Increased diffusivity of lycopene in hot break vs. cold break purees may be due to bioconversion of associated phospholipids rather than differential destruction of fruit tissues or cell structures.

Lycopene bioaccessibility is enhanced by processing, as explained by the destructuration of plant tissues, making diffusion easier. However, in tomato, the relationship between grinding intensity and lycopene release from purees suffers from uncertainty. In particular, hot break puree exhibited twice as much diffusible lycopene as compared to cold break, while both were processed with the same grinding intensity. To explain the difference, we systematically studied the diffusivity of particles according to their size and integrity, and used microscopic and physical analyses to reveal structural differences. Neither particle size distribution, nor cell destruction, nor plastid transformation exhibited any correlation to the differences in diffusivity. However, Raman microspectroscopy combined with a chemometric analysis revealed significant changes in lycopene spectra and a putative linkage to phospholipid transformation. Phospholipid profiling of five pairs of contrasted purees revealed that, during the cold break, a transition from complex phospholipids to more simple phosphatidic acid molecules systematically occurred.

Hydrosols of orange blossom (Citrus aurantium), and rose flower (Rosa damascena and Rosa centifolia) support the growth of a heterogeneous spoilage microbiota.

Hydrosols are hydrodistillation products of aromatic plants. They contain less than 1g/L of dispersed essential oils giving organoleptic properties. Hydrosols are subjected to microbial proliferation. Reasons for spoilage have to be found in the nature of substrates supporting growth and of microbiological contaminants. The composition in essential oils and the microbiota of 22 hydrosol samples of Citrus aurantium L. ssp. amara L. (orange blossom), Rosa damascena Miller (rose D.), and Rosa centifolia L. (rose C.) flowers were analyzed to determine the factors responsible for decay. The median concentrations in essential oils were 677mg/L for orange blossom hydrosols, 205mg/L for rose D. hydrosols, and 116mg/L for rose C. hydrosols. The dry matter content of these hydrosols varied between 4.0mg/L and 702mg/L, and the carbohydrate content varied between 0.21mg/L and 0.38mg/L. These non-volatile compounds were likely carried over during distillation by a priming and foaming effect, and could be used as nutrients by microorganisms. A microbial proliferation at ambient temperature and also at 5°C has been observed in all studied hydrosols when stored in a non-sterile container. In contaminated hydrosols, maximal counts were about 7log10CFU/mL, while the French pharmacopeia recommends a maximal total bacterial count of 2log10CFU/mL. Neither yeast nor mold was detected. The isolated microbial population was composed of environmental Gram-negative bacteria, arranged in four major genera: Pseudomonas sp., Burkholderia cepacia complex, and presumably two new genera belonging to Acetobacteraceae and Rhodospirillaceae. Among those bacteria, Burkholderia vietnamiensis and Novosphingobium capsulatum were able to metabolize volatile compounds, such as geraniol to produce 6-methyl-5-hepten-2-one or geranic acid, or phenylethyl acetate to produce 2-phenylethanol. EO concentrations in hydrosols or cold storage are not sufficient to insure microbiological stability. Additional hurdles such as chemical preservatives or aseptic packaging will be necessary to insure microbial stability.