Cell-tailored calcium carbonate particles with different crystal forms from nanoparticle to nano/microsphere

Nanoarmor: cytoprotection for single living cells

Single cell modification or hybridization technology has become a popular direction in bioengineering in recent years, with applications in clean energy, environmental stewardship, and sustainable human development. Here, we draw attention to nanoarmor, a representative achievement of cytoprotection and functionalization technology. The fundamental principles of nanoarmor need to be studied with input from multiple disciplines, including biology, chemistry, and material science. In this review, we explain the role of nanoarmor and review progress in its applications. We also discuss three main challenges associated with its development: self-driving ability, heterojunction characteristics, and mineralization formation. Finally, we propose a preliminary classification system for nanoarmor.

New Insights Into Microbial Induced Calcium Carbonate Precipitation Using Saccharomyces cerevisiae

Saccharomyces cerevisiae plays an important role in the mineralization of many metal ions, but it is unclear whether this fungus is involved in the mineralization of calcium carbonate. In this study, S. cerevisiae was cultured under various conditions to explore its ability to perform microbially induced calcium carbonate precipitation (MICP). Organic acids, yeast extract, and low-carbon conditions were the factors influencing the biomineralization of calcium carbonate caused by S. cerevisiae, and biomolecules secreted by the fungus under different conditions could change the morphology, size, and crystal form of the biosynthesized mineral. In addition, transcriptome analysis showed that the oxidation of organic acids enhanced the respiration process of yeast. This implied that S. cerevisiae played a role in the formation of calcium carbonate through the mechanism of creating an alkaline environment by the respiratory metabolism of organic acids, which could provide sufficient dissolved inorganic carbon for calcium carbonate formation. These results provide new insights into the role of S. cerevisiae in biomineralization and extend the potential applications of this fungus in the future.

Synthesis and transformation of calcium carbonate polymorphs with chiral purine nucleotides

Crystallization of CaCO3 polymorphs is controlled using the chiral purine nucleotides adenosine triphosphate (ATP) and guanosine triphosphate (GTP). The effects of ATP and GTP on the transformation of calcite into vaterite are investigated.

Yeast cell route: a green and facile strategy for biosynthesis of carbonate nanoparticles

A bioinspired strategy was proposed to synthesize biocompatible BaCO₃ nanoparticles according to intracellular chemical reactions using tactfully the interaction of endogenous CO₃²⁻ and exogenous Ba²⁺ under normal growth conditions of yeast cells.