About
Source code for:
McDougal, R. A., Conte, C., Eggleston, L., Newton, A. J. H., & Galijasevic, H. (2022). Efficient simulation of 3D reaction-diffusion in models of neurons and networks. bioRxiv. doi:10.1101/2022.01.01.474683
Description of files
- 070314F_11.ASC
- CA1 pyramidal cell morphology from Malik et al., 2016 via NeuroMorpho.Org (Ascoli et al., 2007)
- conservation_of_mass.py
- Tests fixed and variable step conservation of mass in a pure diffusion problem on a Y-shape geometry.
- do_timings.py
- Short control script for time_discretization.py that loops over choices of dx and cell morphologies. This generates data and stores it in a sqlite3 database; use get_timings.py to generate the plots.
- Figure1A_3Dwave_time_contour.py
- Propagating wave test near the soma on a realistic morphology (070314F_11.ASC), generates contour maps showing wave front at different time points.
- Figure1A_3Dwave_time_contour70.py
- Like Figure1A_3Dwave_time_contour.py but doesn't generate the contour maps and is instead focused on detecting soma crossing times.
- Figure1A_3Dwave_time_contour100.py
- Like Figure1A_3Dwave_time_contour70.py but does more of the problem in 3D (includes sections whose center lies within 100 µm path distance of the center of the soma instead of just 70 µm).
- Figure1A_hybrid.py
- Like Figure1A_3Dwave_time_contour.py but doesn't generate the contour maps and is instead focused on detecting soma crossing times.
- get_timings.py
- Generates plots from data produced by do_timings.py
- morph_volume_analysis_truebound.py
- Tool for comparing volume of bounding box to volume of cell
- plot_simple_geometry_convergence.py
- Plots data generated by simple_geometry_convergence.py
- plot_thread_scaling.py
- Plots data generated by thread_scaling.py
- plot_wave_time_3d.py
- Plots data generated by wave_time_3d.py
- readme.html
- This file, which provides an overview of all the files in this archive.
- segment-alignment.py
- Visually tests relationship between segment boundaries and 3D voxel segment assignment.
- simple_geometry_convergence.py
- Measures surface area, volume, relative errors, and runtimes for various cylinders with different discretization options. Visualize results by running plot_simple_geometry_convergence.py
- thread_scaling.py
- Measures run-time as the number of threads are varied for different choices of morphology, kinetics, and dx.
- time_discretization.py
- Times the discretization for a specified morphology and dx; also stores the computed volume, surface area, number of voxels, number of surface voxels, total section lengths, and number of sections. Invoked by time_discretization.py
- volume_functions_truebound.py
- ???
- wave_time_3d.py
- ???
All morphologies in the swc folder are via NeuroMorpho.Org:
\texttt{9CL-IVxAnk2-IR\_ddaC} \citep{nanda2018morphological},
\texttt{29-1-8} \citep{martinez2013chronic},
\texttt{64-8-L-B-JB} \citep{ehlinger2017nicotine},
\texttt{243-3-39-AW} \citep{nguyen2020comparative},
\texttt{2017-25-04-slice-2-cell-2-rotated} \citep{scala2019layer},
\texttt{070601-exp1-zB} \citep{groh2010cell},
\texttt{160524\_7\_4} \citep{kunst2019cellular},
\texttt{15892037} \citep{takagi2017divergent},
\texttt{AE5\_EEA\_Outer-thirds\_DG-Mol\_sec1-cel4-aev5me} \citep{de2020long},
\texttt{AM61-2-1} and \texttt{AM81-2-3} \citep{trevelyan2006modular},
\texttt{B4-CA1-L-D63x1zACR3\_1} \citep{canchi2017simulated},
\texttt{Dnmt3bKO-cell-8 and WT-iPS-derived-cell-12MR} \citep{tarusawa2016establishment},
\texttt{Fig5C} \citep{herget2017single},
\texttt{glia\_4090} \citep{helmstaedter2013connectomic},
\texttt{KC-s-4505762} \citep{takemura2017connectome},
\texttt{Mouse\_CA2\_Ma\_Cell\_5} \citep{helton2019diversity},
\texttt{RatS1-6-107} \citep{nogueira2012distribution},
\texttt{RP4\_scaled} \citep{weiss2020multi}, and
\texttt{WT-mPFC-A-20X-3-2} \citep{juan2014phenotypic
References
Ascoli, G. A., Donohue, D. E., & Halavi, M. (2007). NeuroMorpho. Org: a central resource for neuronal morphologies. Journal of Neuroscience, 27(35), 9247-9251.
Malik, R., Dougherty, K. A., Parikh, K., Byrne, C., & Johnston, D. (2016). Mapping the electrophysiological and morphological properties of CA 1 pyramidal neurons along the longitudinal hippocampal axis. Hippocampus, 26(3), 341-361.