Dina Sinclair scite author profile

We created a set of resources to enable research based on openly-available diffusion MRI (dMRI) data from the Healthy Brain Network (HBN) study. First, we curated the HBN dMRI data (N = 2747) into the Brain Imaging Data Structure and preprocessed it according to best-practices, including denoising and correcting for motion effects, susceptibility-related distortions, and eddy currents. Preprocessed, analysis-ready data was made openly available. Data quality plays a key role in the analysis of dMRI. To optimize QC and scale it to this large dataset, we trained a neural network through the combination of a small data subset scored by experts and a larger set scored by community scientists. The network performs QC highly concordant with that of experts on a held out set (ROC-AUC = 0.947). A further analysis of the neural network demonstrates that it relies on image features with relevance to QC. Altogether, this work both delivers resources to advance transdiagnostic research in brain connectivity and pediatric mental health, and establishes a novel paradigm for automated QC of large datasets.

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Simulating surfactant spreading: Influence of a physically motivated equation of state

Sinclair¹,

Levy²,

Daniels³

2017

Eur. J. Appl. Math

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In this paper, we present numerical simulations that demonstrate the effect of the particular choice of the equation of state (EoS) relating the surfactant concentration to the surface tension in surfactant-driven thin liquid films. Previous choices of the model EoS have been an ad-hoc decreasing function. Here, we instead propose an empirically motivated EoS; this provides a route to resolve some discrepancies and raises new issues to be pursued in future experiments. In addition, we test the influence of the choice of initial conditions and values for the non-dimensional groups. We demonstrate that the choice of EoS improves the agreement in surfactant distribution morphology between simulations and experiments, and influences the dynamics of the simulations. Because an empirically motivated EoS has regions with distinct gradients, future mathematical models may be improved by considering more than one timescale. We observe that the non-dimensional number controlling the relative importance of gravitational versus capillary forces has a larger influence on the dynamics than the other non-dimensional groups, but is nonetheless not a likely cause of discrepancy between simulations and experiments. Finally, we observe that the experimental approach using a ring to contain the surfactant could affect the surfactant and fluid dynamics if it disrupts the intended initial surfactant distribution. However, the fluid meniscus itself does not significantly affect the dynamics.

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Simulating Surfactant Spreading: Impact of a Physically Motivated Equation of State

Sinclair¹,

Lévy²,

Daniels³

2016

Preprint

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Publisher Correction: An analysis-ready and quality controlled resource for pediatric brain white-matter research

Richie-Halford

Cieslak²,

Ai³

et al. 2022

Sci Data

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Author Correction: An analysis-ready and quality controlled resource for pediatric brain white-matter research

Richie-Halford¹,

Cieslak²,

Ai³

et al. 2023

Sci Data

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Dina Sinclair

An analysis-ready and quality controlled resource for pediatric brain white-matter research

Simulating surfactant spreading: Influence of a physically motivated equation of state

Simulating Surfactant Spreading: Impact of a Physically Motivated Equation of State

Publisher Correction: An analysis-ready and quality controlled resource for pediatric brain white-matter research

Author Correction: An analysis-ready and quality controlled resource for pediatric brain white-matter research

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