Advances in Technologies for Boron Removal from Water: A Comprehensive Review

Relationship between distance to boron mine and exposure in cattle

Boron, a valuable underground mineral whose usage area is increasing day by day, has been identified as an essential trace element in plant development. However, research on its usage for humans and animals is still ongoing. Recommended doses are physiologically involved in many systems, but excess boron can be risky for living organisms and the environment. Boron moves in an endless cycle between air, water, soil, and food, and can accumulate. Concentration can rise too much, especially in areas with boron mines. This situation causes contamination in the environment and directly affects human, animal and plant health. There is a paucity of research on the residue status of boron mineral, which is extensively mined and frequently used in certain regions, notably Turkey. In our study, we sought to ascertain the effects of proximity to boron mines on boron concentration in blood, urine, water, and feed in animals. In the study, 60 (20*3) cattle living in areas 0-5, 5-15 and 15-30 km away from the boron mine site were used. Blood and urine samples were taken from cattle. Boron concentrations were determined by sampling the feed and water they consumed. The results of the analyses demonstrated that boron levels in all samples were influenced by the distance to the mine. A statistically significant decrease was observed, particularly in drinking water and blood boron levels. This situation is a major risk factor, especially for living organisms in proximity to boron and other mines. It is also recommended to establish more comprehensive studies investigating the effects of boron concentration on living organisms.

Green biotechnological synthesis of rare sugars/alcohols: D-allulose, allitol, D-tagatose, L-xylulose, L-ribose

Rare sugars are paid more attention because of which have the characteristics of low calorie, low absorption and excellent physiological functions. Biotechnological synthesis of rare sugars has the advantages of being green, clean, simple and economic compared to chemical synthesis. Abundant enzymes for rare sugars biosynthesis are introduced and multienzyme cascade catalytic system (MECCS) used in biosynthesis of rare sugars is highlighted in this paper. Different biosynthesis pathways of five important rare sugars (D-allulose, allitol, D-tagatose, L-xylulose, l-ribose), mainly containing isomerization/epimerization reaction (existing thermodynamic equilibrium limitation), reduction-oxidation reaction (needing expensive cofactors) and phosphorylation-dephosphorylation reaction pathways (inherent constraint of thermodynamic equilibrium and requirement high-cost cofactors) etc., are reviewed. Furthermore, techniques of cofactor regeneration and enzyme/cell immobilization are provided. Finally, unique insights and expectations for future development in biosynthesis of rare sugars are given. This review provides a comprehensive analysis of the latest biotechnological advancements in the biosynthesis of rare sugars/alcohols, highlighting innovative multienzyme cascade catalytic systems and cofactor regeneration strategies.

Evaluation of the Effect of Polyethylenimine on Boron Adsorption by Soil Minerals

The removal of hazardous ions from water is crucial for safeguarding both the environment and human health. Soil minerals, integral components of soil, play a vital role as adsorbents for various contaminants, including heavy metal ions, organic dyes, and detergents. This study investigates the interaction between boron ions and soil minerals (gibbsite, kaolinite, and montmorillonite) in the presence of polyethylenimine (PEI). The minerals underwent characterization based on specific surface area, particle size distribution, zeta potential, and the presence of functional groups. The influence of PEI addition on the stability of the soil mineral suspension was evaluated by turbidimetry. Mineral-boron and mineral-boron-PEI interactions were explored under varying conditions, including pH, initial boron concentration, and mineral quantity, with all adsorption experiments conducted over 24 hours. Using the Langmuir isotherm, the maximum adsorption capacity of the studied minerals was determined for boron both without and in the presence of PEI. For gibbsite, kaolinite and montmorillonite, it was 30.63, 24.55 and 26.62 mg g-1, respectively, while in the presence of PEI, it increased to 33.11, 26.61 and 45.47 mg g-1, respectively. The addition of PEI enhanced boron adsorption from aqueous solutions, increasing the removal efficiency from 65 % to about 80 %.

Hydrophilic magnetic Ti3C2Tx-based nanocomposite as an efficient boron adsorbent: Synthesis, characterization, and application

It is widely recognized that wastewater containing boron is an environmental issue. Therefore, the development of adsorbents with excellent adsorption capacity, stability, and recyclability is essential in water treatment applications. A Fe3O4/PDA/Ti3C2Tx/PEI/DHHA nanocomposite has been prepared that can be used to separate and recover boric acid by adjusting the pH of the solution, based on the affinity theory of boric acid and cis-diol. Through series characterization, it was determined that the adsorbent possessed good magnetic properties, high hydrophilicity and high loading capacities. In this study, 4-formylphenylboronic acid (FPBA) was selected as the model compound. The nanocomposite exhibited an adsorption equilibrium time of 10 h and an adsorption capacity of 98.99 mg/g at pH = 8.5 and 25 °C. The Langmuir isothermal model and the quasi-secondary kinetic model are both appropriate for describing the adsorption process. Thermodynamic results suggest that adsorption is a spontaneous chemisorption process. Furthermore, the nanocomposite retains good regeneration performance after five adsorption-desorption cycles.