Biomineralization is a naturally occurring process in living organisms. In this review, we discuss microbially induced calcium carbonate precipitation (MICP) in detail. In the MICP process, urease plays a major role in urea hydrolysis by a wide variety of microorganisms capable of producing high levels of urease. We also elaborate on the different polymorphs and the role of calcium in the formation of calcite crystal structures using various calcium sources. Additionally, the environmental factors affecting the production of urease and carbonate precipitation are discussed. This MICP is a promising, eco-friendly alternative approach to conventional and current remediation technologies to solve environmental problems in multidisciplinary fields. Multiple applications of MICP such as removal of heavy metals and radionuclides, improve the quality of construction materials and sequestration of atmospheric CO2 are discussed. In addition, we discuss other applications such as removal of calcium ions, PCBs and use of filler in rubber and plastics and fluorescent particles in stationary ink and stationary markers. MICP technology has become an efficient aspect of multidisciplinary fields. This report not only highlights the major strengths of MICP, but also discusses the limitations to application of this technology on a commercial scale.
Ionic liquids (ILs) are often considered to be green solvents based on their unusual stability, although their toxicity to living organisms has become an emerging issue based on a number of recent studies. We assume that one of the main reasons for this high level of cell toxicity is the molecular interactions between ILs and cell membranes. In this study, we used model cells to demonstrate that ILs can incorporate into lipid membranes, resulting in the perturbation of membrane structure. We employed various methods to elucidate the molecular interactions between cell membranes and ILs. Our results demonstrate that the stability of cell membranes is inversely related to the alkyl chain length and concentration of ILs, providing important information for the design of greener and safer ILs.
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