Time‐Resolved Dynamics of Struvite Crystallization: Insights from the Macroscopic to Molecular Scale

Kim, Doyoung; Olympiou, Chara; McCoy, Colin; Irwin, Nicola; Rimer, Jeffrey D.

doi:10.1002/chem.201904347

Cited by 18 publications

(19 citation statements)

References 70 publications

(148 reference statements)

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“…We recently used in situ AFM to establish that struvite crystal growth follows a classical mechanism, whereby new layers nucleate on crystal surfaces and advance by the incorporation of solute molecules at steps. 50 Indeed, a snapshot of a (101) surface during growth in a supersaturated solution (Figure 6A)…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…AFM has proven to be a powerful technique for characterizing the growth of crystal surfaces in the absence and presence of inhibitors. We recently used in situ AFM to establish that struvite crystal growth follows a classical mechanism whereby new layers nucleate on crystal surfaces and advance by the incorporation of solute molecules at steps 50 . Indeed, a snapshot of a (101) surface during growth in supersaturated solution (Figure 6A) shows the presence of layers emanating from the bottom left (outside the frame of imaging) with heights equivalent to a single unit cell (h = 0.58 nm).…”

Section: Microfluidics Analysis Of Crystal Growth Inhibitionmentioning

confidence: 99%

“…A microfluidics device was used to examine struvite growth at macroscopic length scale. The device (poly(dimethylsiloxane) (PDMS) on glass) used for these experiments followed the same set up and fabrication protocol as reported in previous work. , This system was monitored under continuous supply of a growth solution using a semiautomatic inverted light microscope (Leica DMi8 equipped with PL Fluotar 5×, 10×, 20×, and N Plan L 50× objectives).…”

Section: Experimental Sectionmentioning

confidence: 99%

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Engaging a Battle on Two Fronts: Dual Role of Polyphosphates as Potent Inhibitors of Struvite Nucleation and Crystal Growth

et al. 2020

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Polyprotic acids often serve as effective regulators of inorganic crystallization in natural, biological, and synthetic systems.These molecules or macromolecules can function as efficient modifiers that either inhibit or promote crystal growth. Few studies report potent inhibitors of crystal nucleation owing to the presumed challenges of hindering these stochastic events; however, in this study we have identified polyphosphates that operate as potent inhibitors of both nucleation and crystal growth of the natural mineral struvite (MgNH4PO4ˑ6H2O), which is a common component of scale in commercial and physiological processes (e.g. water purification and kidney disease). Systematic investigation of linear and cyclic polyphosphates of varying molecular weight reveal that micromolar concentrations of three modifiers, hexametaphosphate, polyphosphate type 45, and phytic acid, lead to suppressed struvite nucleation. Combined studies of struvite growth at the macroscopic level using microfluidics to track anisotropic rates of crystallization and at the molecular level using in situ atomic force microscopy (AFM) to monitor layered growth of crystal surfaces collectively reveal that these modifiers are also capable of fully suppressing crystal growth via their affinity to interact with all principal crystal facets. Time-resolved AFM images of the (101) surface at varying polyphosphate concentrations reveal a unique mode of crystal growth inhibition wherein surfaces become laden with an amorphous layer that leads to roughened interfaces and growth succession through dynamic sequences that are not commonly witnessed for other minerals. It is also observed under certain conditions that inhibitors can induce significant changes in crystal morphology, leading to exquisite leaf-like hierarchical structures. The discovery of potent inhibitors of struvite formation that operate by unparalleled dual modes of action capable of suppressing both nucleation and crystal growth has potential implications for their use in the prevention of commercial scale in water purification as well as in the treatment of kidney stones. Moreover, the fundamental mechanisms of polyphosphates identified in this study may prove to be relevant for other inorganic crystals given the ubiquitous use of inhibitors in processes spanning from biomineralization to crystal engineering.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Section: Microfluidics Analysis Of Crystal Growth Inhibitionmentioning

confidence: 99%

Section: Experimental Sectionmentioning

confidence: 99%

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Engaging a Battle on Two Fronts: Dual Role of Polyphosphates as Potent Inhibitors of Struvite Nucleation and Crystal Growth

et al. 2020

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“…Such studies, together with recent advances in 4D printing (Sydney Gladman et al, 2016), may enable optimization of the design of ureteral stents by prescribing desired properties. Meanwhile, several studies in microbiology have shown the influence of fluid mechanical characteristics on microbial behavior (Kim, Olympiou, McCoy, Irwin, & Rimer, 2020; Laffite et al, 2016; Salta et al, 2013; Zalewska‐Piatek et al, 2020) especially the correlation between the micro‐scale shear stress field and the mobility or attachment of bacteria (Rusconi & Stocker, 2015; Sherman et al, 2019). These efforts will open new avenues to the study of urinary flows, leading to novel ideas and solutions for various urological symptoms, ultimately contributing to the well‐being of individual patients.…”

Section: Discussionmentioning

confidence: 99%

Fluid mechanical modeling of the upper urinary tract

Zheng

Carugo

Mosayyebi

et al. 2021

WIREs Mechanisms of Disease

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The upper urinary tract (UUT) consists of kidneys and ureters, and is an integral part of the human urogenital system. Yet malfunctioning and complications of the UUT can happen at all stages of life, attributed to reasons such as congenital anomalies, urinary tract infections, urolithiasis and urothelial cancers, all of which require urological interventions and significantly compromise patients' quality of life. Therefore, many models have been developed to address the relevant scientific and clinical challenges of the UUT. Of all approaches, fluid mechanical modeling serves a pivotal role and various methods have been employed to develop physiologically meaningful models. In this article, we provide an overview on the historical evolution of fluid mechanical models of UUT that utilize theoretical, computational, and experimental approaches. Descriptions of the physiological functionality of each component are also given and the mechanical characterizations associated with the UUT are provided. As such, it is our aim to offer a brief summary of the current knowledge of the subject, and provide a comprehensive introduction for engineers, scientists, and clinicians who are interested in the field of fluid mechanical modeling of UUT. This article is categorized under: Cancer > Biomedical Engineering Infectious Diseases > Biomedical Engineering Reproductive System Diseases > Biomedical Engineering

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“…Crystallization is a ubiquitous phenomenon in natural, biological, and synthetic processes that poses significant problems for pathological or infectious human diseases − and scale formation in industrial pipelines − and wellbores . Research efforts to curtail the deleterious effects of mineral precipitation are focused on the development of economical, facile routes to inhibit crystallization.…”

Section: Introductionmentioning

confidence: 99%

Suppressing Barium Sulfate Crystallization with Hydroxycitrate: A Dual Nucleation and Growth Inhibitor

et al. 2021

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Designing (macro)molecules that can suppress crystallization is advantageous in natural, pathological, and commercial processes where mineralization has a detrimental impact. Control over this phase transformation is often one-dimensional, meaning that modifiers either block nucleation or impede crystal growth. Inhibitors of mineralization are predominantly composed of either phosphate or carboxylate moieties. It is less common to observe a modifier with only carboxylate functionality inhibit both nucleation and growth. Here, we explore a series of homologous poly(carboxylic acid)s as crystallization inhibitors of barium sulfate (barite), a pervasive and undesirable mineral scale in many industrial processes. Through bulk crystallization, time-resolved microscopy, and scattering measurements, we show that hydroxycitrate (a naturally derived small molecule) effectively inhibits barite nucleation. Moreover, combined microfluidics and atomic force microscopy measurements reveal that hydroxycitrate fully suppresses growth via the formation of a disordered layer on barite surfaces. The rate of barite growth prior to hydroxycitrate exposure could not be recovered over 12 h after removal of the modifier, indicating that growth was sustainably (and irreversibly) altered by exposure to hydroxycitrate. Thus, hydroxycitrate is a barite crystallization modifier capable of suppressing nucleation and irreversibly inhibiting surface growth.

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Time‐Resolved Dynamics of Struvite Crystallization: Insights from the Macroscopic to Molecular Scale

Cited by 18 publications

References 70 publications

Engaging a Battle on Two Fronts: Dual Role of Polyphosphates as Potent Inhibitors of Struvite Nucleation and Crystal Growth

Engaging a Battle on Two Fronts: Dual Role of Polyphosphates as Potent Inhibitors of Struvite Nucleation and Crystal Growth

Fluid mechanical modeling of the upper urinary tract

Suppressing Barium Sulfate Crystallization with Hydroxycitrate: A Dual Nucleation and Growth Inhibitor

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