Your search keyword '"Dragunski DC"' showing total 2 results

1. Lithium bioaccumulation in Lentinus crinitus mycelia grown in media with different lithium sources and pH values.

Author

Faria MGI, Avelino KV, Philadelpho BO, Dos Santos Bomfim R, do Valle JS, Júnior ACG, Dragunski DC, de Souza Ferreira E, de Souza CO, Ribeiro CDF, Colauto NB, and Linde GA

Subjects

Bioaccumulation, Biomass, Hydrogen-Ion Concentration, Plant Extracts, Culture Media, Lithium, Mycelium

Abstract

Lentinus crinitus bioaccumulates lithium in mycelia, but bioaccumulation may be affected by pH of the culture medium. Lithium is used in clinical practice as a mood stabilizer and antidepressant. This study aimed to assess the effect of culture medium pH and lithium source (LiCl or Li 2 CO 3 ) on lithium bioaccumulation in vegetative mycelia of L. crinitus grown in malt extract broth. Lentinus crinitus U9-1 was cultured in malt extract broth supplemented with Li 2 CO 3 or LiCl (50 mg L -1 lithium) in the pH range of 3.0 to 6.0. The pH was adjusted using HCl solution. The results showed that medium pH affected mycelial biomass production, lithium bioaccumulation in mycelial biomass, and lithium transfer from the culture medium to mycelial biomass. The effect of lithium source on the bioaccumulation capacity of mycelial biomass varied according to pH. At pH 4.0, both lithium sources stimulated mycelial biomass production compared to the control without the addition of lithium. At pH 5.5, Li 2 CO 3 provided the highest lithium bioaccumulation in mycelial biomass. Lithium transfer from the culture medium to mycelia was highest in Li 2 CO 3 -supplemented cultures at pH 4.5. LiCl reduced hyphal width compared with Li 2 CO 3 and the control. However, pH and lithium sources did not affect the formation of clamp connections in hyphae. For the first time, the influence of the pH of the culture medium on lithium bioaccumulation by Lentinus crinitus is reported. Finally, we conclude that the culture medium pH affected lithium transfer and bioaccumulation in mycelial biomass differently depending on the lithium source. Additionally, we report the presence of clamp connections in the hyphae of L. crinitus as an indicator of even growth., (© 2022. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2022

2. Adsorption mechanism of chromium(III) using biosorbents of Jatropha curcas L.

Author

Gonçalves AC Jr, Nacke H, Schwantes D, Campagnolo MA, Miola AJ, Tarley CRT, Dragunski DC, and Suquila FAC

Subjects

Adsorption, Chromium chemistry, Kinetics, Temperature, Thermodynamics, Water Pollutants, Chemical chemistry, Chromium isolation & purification, Jatropha metabolism, Water Pollutants, Chemical isolation & purification, Water Purification methods

Abstract

The removal of Cr 3+ from water solutions by biosorbents from the rind, endosperm, and endosperm + episperm of the Jatropha curcas was evaluated. Adsorption tests were performed in batch systems for evaluating the influence of the solution's pH, adsorbent mass, contact time, initial Cr 3+ concentrations, and solution temperature during the adsorption process. Kinetic, adsorption isotherm, and thermodynamic studies were performed to investigate the mechanisms that control adsorption. Ideal conditions for the adsorption process included pH of the solution of 5.5 and 8 g L -1 adsorbent mass, within 60 min time contact between adsorbent and adsorbate. Maximum adsorption capacities by Langmuir model for rind, endosperm, and endosperm + episperm of the J. curcas were, respectively, 22.11, 18.20, and 22.88 mg g -1 , with the occurrence of chemosorption in mono and multilayers. Results show that the biosorbents obtained from J. curcas have a high potential to recuperate Cr 3+ from contaminated water sources.

Published

2017