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| 2 | ((( | ||
| 3 | ==== Online documentation ==== | ||
| 4 | |||
| 5 | [[QuickNII user documentation>>https://quicknii.readthedocs.io/en/latest/index.html]] | ||
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| 7 | [[VisuAlign user documentation>>https://visualign.readthedocs.io/en/latest/index.html]] | ||
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| 9 | [[Ilastik user documentation>>https://nutil.readthedocs.io/en/latest/Ilastik.html]] | ||
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| 11 | [[Nutil user documentation>>https://nutil.readthedocs.io/en/latest/index.html]] | ||
| 12 | ))) | ||
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| 15 | [[image:QUINT_workflow_Plaques.png||height="470" style="float:left" width="1277"]] | ||
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| 17 | == == | ||
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| 19 | == == | ||
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| 25 | == == | ||
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| 27 | == == | ||
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| 29 | == (% style="color:#c0392b" %)**Description**(%%) == | ||
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| 31 | **The QUINT workflow enables an atlas-based analysis of extracted features from histological image sections from the rodent brain by using 3D reference atlases. ** | ||
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| 33 | **Examples of use are cell counting and spatial distributions, determination of projection areas in connectivity experiments, and exploration of pathological hallmarks in brain-disease models. Integration of various data to the same reference space enables new exploration strategies and reuse of experimental data.** | ||
| 34 | |||
| 35 | The workflow is built on the following open-access software. | ||
| 36 | |||
| 37 | * [[(% style="color:#2980b9" %)//ilastik//>>doc:.3\. Image segmentation with ilastik.WebHome]](%%) allows the extraction of labelled features such as cells, by using machine-learning image segmentation. | ||
| 38 | * [[(% style="color:#2980b9" %)//QuickNII//>>doc:.Image registration to reference atlas using QuickNII.WebHome]](%%) generates custom-angle slices from volumetric brain atlases to match the proportions and cutting plane of histological sections. | ||
| 39 | * //[[(% style="color:#3498db" %)VisuAlign>>doc:.Image registration to reference atlas using QuickNII.WebHome]]//(%%) is then used for non-linear alignment of the reference-atlas slice to the section image. | ||
| 40 | * (% style="color:#2980b9" %)//Nutil//(%%) enables image [[transformations>>doc:.1\. Preparing the images.WebHome]], in addition to [[quantification and spatial analysis>>doc:.4\. Quantification and spatial analysis with Nutil.WebHome]] of features by drawing on the output of //ilastik// and //QuickNII//. | ||
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| 42 | In combination, the tools facilitate semi-automated quantification, eliminating the need for more time-consuming methods such as stereological analysis with manual delineation of brain regions. | ||
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| 45 | [[[[image:Youtube_QUINT.PNG||height="310" style="float:right" width="550"]]>>https://www.youtube.com/watch?v=8oeg3qTzLnE]] | ||
| 46 | |||
| 47 | [[[[image:Quint tutorial video pic.png||height="339" style="float:left" width="550"]]>>https://www.youtube.com/watch?v=n-gQigcGMJ0]] | ||
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| 65 | |||
| 66 | QUINT workflow video | ||
| 67 | |||
| 68 | |||
| 69 | == (% style="color:#c0392b" %)**Workflow highlights**(%%) == | ||
| 70 | |||
| 71 | (% class="box successmessage" %) | ||
| 72 | ((( | ||
| 73 | The semi-automated QUINT workflow uses open-access software that can be operated without any scripting knowledge. | ||
| 74 | ))) | ||
| 75 | |||
| 76 | ((( | ||
| 77 | (% class="box successmessage" %) | ||
| 78 | ((( | ||
| 79 | Because the quantifications are performed in regions defined by a reference atlas, the region definitions are standardised, allowing comparisons of data from different laboratories. | ||
| 80 | ))) | ||
| 81 | |||
| 82 | ==== (% style="color:#c0392b" %)**References**(%%) ==== | ||
| 83 | |||
| 84 | * Yates SC et al. (2019) QUINT: Workflow for Quantification and Spatial Analysis of Features in Histological Images From Rodent Brain. Front. Neuroinform. 13:75. doi: [[10.3389/fninf.2019.00075>>https://www.frontiersin.org/articles/10.3389/fninf.2019.00075/full]] | ||
| 85 | * Groeneboom NE, Yates SC, Puchades MA and Bjaalie JG (2020) Nutil: A Pre- and Post-processing Toolbox for Histological Rodent Brain Section Images. //Front. Neuroinform.// 14:37. doi: [[10.3389/fninf.2020.00037>>https://www.frontiersin.org/articles/10.3389/fninf.2020.00037/full]] | ||
| 86 | * Berg S, Kutra D, Kroeger T, et al. & Kreshuk A (2019) ilastik: interactive machine learning for (bio)image analysis. Nat Methods. 16:1226-1232. doi: [[10.1038/s41592-019-0582-9>>https://www.nature.com/articles/s41592-019-0582-9]] | ||
| 87 | * ((( | ||
| 88 | Puchades MA et al. (2019) Spatial registration of serial microscopic brain images to three-dimensional reference atlases with the QuickNII tool. PlosOne. 14(5): e0216796. doi: [[10.1371/journal.pone.0216796>>https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0216796]] | ||
| 89 | ))) | ||
| 90 | |||
| 91 | ==== ==== | ||
| 92 | ))) |