Abstract
Microscopic images of neuronal cells provide essential structural information about the key constituents of the brain and form the basis of many neuroscientific studies. Computational analyses of the morphological properties of the captured neurons require first converting the structural information into digital tree-like reconstructions. Many dedicated computational methods and corresponding software tools have been and are continuously being developed with the aim to automate this step while achieving human-comparable reconstruction accuracy. This pursuit is hampered by the immense diversity and intricacy of neuronal morphologies as well as the often low quality and ambiguity of the images. Here we present a novel method we developed in an effort to improve the robustness of digital reconstruction against these complicating factors. The method is based on probabilistic filtering by sequential Monte Carlo estimation and uses prediction and update models designed specifically for tracing neuronal branches in microscopic image stacks. Moreover, it uses multiple probabilistic traces to arrive at a more robust, ensemble reconstruction. The proposed method was evaluated on fluorescence microscopy image stacks of single neurons and dense neuronal networks with expert manual annotations serving as the gold standard, as well as on synthetic images with known ground truth. The results indicate that our method performs well under varying experimental conditions and compares favorably to state-of-the-art alternative methods.
Highlights
The brain is regarded as one of the most complex and enigmatic biological structures
The performance of our Probabilistic Neuron Reconstructor (PNR) method was evaluated using both synthetic and real fluorescence microscopy image stacks of single neurons and was compared to several alternative 3D neuron reconstruction methods that yielded favorable performance in the BigNeuron project (Peng et al 2015a). These included the second all-path pruning method (APP2) (Xiao and Peng 2013), NeuroGPS-Tree (GPS) (Quan et al 2016), BigNeuron’s minimum spanning tree (MST) method, and we added our recently published alternative probabilistic method based on probability hypothesis density filtering (PHD) (Radojevicand Meijering 2017a)
We have presented a new fully automated probabilistic neuron reconstruction method (PNR) based on sequential
Summary
The brain is regarded as one of the most complex and enigmatic biological structures. Composed of an intricate network of tree-shaped neuronal cells (Ascoli 2015), together forming a powerful information processing unit, it performs a myriad of functions that are essential to living organisms. A key instrument in this endeavor is microscopic imaging, as it allows detailed visualization of neuronal cells in isolation and in tissue, providing the means to study their structural properties quantitatively (Senft 2011). Quantitative measurement and statistical analysis of neuronal cell and network properties from microscopic data rely on the ability to obtain accurate digital reconstructions of the branching structures (Halavi et al 2012) in the form of a directional tree of connected nodes (Ascoli et al 2007).
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