Review on data analysis methods for mesoscale neural imaging in vivo

Cai, Yeyi; Wu, Jiamin; Dai, Qionghai

doi:10.1117/1.nph.9.4.041407

Cited by 7 publications

(4 citation statements)

References 126 publications

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“…As deep learning-based image denoising continues to evolve, it remains essential for enhancing feature detection in neural imaging, crucial for analyzing neural connectivity and function. However, the application of these tools involves careful consideration of balance between reducing noise and preserving crucial image details [ 68 ]. Over-denoising may results in the loss of important details, while under-denoising may leave excessive noise, potentially leading to data misinterpretation, which makes diligent judgement from the users to maintain balance.…”

Section: Mapping Brain Connectivity Through Feature Extractionmentioning

confidence: 99%

Connecto-informatics at the mesoscale: current advances in image processing and analysis for mapping the brain connectivity

Choi,

Feng,

Jeong

et al. 2024

Brain Inf.

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Mapping neural connections within the brain has been a fundamental goal in neuroscience to understand better its functions and changes that follow aging and diseases. Developments in imaging technology, such as microscopy and labeling tools, have allowed researchers to visualize this connectivity through high-resolution brain-wide imaging. With this, image processing and analysis have become more crucial. However, despite the wealth of neural images generated, access to an integrated image processing and analysis pipeline to process these data is challenging due to scattered information on available tools and methods. To map the neural connections, registration to atlases and feature extraction through segmentation and signal detection are necessary. In this review, our goal is to provide an updated overview of recent advances in these image-processing methods, with a particular focus on fluorescent images of the mouse brain. Our goal is to outline a pathway toward an integrated image-processing pipeline tailored for connecto-informatics. An integrated workflow of these image processing will facilitate researchers’ approach to mapping brain connectivity to better understand complex brain networks and their underlying brain functions. By highlighting the image-processing tools available for fluroscent imaging of the mouse brain, this review will contribute to a deeper grasp of connecto-informatics, paving the way for better comprehension of brain connectivity and its implications.

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Section: Mapping Brain Connectivity Through Feature Extractionmentioning

confidence: 99%

Connecto-informatics at the mesoscale: current advances in image processing and analysis for mapping the brain connectivity

Choi,

Feng,

Jeong

et al. 2024

Brain Inf.

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“…Minimally invasive imaging is important to optogenetics 1 – 3 and cancer diagnostics 4 – 6 since it minimizes the damage to living tissues. Conventional brain cancer diagnosis requires surgical biopsy and resection, histological staining, and observation.…”

Section: Introductionmentioning

confidence: 99%

Resolution-enhanced multi-core fiber imaging learned on a digital twin for cancer diagnosis

Wang,

Dremel,

Richter

et al. 2024

Neurophoton.

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. Significance Deep learning enables label-free all-optical biopsies and automated tissue classification. Endoscopic systems provide intraoperative diagnostics to deep tissue and speed up treatment without harmful tissue removal. However, conventional multi-core fiber (MCF) endoscopes suffer from low resolution and artifacts, which hinder tumor diagnostics. Aim We introduce a method to enable unpixelated, high-resolution tumor imaging through a given MCF with a diameter of around 0.65 mm and arbitrary core arrangement and inhomogeneous transmissivity. Approach Image reconstruction is based on deep learning and the digital twin concept of the single-reference-based simulation with inhomogeneous optical properties of MCF and transfer learning on a small experimental dataset of biological tissue. The reference provided physical information about the MCF during the training processes. Results For the simulated data, hallucination caused by the MCF inhomogeneity was eliminated, and the averaged peak signal-to-noise ratio and structural similarity were increased from 11.2 dB and 0.20 to 23.4 dB and 0.74, respectively. By transfer learning, the metrics of independent test images experimentally acquired on glioblastoma tissue ex vivo can reach up to 31.6 dB and 0.97 with 14 fps computing speed. Conclusions With the proposed approach, a single reference image was required in the pre-training stage and laborious acquisition of training data was bypassed. Validation on glioblastoma cryosections with transfer learning on only 50 image pairs showed the capability for high-resolution deep tissue retrieval and high clinical feasibility.

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“…Benisty et al 1 provide a comprehensive review on data processing of functional optical microscopy for neuroscience, which surveys a broad range of techniques to handle massive spatiotemporal datasets from fluorescent microscopes in order to uncover neuronal activity related to behavior and stimuli, and local circuits in the brain. Cai et al 2 provide a focused review on data analysis methods for mesoscale neural imaging in vivo, which is timely since mesoscale imaging at high resolution has become one of the main frontier in neuroimaging. Carrillo-Reid and Calderon 3 present a review on conceptual framework for neuronal ensemble identification and manipulation related to behavior using calcium imaging, which discusses computational approaches to infer neuronal ensembles from calcium imaging in behaving mice.…”

mentioning

confidence: 99%

“…provide a comprehensive review on data processing of functional optical microscopy for neuroscience, which surveys a broad range of techniques to handle massive spatiotemporal datasets from fluorescent microscopes in order to uncover neuronal activity related to behavior and stimuli, and local circuits in the brain. Cai et al 2 . provide a focused review on data analysis methods for mesoscale neural imaging in vivo , which is timely since mesoscale imaging at high resolution has become one of the main frontier in neuroimaging.…”

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confidence: 99%

Special Section Guest Editorial: Computational Approaches for Neuroimaging

2022

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New advances in computational methods are revolutionizing our ability to collect, reconstruct, analyze, and interpret neuroimaging data. In turn, they provide unique new approaches to understand brain activities and functions at subcellular, cellular, circuit and network levels. This special section collates ten contributions that cover many recent computational technologies underlying these developments. These computational techniques address several challenges, including recording of neural activities, reconstruction of neural activities, inference of functional connectivity, and interpretation of the brain function at cellular level and circuit level. This special section of Neurophotonics Volume 9 Issue 4 consists of five review articles and five research papers. These contributions are representative of the broad range of optical technologies employed in neuroscience, such as one-photon or multi-photon imaging of functional indicators, e.g., calcium, voltage, and neurotransmitter, functional near-infrared spectroscopies to image hemodynamics, and optical intrinsic signal imaging. Beyond imaging, this special section also covers the rising field of photostimulation.A major focus of emerging computational approaches is towards fast and accurate data processing for functional neuroimaging data. Benisty et al. 1 provide a comprehensive review on data processing of functional optical microscopy for neuroscience, which surveys a broad range of techniques to handle massive spatiotemporal datasets from fluorescent microscopes in order to uncover neuronal activity related to behavior and stimuli, and local circuits in the brain. Cai et al. 2 provide a focused review on data analysis methods for mesoscale neural imaging in vivo, which is timely since mesoscale imaging at high resolution has become one of the main frontier in neuroimaging. Carrillo-Reid and Calderon 3 present a review on conceptual framework for neuronal ensemble identification and manipulation related to behavior using calcium imaging, which discusses computational approaches to infer neuronal ensembles from calcium imaging in behaving mice. Eastmond et al. 4 offer a comprehensive review on deep learning in functional near-infrared spectroscopy (fNIRS), which covers the many applications of deep learning in fNIRS for brain-computer interface, neuro-impairment diagnosis, and neuroscience discovery. Gao et al. 5 report a novel denoising autoencoder deep learning model to remove motion artifacts that plague fNIRS data in real world applications. White et al. 6 compare data processing methods for optical intrinsic signal imaging to analyze resting-state functional connectivity in mice by processing temporal and spatial autocorrelations. Dehkharghanian et al. 7 present a new semi-automated machine learning algorithm for analyzing bioluminescence images in order to measure adenosine triphosphate (ATP) indicators in neurons.Another emerging area is computational imaging, which seeks to synergistically combine novel optical designs and advanced computational ...

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Review on data analysis methods for mesoscale neural imaging in vivo

Cited by 7 publications

References 126 publications

Connecto-informatics at the mesoscale: current advances in image processing and analysis for mapping the brain connectivity

Connecto-informatics at the mesoscale: current advances in image processing and analysis for mapping the brain connectivity

Resolution-enhanced multi-core fiber imaging learned on a digital twin for cancer diagnosis

Special Section Guest Editorial: Computational Approaches for Neuroimaging

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