6 results on '"Brat, Pierre"'
Search Results
2. Encapsulation of thymol and limonene in metal–organic frameworks for inhibition of Colletotrichum musae growth.
- Author
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Zuniega, Johnrell, Grabulos, Joël, Lebrun, Marc, Aumond, Thibaud, Daniel, Cécile, Brat, Pierre, and Farrusseng, David
- Subjects
THYMOL ,METAL-organic frameworks ,LIMONENE ,COLLETOTRICHUM ,PHYTOPATHOGENIC fungi ,ESSENTIAL oils - Abstract
Summary: Monoterpenes are the most prevalent compounds found in essential oils. They exhibit inhibitory actions against phytopathogenic postharvest fungi. Direct application limits their effectiveness due to their instability, high volatility, hydrophobicity and susceptibility to degradation. Encapsulation systems using metal–organic frameworks (MOFs) have been developed to maximise their use. In this study, four protocols were shown to encapsulate thymol and limonene in porous solids, such as ZIF‐8, UiO‐66‐(COOH)2 and zeolite 13X. Vapourisation and diffusion at 60 °C for 16 h was found to be the most efficient encapsulation process. A larger amount of thymol than limonene was loaded in the porous solids. Thymol released from MOFs slowed down the growth of Colletotrichum musae by up to 6 days at 25 °C. There was a sustained release of thymol even beyond the period of maximum fungal growth. This proof‐of‐concept study revealed the potential utility of MOFs as carriers of thymol against postharvest fungi. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
- View/download PDF
3. Effect of high‐pressure homogenization on the sensory, nutritional and physical characteristics of mango nectar (Mangifera indica L.).
- Author
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Joly, Victoria, Brat, Pierre, Nigen, Michael, Lebrun, Marc, Maraval, Isabelle, Ricci, Julien, Forestier‐Chiron, Nelly, and Servent, Adrien
- Subjects
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MANGO , *NECTAR , *MAILLARD reaction , *PHASE separation , *TREATMENT delay (Medicine) , *CAROTENOIDS - Abstract
High‐pressure homogenization (HPH) was applied within a range of 300 to 1000 bar for 2 to 8 cycles. At constant dry matter (6.2%), pulp mass increased from 3.7 to 8%, indicating a change in particle organization. D90 varied from 197 to 20 μm depending on the pressure and number of cycles. The aggregation of particles, then destruction of the aggregates depending on the number of cycles, explained viscosity behavior. HPH delayed phase separation by an average 28.5 h. Sedimentation velocity was 10 times higher at 8 cycles than at 3 cycles, at 1000 bar. At 1000 bar, browning was observed, resulting from Maillard reactions, and was linked to the furan‐2‐pentyl content (10‐fold higher) and a 45% loss of carotenoids. This study will help in understanding changes induced in mango nectar by HPH and will be of use in developing processing technologies to preserve mango‐based products. Novelty impact statement: This study provides some additional scientific indications for understanding the subtility of HPH impacts in stabilizing mango nectar. The optimum pressure treatment for delaying phase separation (1000 bar, 3–6 cycles), i.e., reducing particle size and forming adequate re‐aggregation, also causes a Maillard reaction (2‐fold color difference, 10‐fold furan increase, etc.), hence browning through an increase in local temperature. It will therefore be necessary to find a compromise to limit degradation reactions caused by the process, and to guarantee greater consumer acceptance (phase separation and sensory quality). [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
4. Properties of beeswax antifungal coatings obtained by high‐pressure homogenisation and their application for preserving bananas during storage.
- Author
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Agyemang, Bridget, Grabulos, Joel, Hubert, Olivier, Bourlieu, Claire, Nigen, Michael, Lebrun, Marc, Coffigniez, Fanny, Guillard, Valérie, and Brat, Pierre
- Subjects
BANANAS ,EDIBLE coatings ,TROPICAL fruit ,BEESWAX ,PARTICLE size distribution ,SURFACE coatings ,WATER vapor - Abstract
Summary: Bananas are tropical fruits that are perishable and susceptible to fungal diseases, mainly caused by Colletotrichum musae. Antimicrobial emulsion‐based coating materials have been used extensively to inhibit the growth of these fungi and extend the shelf life of bananas. Targeted emulsion‐based film functionalities offer excellent mechanical, physicochemical and barrier properties and limit fungal growth kinetics. Antifungal compounds, such as essential oils or phenolic compounds, are added to emulsion‐based (wax/biopolymer) coatings to enhance their antimicrobial properties. This study set out to formulate a beeswax‐based emulsion for banana coatings using high‐pressure homogenisation (HPH) and hydrophilic food‐grade/organic coating materials. The particle size distribution, stability and mechanical properties of the film‐forming emulsions, water vapour and the oxygen permeabilities of the resulting coating were investigated. The most promising sucrose emulsions were tested as coatings on banana fruits to assess their efficacy against moisture and firmness loss during storage. Adding thymol (0.5% w/w) to the sucrose emulsions further enhanced the inhibition of Colletotrichum musae growth to its barest minimum of <20%. Emulsion stability was clearly enhanced using HPH while the best inhibition was obtained with a 20% diluted sucrose emulsion containing 0.5% thymol, with or without HPH. [ABSTRACT FROM AUTHOR]
- Published
- 2022
- Full Text
- View/download PDF
5. Specific Physiological and Anatomical Traits Associated With Polyploidy and Better Detoxification Processes Contribute to Improved Huanglongbing Tolerance of the Persian Lime Compared With the Mexican Lime.
- Author
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Sivager, Gary, Calvez, Leny, Bruyere, Saturnin, Boisne-Noc, Rosiane, Brat, Pierre, Gros, Olivier, Ollitrault, Patrick, and Morillon, Raphaël
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POLYPLOIDY ,CITRUS ,CITRUS fruit industry ,SIEVE elements ,TYPHA latifolia ,SCANNING electron microscopy ,PHYTOCHELATINS - Abstract
Huanglongbing (HLB) is presently a major threat to the citrus industry. Because of this disease, millions of trees are currently dying worldwide. The putative causal agent is a motile bacteria belonging to Candidatus Liberibacter spp., which is transmitted by psyllids. The bacteria is responsible for the synthesis of callose at the phloem sieve plate, leading to the obstruction of the pores that provide connections between adjacent sieve elements, thus limiting the symplastic transport of the sugars and starches synthesized in leaves to the other plant organs. The Persian triploid lime (Citrus latifolia) is one of the most HLB-tolerant citrus varieties, but the determinants associated with the tolerance are still unknown. HLB-infected diploid Mexican lime (Citrus aurantiifolia) and Persian lime were investigated. The leaf petiole was analyzed using scanning electron microscopy (SEM) to observe callose deposition at the phloem sieve plate. Leaf starch contents and detoxification enzyme activities were investigated. In the field, Persian lime leaves present more limited symptoms due to HLB than the Mexican lime leaves do. Photosynthesis, stomatal conductance, and transpiration decreased compared with control plants, but values remained greater in the Persian than in the Mexican lime. Analysis of the petiole sieve plate in control petiole samples showed that pores were approximately 1.8-fold larger in the Persian than in the Mexican lime. SEM analyses of petiole samples of symptomatic leaves showed the important deposition of callose into pores of Mexican and Persian limes, whereas biochemical analyses revealed better detoxification in Persian limes than in Mexican limes. Moreover, SEM analyses of infected petiole samples of asymptomatic leaves showed much larger callose depositions into the Mexican lime pores than in the Persian lime pores, whereas biochemical traits revealed much better behavior in Persian limes than in Mexican limes. Our results reveal that polyploids present specific behaviors associated with important physiological and biochemical determinants that may explain the better tolerance of the Persian lime against HLB compared with the Mexican lime. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
6. Control of banana anthracnose by hot water dip: A semi-empirical model coupling heat transfer and Colletotrichum musae inactivation.
- Author
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Siguemoto, Erica, Collombel, Ingrid, Hatchy, Charles-Gabriel, Delpech, Charlotte, Grabulos, Joel, Brat, Pierre, Hubert, Olivier, and Meot, Jean-Michel
- Subjects
- *
BANANAS , *HOT water , *HEAT transfer , *ANTHRACNOSE , *COLLETOTRICHUM , *PARAMETER identification - Abstract
A semi-empirical model was developed to predict simultaneously time-temperature distribution inside the unripe banana and fungal reduction during the hot water dip, in order to simulate different process conditions for controlling banana anthracnose disease. For this purpose, the kinetic parameters of Colletotrichum musae reduction were estimated based on the thermal death time concept (z = 3.56 °C and D 50 ° C = 1044 s), and evaluated in different simulated media (unripe and fully ripe banana peel agar media). At the same time, a heat transfer model based on the Fourier equation was developed considering two unripe banana domains (peel and pulp). The comparison between the predicted and observed number of C. musae spores after the thermal treatment of unripe banana was satisfactory (coefficient of variation less than 10%), suggesting that the survival ratio is affected by the banana composition. The resulting model can be used to simulate different time-temperature scenarios, and to show how the parameter combinations may affect C. musae reduction in the unripe banana during the hot water dip process. • Identification of the kinetic parameters of Colletotrichum musae inactivation. • Development and validation of banana heat transfer model with two domains. • Validation of the fungal reduction in unripe banana under different scenarios. • Potential of numerical modeling for evaluating decontamination of other fruit. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
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