Biofilter aquaponic system for nutrients removal from fresh market wastewater

Aquaponics is a significant wastewater treatment system which refers to the combination of conventional aquaculture (raising aquatic organism) with hydroponics (cultivating plants in water) in a symbiotic environment. This system has a high ability in removing nutrients compared to conventional methods because it is a natural and environmentally friendly system (aquaponics). The current chapter aimed to review the possible application of aquaponics system to treat fresh market wastewater with the intention to highlight the mechanism of phytoremediation occurs in aquaponic system. The literature revealed that aquaponic system was able to remove nutrients in terms of nitrogen and phosphorus

Growth Regulators and KNO3 on Seed Germination of Angelonia salicariifolia

Angelonia salicariifolia is an herbaceous perennial native to Brazil with ornamental potential as garden plant, cut-flower and potted plant. It has blue flowers 1.0 to 1.4 cm long, in 10-30 cm long terminal racemes. In previous studies seeds of A. salicariifolia showed a positive photoblastic behavior under constant temperatures of 10, 15, 20, 25, 30 and 35 degrees C. The present study evaluated the effects of growth regulators (100, 200, 300, 400, 500 mg L-1 of gibberellic acid and 2.25, 11.3, 22.5 mg L-1 of 6-benzylamino-purine) and potassium nitrate (0.2 and 1.0 %) on promoting its seed germination. The experiment was conducted in a completely randomized design with six replications of 25 seeds, for each treatment. Seeds from dehiscent capsules were sown on one layer of filter paper and moistened with growth regulators or KNO3 solutions. Germination was carried out at 25 degrees C +/- 1 degrees C, under continuous light or darkness. Germination (protusion of the radicle) was observed daily for 20 days. In the dark, only gibberellic acid promoted seed germination. The percentage of germination and the speed of germination index at 400 mg L-1 (47.3%; 0.86) and 500 mg L-1 (52.0%; 0.95) were significantly higher compared to 100 mg L-1 (27.8%; 0.38) and 200 mg L-1 (32.3%; 0.49). The mean germination time at 500 mg L-1 (10.0 days) was significantly smaller compared to 100 mg L-1 (11.9 days) and 200 mg L-1 (11.5 days). Under light, treatments did not differ among each other or from the control, except for 22.5 mg L-1 of 6-benzylamino-purine and potassium nitrate (1.0%), which decreased the percentage of germination and the speed of germination index compared to control. The application of growth regulators or potassium nitrate under light condition is not necessary, since these treatments did not improve germination percentage or the speed of germination index

Flower differentiation of azalea depends on genotype and not on the use of plant growth regulators

Flowering is a complex process which starts with the induction and development of the flower buds. For azalea (Rhododendron simsii hybrids), flower induction was hastened by the application of chlormequat and took place within 11 days after treatment. Subsequent flower bud differentiation was not altered by the application rate of the plant growth regulators (PGR) chlormequat and paclobutrazol, nor by temperature or light sum. There were however, large genotypic variations in flower bud differentiation rate. For all cultivars a linear phase until flower primordia were fully differentiated and the style started to enlarge (flower bud stage 7), was followed by a slower final development (to stage 8). The linear phase was fastest for the semi-early flowering cultivars (‘Mont Blanc’, ‘M. Marie’ and ‘Otto’), requiring only 46 or 48 days to reach flower bud stage 7 after the first PGR treatment. Two late flowering cultivars (‘Thesla’ and ‘Sachsenstern’) had the slowest differentiation, requiring 64 days to reach stage 7. The early flowering cultivars (‘H. Vogel’ sports) and two late flowering cultivars (‘Mw. G. Kint’ and ‘Tamira’) required 54 and 52 days, respectively, after the first PGR treatment to reach stage 7. To reach flower bud stage 8, a similar trend in velocity was seen, the semi-early flowering cultivars requiring the least amount of days (17 to 18 days), the late flowering cultivars ‘Thesla’ and ‘Sachsenstern’ requiring the highest amount of days (24) and the early flowering cultivars and the late flowering cultivars ‘Mw. G. Kint’ and ‘Tamira’ requiring an intermediate number of days (20 to 22 days)

Teor e composição química do óleo essencial de alpínia em razão da adubação e da disponibilidade de água no solo

A influência de diferentes adubos e disponibilidade de água no solo foi avaliada em relação ao teor e à composição química de óleos essenciais em folhas de alpínia. O experimento foi realizado em blocos casualizados, com três repetições, em esquema de parcelas subdivididas. As parcelas corresponderam a dois limites de disponibilidade de água no solo [LDA1 - redução de 75% da capacidade total de retenção de água (CTA) - e LDA2 - redução de 50% da CTA], e as subparcelas, aos adubos: esterco bovino, cama-de-galinha, torta-de-filtro, químico e o controle não-adubado. A disponibilidade de água no solo, assim como a adubação, não influenciou no teor e na composição química de óleos essenciais aos 12 meses após o plantio. Os principais constituintes químicos (teores) dos óleos essenciais em folhas de alpínia foram: α-thujeno (6,11%), α-pineno (2,69%), sabineno (16,69%), β-pineno (4,64%), β-mirceno (1,76%), 1,8-cineol (19,41%) e 1-terpinen-4-ol (14,32%)

In Vivo Analysis of the Mesenchymal-to-Epithelial Transition During Chick Secondary Neurulation

The neural tube in amniotic embryos forms as a result of two consecutive events along the anteroposterior axis, referred to as primary and secondary neurulation (PN and SN). While PN involves the invagination of a sheet of epithelial cells, SN shapes the caudal neural tube through the mesenchymal-to-epithelial transition (MET) of neuromesodermal progenitors, followed by cavitation of the medullary cord. The technical difficulties in studying SN mainly involve the challenge of labeling and manipulating SN cells in vivo. Here we describe a new method to follow MET during SN in the chick embryo, combining early in ovo chick electroporation with in vivo time-lapse imaging. This procedure allows the cells undergoing SN to be manipulated in order to investigate the MET process, permitting their cell dynamics to be followed in vivo