M. L. Weaver scite author profile

In vitro observations have revealed major effects on the structure, growth, and composition of biomineral phases, including stabilization of amorphous precursors, acceleration and inhibition of kinetics, and alteration of impurity signatures. However, deciphering the mechanistic sources of these effects has been problematic due to a lack of tools to resolve molecular structures on mineral surfaces during growth. Here we report atomic force microscopy investigations using a system designed to maximize resolution while minimizing contact force. By imaging the growth of calciumoxalate monohydrate under the influence of aspartic-rich peptides at single-molecule resolution, we reveal how the unique interactions of polypeptides with mineral surfaces lead to acceleration, inhibition, and switching of growth between two distinct states. Interaction with the positively charged face of calcium-oxalate monohydrate leads to formation of a peptide film, but the slow adsorption kinetics and gradual relaxation to a well-bound state result in time-dependent effects. These include a positive feedback between peptide adsorption and step inhibition described by a mathematical catastrophe that results in growth hysteresis, characterized by rapid switching from fast to near-zero growth rates for very small reductions in supersaturation. Interactions with the negatively charged face result in formation of peptide clusters that impede step advancement. The result is a competition between accelerated solute attachment and inhibition due to blocking of the steps by the clusters. The findings have implications for control of pathological mineralization and suggest artificial strategies for directing crystallization.biomineralization | calcium oxalate monohydrate | crystal growth | peptide adsorption | molecular resolution

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Improved Model for Inhibition of Pathological Mineralization Based on Citrate–Calcium Oxalate Monohydrate Interaction

Weaver

Qiu

Hoyer

et al. 2006

ChemPhysChem

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M. L. Weaver

Inhibition of calcium oxalate monohydrate growth by citrate and the effect of the background electrolyte

Subnanometer atomic force microscopy of peptide–mineral interactions links clustering and competition to acceleration and catastrophe

Improved Model for Inhibition of Pathological Mineralization Based on Citrate–Calcium Oxalate Monohydrate Interaction

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