Biodegradation of Basic Yellow Auramine- O Dye using Staphylococcus sp. Isolated from Textile Industry Effluent

Due to the increased use of synthetic dyes in various industries, there is an increased disposal of wastewater containing harmful dyes. These, in turn, have affected plants, animals, and humans. The physical and chemical methods of dye decolorization have failed to degrade the synthetic dyes in industrial effluents completely. The microbial decolorization is better due to its versatility, dynamic metabolism, and potential machinery of enzymes. This study aimed to degrade basic yellow dye auramine O by bacteria isolated from textile industry effluent. In this regard, five bacterial strains were isolated and screened from a soil sample taken from textile industry effluent. The initial physical and biochemical characterization of the bacterial isolates 1 and 2 indicated catalase test-positive, starch test-negative, motility agar test-negative, gram staining test-positive, and morphology-bacillus. The bacterial isolates 3, 4, and 5 indicated oxidase test-negative, urease test-positive, gram staining test-negative, and morphology-staphylococcus. All the isolates were further subjected to a screening test, where isolate 5 showed maximum dye decolorization of 98.9% in 96 h. The biodegradation of dye was optimized for different values of initial pH (4-10), inoculum size (2% -10%), initial dye concentration (50 mgL-1 to400 mgL-1), carbon source (glucose, fructose, xylose, starch and lactose) and nitrogen source (peptone, ammonium sulphate, yeast extract, ammonium nitrate and urea). Maximum dye decolorization was observed for initial dye concentration of 200 mgL-1, initial pH of 6, inoculum size of 10%, yeast extract as nitrogen source, and glucose as carbon source. Therefore, dye degradation by bacteria can be used as a potential method for auramine O dye treatment.

Application of Taguchi method and response surface methodology into the removal of malachite green and auramine-O by NaX nanozeolites

In the present study, the simultaneous removal of malachite green (MG) and auramine-O (AO) dyes from the aqueous solution by NaX nanozeolites in a batch system is investigated. Taguchi method and response surface methodology (RSM) were used to optimize and model dye removal conditions. In order to do so, the effect of various factors (dyes concentration, sonication time, ionic strength, adsorbent dosage, temperature, and pH of the solution) on the amount of dye removal was evaluated by the Taguchi method. Then, the most important factors were chosen and modeled by the RSM method so as to reach the highest percentage of dye removal. The proposed quadratic models to remove both dyes were in good accordance with the actual experimental data. The maximum removal efficiencies of MG and AO dyes in optimal operating conditions were 99.07% and 99.61%, respectively. Also, the coefficients of determination (R2) for test data were 0.9983 and 0.9988 for MG and AO dyes, respectively. The reusability of NaX nanozeolites was evaluated during the adsorption process of MG and AO. The results showed that the adsorption efficiency decreases very little up to five cycles. Moreover, NaX nanozeolites were also applied as adsorbents to remove MG and AO from environmental water samples, and more than 98.1% of both dyes were removed from the solution in optimal conditions.

Non-tuberculous mycobacteria in phthisiopulmonary practice in the Republic of Uzbekistan

The objective of the study: monitoring the spectrum of non-tuberculous mycobacteria isolated from patients who referred for medical care to the Republican Specialized Scientific and Practical Medical Center of Phthisiology and Pulmonology.Subjects and methods. The diagnostic procedure of ATS/IDSA was used to define if the patient suffers from mycobacteriosis. The following specimens were collected to isolate non-tuberculosis mycobacteria: sputum, bronchoalveolar lavage fluid, feces, pleural fluid, surgical and biopsy specimens, and urine. The following tests were performed: Ziehl-Nielsen microscopy, microscopy stained by auramine-O, cultures by Middlebrook 7H9 in BACTEC™ MGIT™ 960 System, Becton Dickinson, USA. Non-tuberculosis mycobateria were differentiated from mycobacterium tuberculosis complex using the sdmpt64 chromatographic test (SD Bioline TBAg MPT64 test, Korea). The non-tuberculosis species were defined by the hybridization technology of DNA* strips GenoType Mycobacterium AS/CM, version 1.0.Results. Of 14,544 patients with suspected respiratory tuberculosis, non-tuberculous mycobacteria were detected in 38 (0.26%) of them, 17 (44.7%) patients had Mycobacterium avium complex, in them there were 26 men (68.4%) and 12 (31.6%) women. Non-tuberculosis mycobacteria were isolated mainly from sputum – in 27 (71.2%) patients and urine – in 6 (15.7%) patients. In 26 (68.4%) patients, mycobacteriosis was caused by slow-growing non-tuberculosis mycobacteria, of which Mycobacterium avium complex prevailed – in 17 people as well as Mgordonae – in 8 patients. Rapidly growing non-tuberculosis mycobacteria were identified in 12 (31.6%) patients, they included M. fortuitum (5 cases) and M. chelonae (4) prevailed.

Application of Chemometrics Into Removal of Dyes by NaX Nanozeolites: Simultaneous Model

In the present study, the simultaneous removal of malachite green (MG) and auramine-O (AO) dyes from the aqueous solution by NaX nanozeolites in a batch system is investigated. Taguchi method and response surface methodology (RSM) were used to optimize and model dye removal conditions. In order to do so, the effect of various factors (dyes concentration, sonication time, ionic strength, adsorbent dosage, temperature, and pH of the solution) on the amount of dye removal was evaluated by the Taguchi method. Then, the most important factors were chosen and modeled by the RSM method so as to reach the highest percentage of dye removal. The proposed quadratic models to remove both dyes were in good accordance with the actual experimental data. The maximum removal efficiencies of MG and AO dyes in optimal operating conditions were %99.07 and %99.61, respectively. Also, coefficients of determination (R2) for test data were 0.9983 and 0.9988 for MG and AO dyes, respectively. The reusability of NaX nanozeolites was evaluated during the adsorption process of MG and AO. The results showed that the adsorption efficiency decreases very little up to 5 cycles. Moreover, NaX nanozeolites were also applied as adsorbents to remove MG and AO from environmental water samples and more than %98.1 of both dyes were removed from the solution in optimal conditions.