Automating cell detection and classification in human brain fluorescent microscopy images using dictionary learning and sparse coding

Alegro, Maryana; Theofilas, Panagiotis; Nguy, Austin; Castruita, Patricia A.; Seeley, William W.; Heinsen, Helmut; Ushizima, Daniela; Grinberg, Lea T.

doi:10.1016/j.jneumeth.2017.03.002

Cited by 25 publications

(16 citation statements)

References 60 publications

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“…MBP and SLC17A7) to assign the most likely cell type for each ROI. As molecular profiles of cell types become more complex, machine learning approaches such as CART may become increasingly necessary to interpret overlapping patterns of gene expression 55 .…”

Section: Dotdotdot Complements Growing Computational Approaches For Smentioning

confidence: 99%

dotdotdot: an automated approach to quantify multiplex single molecule fluorescent in situ hybridization (smFISH) images in complex tissues

Maynard

Tippani

Takahashi

et al. 2019

Preprint

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ABSTRACTMultiplex single-molecule fluorescent in situ hybridization (smFISH) is a powerful method for validating RNA sequencing and emerging spatial transcriptomic data, but quantification remains a computational challenge. We present a framework for generating and analyzing smFISH data in complex tissues while overcoming autofluorescence and increasing multiplexing capacity. We developed dotdotdot (https://github.com/LieberInstitute/dotdotdot) as a corresponding software package to quantify RNA transcripts in single nuclei and perform differential expression analysis. We first demonstrate robustness of our platform in single mouse neurons by quantifying differential expression of activity-regulated genes. We then quantify spatial gene expression in human dorsolateral prefrontal cortex (DLPFC) using spectral imaging and dotdotdot to mask lipofuscin autofluorescence. We lastly apply machine learning to predict cell types and perform downstream cell type-specific expression analysis. In summary, we provide experimental workflows, imaging acquisition and analytic strategies for quantification and biological interpretation of smFISH data in complex tissues.

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Section: Dotdotdot Complements Growing Computational Approaches For Smentioning

confidence: 99%

dotdotdot: an automated approach to quantify multiplex single molecule fluorescent in situ hybridization (smFISH) images in complex tissues

Maynard

Tippani

Takahashi

et al. 2019

Preprint

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“…When these properties are not enough to capture different phases of the object, considerable effort is required to design other priors. Examples include adding spatial dependency of the labeling using the distance transform , star‐convexity of the shape given the initial position of a labeling , texture features , and in other cases a combination of spatial cues, color, and dictionary learning .…”

Section: Background and Related Workmentioning

confidence: 99%

Interactive volumetric segmentation for textile micro‐tomography data using wavelets and nonlocal means

MacNeil

Ushizima

Panerai

et al. 2019

Statistical Analysis

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This work addresses segmentation of volumetric images of woven carbon fiber textiles from micro‐tomography data. We propose a semi‐supervised algorithm to classify carbon fibers that requires sparse input as opposed to completely labeled images. The main contributions are: (a) design of effective discriminative classifiers, for three‐dimensional textile samples, trained on wavelet features for segmentation; (b) coupling of previous step with nonlocal means as simple, efficient alternative to the Potts model; and (c) demonstration of reuse of classifier to diverse samples containing similar content. We evaluate our work by curating test sets of voxels in the absence of a complete ground truth mask. The algorithm obtains an average 0.95 F1 score on test sets and average F1 score of 0.93 on new samples. We conclude with discussion of failure cases and propose future directions toward analysis of spatiotemporal high‐resolution micro‐tomography images.

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“…The automated identification and segmentation of axons from 3D images should circumvent these limitations. Recent application of deep convolutional neural networks (DCNNs) and Markov random fields to biomedical imaging have made excellent progress at segmenting grayscale CT and MRI volumes for medical applications (Alegro et al, 2017;Dong et al, 2018;Frasconi et al, 2014;Mathew et al, 2015;Thierbach et al, 2018). Other fluorescent imaging strategies including light-sheet, fMOST, and serial two-photon tomography have been combined with software like TeraVR, Vaa3D, Ilastik, and NeuroGPS-Tree to trace or otherwise reconstruct individual neurons (Peng et al, 2010;Quan et al, 2016;Wang et al, 2019;Winnubst et al, 2019;Zhou et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Mapping Mesoscale Axonal Projections in the Mouse Brain Using A 3D Convolutional Network

Friedmann

Pun

Adams

et al. 2019

Preprint

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AbstractThe projection targets of a neuronal population are a key feature of its anatomical characterization. Historically, tissue sectioning, confocal microscopy, and manual scoring of specific regions of interest have been used to generate coarse summaries of mesoscale projectomes. We present here TrailMap, a 3D convolutional network for extracting axonal projections from intact cleared mouse brains imaged by light-sheet microscopy. TrailMap allows region-based quantification of total axon content in large and complex 3D structures after registration to a standard reference atlas. The identification of axonal structures as thin as one voxel benefits from data augmentation but also requires a loss function that tolerates errors in annotation. A network trained with volumes of serotonergic axons in all major brain regions can be generalized to map and quantify axons from thalamocortical, deep cerebellar, and cortical projection neurons, validating transfer learning as a tool to adapt the model to novel categories of axonal morphology. Speed of training, ease of use, and accuracy improve over existing tools without a need for specialized computing hardware. Given the recent emphasis on genetically and functionally defining cell types in neural circuit analysis, TrailMap will facilitate automated extraction and quantification of axons from these specific cell types at the scale of the entire mouse brain, an essential component of deciphering their connectivity.

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Automating cell detection and classification in human brain fluorescent microscopy images using dictionary learning and sparse coding

Cited by 25 publications

References 60 publications

dotdotdot: an automated approach to quantify multiplex single molecule fluorescent in situ hybridization (smFISH) images in complex tissues

dotdotdot: an automated approach to quantify multiplex single molecule fluorescent in situ hybridization (smFISH) images in complex tissues

Interactive volumetric segmentation for textile micro‐tomography data using wavelets and nonlocal means

Mapping Mesoscale Axonal Projections in the Mouse Brain Using A 3D Convolutional Network

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