Ran Zhao scite author profile

Detection of amyloid growth is commonly carried out by measurement of solution turbidity, a low-cost assay procedure based on the intrinsic light scattering properties of the protein aggregate. Here, we review the biophysical chemistry associated with the turbidimetric assay methodology, exploring the reviewed literature using a series of pedagogical kinetic simulations. In turn, these simulations are used to interrogate the literature concerned with in vitro drug screening and the assessment of amyloid aggregation mechanisms.

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Protein aggregate turbidity: Simulation of turbidity profiles for mixed-aggregation reactions

Hall

Zhao

Dehlsen

et al. 2016

Analytical Biochemistry

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Superior Biomimetic Nacreous Bulk Nanocomposites by a Multiscale Soft-Rigid Dual-Network Interfacial Design Strategy

Chen

Gao

Sun

et al. 2019

Matter

100

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Bioinspired hierarchical helical nanocomposite macrofibers based on bacterial cellulose nanofibers

Gao¹,

Zhao²,

Cui³

et al. 2019

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Bio-sourced nanocellulosic materials are promising candidates for spinning high-performance sustainable macrofibers for advanced applications. Various strategies have been pursued to gain nanocellulose-based macrofibers with improved strength. However, nearly all of them have been achieved at the expense of their elongation and toughness. Inspired by the widely existed hierarchical helical and nanocomposite structural features in biosynthesized fibers exhibiting exceptional combinations of strength and toughness, we report a design strategy to make nanocellulose-based macrofibers with similar characteristics. By combining a facile wet-spinning process with a subsequent multiple wet-twisting procedure, we successfully obtain biomimetic hierarchical helical nanocomposite macrofibers based on bacterial cellulose nanofibers, realizing impressive improvement in their tensile strength, elongation and toughness simultaneously. The achievement certifies the validity of the bioinspired hierarchical helical and nanocomposite structural design proposed here. This bioinspired design strategy provides a potential platform for further optimizing or creating many more strong and tough nanocomposite fiber materials for diverse applications.

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Recognizing and analyzing variability in amyloid formation kinetics: Simulation and statistical methods

Hall

Zhao

et al. 2016

Analytical Biochemistry

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Ran Zhao

Measurement of amyloid formation by turbidity assay—seeing through the cloud

Protein aggregate turbidity: Simulation of turbidity profiles for mixed-aggregation reactions

Superior Biomimetic Nacreous Bulk Nanocomposites by a Multiscale Soft-Rigid Dual-Network Interfacial Design Strategy

Bioinspired hierarchical helical nanocomposite macrofibers based on bacterial cellulose nanofibers

Recognizing and analyzing variability in amyloid formation kinetics: Simulation and statistical methods

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