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The tyssue
library seeks to provide a unified interface to implement
bio-mechanical models of living tissues.
It's main focus is on vertex based epithelium models.
The first model implemented is the one described in Monier et al. [monier2015apico]. It is an example of a vertex model, where the interactions are only evaluated on the apical surface sheet of the epithelium. The second class of models is still at an stage. They implement a description of the tissue's rheology, within a dissipation function formalism.
Each biological question, be it in morphogenesis or cancer studies is unique, and requires tweeking of the models developed by the physicists. Most of the modelling softwares follow an architecture based on a core C++ engine with a combinaison of markup or scripting capacities to run specific simulation.
In tyssue
, we rather try to expose an API that simplifies the
building of tissue models and running simulations, while keeping the
possibilities as open as possible.
Separate structure, geometry and models
We seek to have a design as modular as possible, to allow the same epithlium mesh to be fed to different physical models.
Accessible, easy to use data structures
The core of the tyssue library rests on two structures: a set of
pandas DataFrame
holding the tissue geometry and associated data,
and nested dictionnaries holding the model parameters, variables and
default values.
The API thus defines an Epithelium
class. An instance of this class
is a container for the datasets and the specifications, and implements
methods to manipulate indexing of the dataframes to ease calculations.
The mesh structure is heavily inspired by CGAL Linear Cell Complexes, most importantly, in the case of a 2D vertex sheet for example, each junction edge between the cells is "splitted" between two oriented half edges.
## Core object
from tyssue import Sheet
## Simple 2D geometry
from tyssue import PlanarGeometry
## Visualisation (matplotlib based)
from tyssue.draw import sheet_view
sheet = Sheet.planar_sheet_2d('basic2D', nx=6, ny=7,
distx=1, disty=1)
PlanarGeometry.update_all(sheet)
sheet.sanitize()
fig, ax = sheet_view(sheet)
- Easy data manipulation.
- Multiple geometries (Sheets in 2D and 3D, monolayers, bulk).
- Easy to extend.
- 2D (matplotlib) and 3D (ipyvolume) customisable visualisation.
- Easy quasistatic model definition.
- Self collision detection. new in 0.3
- The documentation is now browsable on tyssue.io
- The old documentation is still browsable online here
- Introduction notebooks are available here.
tyssue@framaliste.org - https://framalistes.org/sympa/info/tyssue
Subscribe ➙ https://framalistes.org/sympa/subscribe/tyssue Unsubscribe ➙ https://framalistes.org/sympa/sigrequest/tyssue
- Bertrand Caré - @bcare
- Cyprien Gay - @cypriengay
- Guillaume Gay (maintainer) - @glyg
- Hadrien Mary - @hadim
- François Molino
- Magali Suzanne
- Sophie Theis - @sophietheis
As all the dependencies are already completely supported in python 3.x, we won't be maintaining a python 2.x version, because it's time to move on...
- CGAL > 4.7
- Python >= 3.6
- numpy
- scipy
- matplotlib
- pandas
- pytables
- jupyter
- notebook
- quantities
- ipywidgets
- pythreejs
- ipyvolume
- vispy
- pytest
- coverage
- pytest-cov
You can install the library with the conda package manager
conda install -c conda-forge tyssue
You can also install tyssue from PyPi, this is a CGAL-less version (pure python), lacking some features:
python -m pip install --user --upgrade tyssue
See INSTALL.md for a step by step install, including the necessary python environment.
Since version 0.3, this project is distributed under the terms of the General Public Licence.
Versions 2.4 and earlier were distributed under the Mozilla Public Licence.
If GPL licencing is too restrictive for your intended usage, please contact the maintainer.
- There is a Bibtex file here with collected relevant publications.
The tyssue library stemed from a refactoring of the leg-joint
code used in [monier2015apico].
[monier2015apico]: Monier, B. et al. Apico-basal forces exerted by apoptotic cells drive epithelium folding. Nature 518, 245–248 (2015).
[Tamulonis2013]: Tamulonis, C. Cell-based models. (Universiteit ven Amsterdam, 2013). doi:10.1177/1745691612459060.
[Tlili2013]: Tlili,S. et al. Mechanical formalism for tissue dynamics. 6, 23 (2013).