Bioimage informatics: a new area of engineering biology

Peng, Hanchuan

doi:10.1093/bioinformatics/btn346

Cited by 308 publications

(217 citation statements)

References 111 publications

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“…For example, by means of confocal microscopy, [ 1 , 2 ] stimulated emission depletion microscopy, [ 3 , 4 ] stochastic optical reconstruction microscopy [ 5 , 6 ] and others, [ 7 ] these techniques enable to retrieve three-dimensional images and even to reconstruct sub-wavelength resolutions beyond the diffraction limit. Among these cutting-edge optical microscopic techniques aforementioned, a critical step requires fl uorescent labeling, which is often detrimental to live cells and more critically, could affect the physiology of the cells by means of mechanotransduction.…”

Section: Doi: 101002/adma201200291mentioning

confidence: 99%

Label‐Free, Coupler‐Free, Scalable and Intracellular Bio‐imaging by Multimode Plasmonic Resonances in Split‐Ring Resonators

et al. 2012

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Section: Doi: 101002/adma201200291mentioning

confidence: 99%

Label‐Free, Coupler‐Free, Scalable and Intracellular Bio‐imaging by Multimode Plasmonic Resonances in Split‐Ring Resonators

et al. 2012

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“…Hence, the current trend toward automatic, highcontent, high-throughput screening brings new bottlenecks in the domain of image analysis (Baker, 2010;Truong and Supatto, 2011): The unprecedented rise in complexity and size of data have favored the blossoming of a new discipline, bioimage informatics (Peng, 2008), or the science of organizing distributed and heterogeneous biological image data into typed data and categorized quantitative information.…”

Section: Introductionmentioning

confidence: 99%

Assembling models of embryo development: Image analysis and the construction of digital atlases

Castro-González

Ledesma-Carbayo

Peyriéras

et al. 2012

Birth Defects Research Pt C

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Digital atlases of animal development provide a quantitative description of morphogenesis, opening the path toward processes modeling. Prototype atlases offer a data integration framework where to gather information from cohorts of individuals with phenotypic variability. Relevant information for further theoretical reconstruction includes measurements in time and space for cell behaviors and gene expression. The latter as well as data integration in a prototypic model, rely on image processing strategies. Developing the tools to integrate and analyze biological multidimensional data are highly relevant for assessing chemical toxicity or performing drugs preclinical testing. This article surveys some of the most prominent efforts to assemble these prototypes, categorizes them according to salient criteria and discusses the key questions in the field and the future challenges toward the reconstruction of multiscale dynamics in model organisms.

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“…[5]. Automated alignment (registration) of 3D images of fruit fly brains is a critical technique for high-throughput analysis of neuronal patterns [6]. However, as shown in Figure 1, the two optic lobes (OLs) are loosely connected with the center region of a fly brain via the neuronal bundles.…”

Section: Introductionmentioning

confidence: 99%

Segmentation of center brains and optic lobes in 3D confocal images of adult fruit fly brains

Lam

Ruan

Zhao

et al. 2010

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Automatic alignment (registration) of 3D images of adult fruit fly brains is often influenced by the significant displacement of the relative locations of the two optic lobes (OLs) and the center brain (CB). In one of our ongoing efforts to produce a better image alignment pipeline of adult fruit fly brains, we consider separating CB and OLs and align them independently. This paper reports our automatic method to segregate CB and OLs, in particular under conditions where the signal to noise ratio (SNR) is low, the variation of the image intensity is big, and the relative displacement of OLs and CB is substantial.We design an algorithm to find a minimum-cost 3D surface in a 3D image stack to best separate an OL (of one side, either left or right) from CB. This surface is defined as an aggregation of the respective minimum-cost curves detected in each individual 2D image slice. Each curve is defined by a list of control points that best segregate OL and CB. To obtain the locations of these control points, we derive an energy function that includes an image energy term defined by local pixel intensities and two internal energy terms that constrain the curve's smoothness and length. Gradient descent method is used to optimize this energy function. To improve both the speed and robustness of the method, for each stack, the locations of optimized control points in a slice are taken as the initialization prior for the next slice. We have tested this approach on simulated and real 3D fly brain image stacks and demonstrated that this method can reasonably segregate OLs from CBs despite the aforementioned difficulties.

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Bioimage informatics: a new area of engineering biology

Cited by 308 publications

References 111 publications

Label‐Free, Coupler‐Free, Scalable and Intracellular Bio‐imaging by Multimode Plasmonic Resonances in Split‐Ring Resonators

Label‐Free, Coupler‐Free, Scalable and Intracellular Bio‐imaging by Multimode Plasmonic Resonances in Split‐Ring Resonators

Assembling models of embryo development: Image analysis and the construction of digital atlases

Segmentation of center brains and optic lobes in 3D confocal images of adult fruit fly brains

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