harvested from a commercial orchard in the northern region, and the second experiment used fruits from Zona da Mata. Fruits were harvested when showing minimum attributes of 35% juice, 9° Brix and soluble solids/tritable acidity ratio of 9.5. Then the fruits were packed in airtight boxes, which were exposed for 24, 48 and 96 h to different concentrations of ethylene gas: 0, 5, 10, 20 and 40 μL.L-1, at 20 + 1 °C and 90 + 5% relative humidity, respectively. Every 24 h, the boxes were opened for renewal of internal atmosphere, by reapplying the gas until treatment end. A post-treatment phase of 96 h duration took place at the end of each exposure time, when the fruits were kept in ethylene-free atmosphere, in cold chamber, at the same temperature and relative humidity used during the exposure to ethylene. During this phase, the fruits were evaluated every 24 h, and the difference in skin color, Hue angle of the peel, total chlorophyll and carotenoid content, soluble solids content, tritable acidity and SS/TA ratio of juice, solute leakage, CO2 production and loss of fruit fresh mass. In the first experiment, the fruits showed stronger degreening with increasing time of exposure to ethylene, most markedly for 96 h. After this exposure time, the Hue angle increased from 96.1o, in the first assessment days, to 82.3o, at the end of 96 h, which was lower than values observed in naturally degreened fruits. Fruits exposed for 24 h showed evolution of the yellow peel color similar to the untreated ones. It was observed that fruits left to ripe on the plant showed non-homogeneous peel degreening. The fruits exposed to ethylene for 96 h showed no visual signs of loss of commercial quality, although there was increased solute leakage from the peel during the treatment. Soluble solids content, tritable acidity and SS/TA ratio remained unchanged throughout the assessment period. The synthesis of total carotenoids in the peel was low, from 6.0 μg/cm2, in control fruits at the end of evaluations, to a maximum of 8.2 μg/cm2, in fruits exposed to ethylene for 96 h. This synthesis was insufficient to reach the orange color, therefore, the degreening of fruit peel was due, almost exclusively, to chlorophyll degradation. In the second experiment, the fruits showed yellowing of the peel stronger than fruits of the first experiment. The exposure time of 96 h proved to be the most efficient in promoting the fruit degreening in comparison with other times. Color evolution was quite similar between the control and fruits treated for 24 and 48 h. Fruits of all treatments had very low synthesis of total carotenoids in the peel, changing from 7.3 μg/cm2 in control fruits to 9.2 μg/cm2, maximum value observed in fruits exposed to ethylene for 96 h. Even in fruits showing the strongest yellowing, there was little participation of new synthesized carotenoids in the composition of the final color. Fruits fully developed in the plant reached the maximum degreening, becoming orange, the typical color of the species. Thus, for fruits produced in the Zona da Mata region, the post-harvest degreening with ethylene is only justified to anticipate the harvest, since the region has favorable climate to natural degreening. However, for fruits produced in northern Minas Gerais, where the high temperatures prevailing throughout the year impair the natural degreening, the postharvest use of ethylene may serve to obtain a more uniform peel color.

Citrus reticulata Blanco

Etileno

Degradação de clorofila

Coloração da casca

Qualidade do fruto

Citrus reticulata Blanco

Etylene

Chlorophyll degradation

Peel color

Fruit quality

Development of new types of mechanocatalytic systems / Développement de nouveaux systèmes enzymatiques mécano-transductifs

Zahouani, Sarah

25 September 2017

Le fascinant processus par lequel les signaux mécaniques sont transformés en réactions biochimiques dans la nature est appelé mécano-transduction. Le but de ma thèse a été de mimer la Nature en élaborant de nouveaux systèmes enzymatiques mécano-transductifs, i.e des matériaux capables de moduler une catalyse enzymatique lorsqu’ils sont sollicités mécaniquement. Nous avons d’abord étudié l’effet de l’étirement sur les chaînes constitutives de films multicouches de polyélectrolytes, matrices souvent utilisées pour le développement de biomatériaux intelligents. Dans le cadre d’une nouvelle stratégie axée sur la modulation mécanique de la conformation, nous avons ensuite élaboré des matrices étirables à base de poly(éthylène glycol)s. Nous avons en particulier développé de tout nouveaux revêtements covalents appelés nanogels qui se sont avérés être déposables sur le silicone étirable et fonctionnalisables avec différentes biomacromolécules, ouvrant ainsi de nouvelles routes biomimétiques. / The fascinating process by which mechanical signals are transformed into biochemical reactions in Nature is called mechanotransduction. The goal of my PhD was to mimic Nature by elaborating new types of mechanocatalytic materials, i.e materials able to modulate a catalytic activity when mechanically stimulated. We first aimed at understanding the impact of stretching on the structural properties of polyelectrolyte multilayers films, polymeric matrices often used for the design of smart biomaterials. Within the framework of a new strategy essentially relying on mechanically induced conformational changes, we then developed stretchable polymeric matrices based on poly(ethylene glycol)s. We more particularly designed new types of covalent coatings, called nanogels. We showed that these architectures were buildable on stretchable silicone and that they could be functionalized with different types of biomacromolecules; thus opening new biomimetic routes.

Mécano-transduction

Conformation

Étirement

Catalytique

Polyélectrolytes

Poly(etylene glycol)

Hydrogels

Nanogels,

Couche par couche

Mechanotransduction

Conformation

Stretching

Catalytic

Polyelectrolytes

Poly(ethylene glycol)

Hydrogels

Nanogels

Step-by-step

541.3