Agar-supported cultivation of Halorubrum sp. SSR, and production of halocin C8 on the scale-up prototype Platotex.

Halorubrum sp. SSR was isolated from a solar saltern in Algeria. The strain exhibited a high antibiotic activity against the indicator strain Natronorubrum aibiense G23, and the bioactive compound showed thermal, acid and alkali stability. SSR was grown on agar-supported cultivation (AgSF) to compare yields and applicability with traditional submerged cultivation. AgSF scale-up was implemented taking benefit from the solid-state cultivation prototype Platotex. This technology leads to high amounts of the target Halocin and facilitate the downstream steps. The antibiotic compound was purified according to a fast efficient procedure including ion exchange chromatography followed by a fractionation on C18 Sep-Pack cartridge. The compound was identified as Halocin C8 according to N-terminal amino acid sequencing and high-resolution mass spectrometry.

Ion exchange membrane textile bioreactor as a new alternative for drinking water denitrification.

This work enters in the optics of the denitrification of a polluted water by two membrane techniques, the Donnan dialysis (DD) and the ion exchange membrane bioreactor (IEMB), using a conventional barrier, composed by an anion exchange membrane (AEM), and a hybrid barrier, where the AEM is combined to an anion exchange textile (AET). The effects of the hydrodynamic factor and the nature of the carbon source on the transfer and the reduction of nitrate ions were studied. The study results obtained through the DD showed the effectiveness of the hybrid barrier in the recovery and concentration of nitrate ions. This was also recorded during denitrification by the hybrid process, called the ion exchange membrane textile bioreactor (IEMTB), with a significant reduction of nitrates, compared to IEMB, due to the efficiency of the Pseudomonas aeruginosa biofilm formed at the surface of the AET. Here, the permselectivity of the membrane and the good bioreduction of the pollutants are no longer major conditions to the better performance of the process. The application of IEMTB in the denitrification of groundwater, having a nitrate concentration of 96.67 ppm, shows a total reduction of nitrate ions without changing the quality of the water. Indeed, the analysis of the recovered water, or yet the treated water, shows the absence of the bacterium by-products and concentrations in the nitrates and nitrites which are, respectively, equal to 0.02±0.01 ppm, and inferiors to the detection limit (<0.02 ppm).