Biosorption for Wastewater Contaminants. Группа авторов

Biosorption for Wastewater Contaminants - Группа авторов


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      The functional groups of the cell wall, such as hydroxyl, amine, carboxyl, sulfate, and phosphate, play an essential part in the biosorption process. The metal ions become attached to the functional groups on the cell wall. The general process of metal absorption includes the attachment of metal ions to reactive groups located on bacterial cell walls and the internalization of metal ions within cells (Abbas et al., 2014). The presence of glycoproteins allows more metal to be taken by gram‐positive bacteria. Less metal absorption is observed in gram‐negative bacteria due to phospholipids and lipopolysaccharides (Das et al., 2008). The action of Van der Waals forces can lead to weak physical sorption, while relatively strong physical sorption may be due to electrostatic attractions between metal ions and functional groups in the surface (Aryal, 2020). The bacteria's biosorption mechanisms and characterization have been investigated by various methods such as X‐ray diffraction, electron scanners, transmission electron microscopy, Fourier infrared spectroscopy transformation, potentiometric titrations, and energy‐dispersive X‐ray microanalysis. These methods have revealed the existence, type, and number of binding sites on the bacterial surface (Kazy et al., 2006).

      Studies have identified numerous means of improving the bacterial capacity to function as biosorbents, including chemical and genetic modification. Some concentrated on improving the active sites to enhance biosorption, while the inhibition sites on the surface of the bacteria were less often taken into consideration (Adewuyi, 2020). For large‐scale domestic and industrial wastewater treatment, several membrane bioreactors have been developed. The application of the membrane reactor has shown many advantages such as operational stability, prolonged preservation of the microorganism, maximum removal of suspended solids, low sludge production rate, ability to treat toxic organic and inorganic contaminants, compact plant size, and high degradation rate (Rana et al., 2017).

      Algae as Biosorbents

Bacterial biomass(biosorbent) Metal ions(biosorbate) Functional groups Reference
B.subtilis Chromium(III) Carboxylic group (Aravindhan et al., 2012)
E. coli Chromium (VI) Amine, phosphodiester groups (Quiton et al., 2018)
B. thuringiensisOSM29 Nickel Amine, carbonyl, carboxylic, and hydroxylgroups (Oves et al., 2013)
Arthrobacter sp. Copper Amine, carboxylic, and phosphate groups (Aryal et al., 2012)
C. mutjisii Zinc Amine, hydroxyl, ketone, and phosphategroups (Saranya et al., 2018)
Rhodococcus sp. Arsenic Amine, carboxylic, and hydroxyl groups (Prasad et al., 2011)
Pseudomonas sp. Cadmium Amine, carboxylic, hydroxyl, and phosphategroups (Huang and Liu, 2013)
B. pumilus sp. Lead Carboxylic and hydroxyl groups (Sayyadi et al., 2017)
Cupriavidusmetallidurans Silver Amino, Carboxylic, and hydroxyl groups (Shamim and Rehman, 2014)
Cupriavidusmetallidurans Selenium Amino, Carboxylic, and hydroxyl groups (Shamim et al., 2014)
Enterobacter cloacae Mercury Amino, hydroxyl groups (Rani et al., 2010)
Cupriavidusmetallidurans Gold Amino, Carboxylic, and hydroxyl groups (Monsieurs et al., 2015)
Thiobacillusthiooxidans Copper Amine, hydroxyl, ketone, and phosphategroups (Nagashetti et al., 2013)
Rhodopseudomonaspalustris
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