Versions: 1.14.0 -
Release dates: 15 September 2024 -
- 1.14.0 : 15 September 2024
PhysiCell is a flexible open source framework for building agent-based multicellular models in 3-D tissue environments.
Reference: A Ghaffarizadeh, R Heiland, SH Friedman, SM Mumenthaler, and P Macklin, PhysiCell: an Open Source Physics-Based Cell Simulator for Multicellular Systems, PLoS Comput. Biol. 14(2): e1005991, 2018. DOI: 10.1371/journal.pcbi.1005991
Visit http://MathCancer.org/blog for the latest tutorials and help.
Notable recognition:
make
: compiles the current project. If no
project has been defined, it first
populates the cancer heterogeneity 2D
sample project and compiles it
make project-name
: populates the indicated sample project.
Use "make" to compile it.
project-name
choices:- template
- biorobots-sample
- cancer-biorobots-sample
- cancer-immune-sample
- celltypes3-sample
- heterogeneity-sample
- pred-prey-farmer
- virus-macrophage-sample
- worm-sample
- ode-energy-sample
- physiboss-cell-lines-sample
- cancer-metabolism-sample
- interaction-sample
- mechano-sample
- rules-sample
- physimess-sample
- custom-division-sample
make list-projects
: list all available sample projects
make clean
: removes all .o files and the executable, so that the next "make" recompiles the entire project
make data-cleanup
: clears out all simulation data
make reset
: de-populates the sample project and returns to the original PhysiCell state. Use this when switching to a new PhysiCell sample project.
make save PROJ=name
: save the current project (including the Makefile
, main.cpp
, and everything in ./config
and ./custom_modules/
) in ./user_projects/name
, where name
is your choice for the project. If the project already exists, overwrite it.
make load PROJ=name
: load the user project name
from ./user_projects/name
(including the Makefile
, main.cpp
, and everything in ./config
and ./custom_modules/
).
make list-user-projects
: list all user projects in ./user_projects/
. (Use these names without the trailing /
in make load PROJ=name
.)
make jpeg
: uses ImageMagick to convert the SVG files in the output directory to JPG (with appropriate sizing to make movies). Supply OUTPUT=foldername
to select a different folder.
make movie
: uses ffmpeg to convert the JPG files in the output directory an mp4 movie. Supply OUTPUT=foldername
to select a different folder, or FRAMERATE=framerate
to override the frame rate.
make upgrade
: fetch the latest release of PhysiCell and overwrite the core library and sample projects.
Homepage: http://PhysiCell.org
Setup Guide: https://github.com/physicell-training/ws2023/blob/main/agenda.md#set-up-physicell
Downloads: https://PhysiCell.sf.net AND https://github.com/MathCancer/PhysiCell/releases
Support: https://join.slack.com/t/physicellcomm-sf93727/shared_invite/zt-qj1av6yd-yVeer8VkQaNDjDz7fF00jA
User Guide: Look at UserGuide.pdf in the documentation folder.
Setup and Training: See this year's workshop and hackathon at https://github.com/PhysiCell-Training/ws2023
Older Tutorials: http://www.mathcancer.org/blog/physicell-tutorials/
Latest info: follow @PhysiCell on Twitter (http://twitter.com/PhysiCell)
See changes.md for the full change log.
Version 1.14 upgrades the Cell Beheavior Hypothesis Grammar (to version 3), including refinements to cell phagocytosis, effector attack, and cell damage/integrity in response to community discussions and peer review. It also introduces numerous refinements to cell division, random seeds, and randomized parameter initialization, as well as upgrades to PhysiBoSS and PhysiMeSS and bug fixes. Other refinements are "under the hood," including new GitHub actions and improved automation of testing, as well as improvements to MultiCellDS output.
Version 1.14.0 Introduces Cell Behavior Hypothesis Grammar (CBHG) 3.0, enhancing the modeling of cellular behaviors with the addition of a new Cell_Integrity
class and refined phagocytosis behaviors (now split into separate rates for apoptotic, necrotic, and other dead cells). The built-in "attack" model has been refined to include formation of a persistent synapse (with a spring adhesion) throughout the attack (which is tunable via the attack_duration
parameter), and a clarified attack_damage_rate
to denote the rate at which an attacker damages its target cell. The attacking cell also tracks how long it has attacked (may be useful for exhaustion modeling), whether it is or is not attacking, and the identity (cell pointer) of the cell it is attacking.
The new Cell_Integrity
class (within Phenotype
) allows more control over cell damage. Attacking cells (see above) can increase damage, as well as a new generalized damage_rate
that can (for example) be used to model damage from other sources such as cytotoxic drugs or toxins. A built-in model for damage repair (with default rate damage_repair_rate
= 0) can be used for simple modeling of damage repair (e.g., DNA damage response during a cycle damage checkpoint).
This release also includes an option to set the random number generator seed value, new capabilities to draw initial parameters from a random distribution, and support for user-defined custom functions the evaluated during cell division (which allow users to individually set properties of daughter cells, such as during asymmetric division). Beyond bug fixes, the release includes a systematic testing package, utilizing scripts and GitHub Actions for automated testing.
We are grateful for contributions by Vincent Noël, Randy Heiland, Daniel Bergman, Heber Rocha, and Elmar Bucher in this release.
NOTE 1: MacOS users need to define a PHYSICELL_CPP environment variable to specify their OpenMP-enabled g++. See the Setup Guides for details.
NOTE 2: Windows users need to follow an updated (from v1.8) MinGW64 installation procedure. This will install an updated version of g++, plus libraries that are needed for some of the intracellular models. See the Setup Guides for details.
- Introduced changes to Rules:
damage rate
(a part ofCell_Integrity
) is now a generalized term for a rate of damage caused by non-attack meansattack damage rate
means whatdamage rate
used to mean: how fast an attacking cell deals damage to a target cell throughout the duration of the atttackphagocytose dead cell
is replaced by death-model-specific rates:phagocytose apoptotic cell
phagocytose necrotic cell
phagocytose other dead cell
- New
Cell_Integrity
class in PhysiCell_phenotype.h.damage
was moved from Cell_State into Cell_Integrity- the cancer-biorobots-sample
custom.cpp
was updated to reflect this change.
- the cancer-biorobots-sample
contact with dead cell
has been supplemented with additional (refined) signalscontact with apoptotic cell
,contact with necrotic cell
, andcontact with other dead cell
- Seed for random numbers: in the top most tag of a config file (for options that apply to the overall simulation), there is now a <random_seed>. Traditionally, this has been provided in <user_parameters> and if it is still present there, it will override the one in . Users are encouraged to migrate away from its use in <user_parameters> as this will likely be removed from sample projects in a future release.
- Setting as an integer will have the same behavior as the
user_parameter
- <random_seed>0</random_seed>
- Setting as “”, “random”, or “system_clock” will use the system clock to set the random seed
- <random_seed />
- <random_seed></random_seed>
- <random_seed>random</random_seed>
- <random_seed>system_clock</random_seed>
- Setting as an integer will have the same behavior as the
- New option for a user-defined custom function for cell division. If provided, the custom function will receive pointers to the two daughter cells. A new sample project,
custom-division-sample
, is provided. - Initial parameter distributions
- Users can now start cells with heterogeneity in any behavior or also the total volume
- For ease of access, in studio navigate to Cell Types > Misc > Parameter Distributions
- Five distributions supported:
- Uniform
- Set min and max; behavior ~ U(min, max)
- Log uniform
- Set min and max; z ~ U(log(min), log(max)); behavior ~ exp(z)
- Note: min and max are on the behavior scale, not the logarithmic scale
- Normal
- Set μ and σ; behavior ~ N(μ, σ)
- Optionally set lb, ub to impose lb <= behavior <= ub
- Log normal
- Set μ and σ; z ~ N(μ, σ); behavior ~ exp(z)
- Optionally set lb, ub to impose lb <= behavior <= ub
- Note: μ and σ are on the logarithmic scale
- Note: lb and ub are on the behavior scale
- Log10 normal
- Same as log normal, except behavior ~ 10^z
- Implemented because log10 values are more human-interpretable
- Uniform
- Can enforce that the base value is within the distribution to help constrain parameter sweeps
- “Enable” attributes make it easy to toggle on/off individual distributions or for an entire cell type
- MultiCellDS update:
- PhysiBoSS intracellular data is now part of data export
- Spring attachments are now part of data export
- Streamlined MultiCellDS with incorporation of more single-cell parameters/state variables
- Update to PhysiBoSS 2.2.3
- Added steepness parameter to output mapping, controlling the Hill coefficient used.
- Added use_for_dead parameter to input and output mapping, to define if this mapping should be used on dead cells.
- Added three new sample projects:
- template_BM: adaptation of the template project of PhysiCell, with PhysiBoSS support
- physiboss-tutorial: three toy models presented in the PhysiBoSS tutorial (10.48550/arXiv.2406.18371).
- physiboss-tutorial-invasion: update of the cancer invasion model by Ruscone et al., also presented in the PhysiBoSS tutorial.
- Update to PhysiMeSS 1.0.1
- Most parameters are now defined in custom_data, to make them specific to a cell definition. This introduces the possibility to have multiple types of fibers.
- Introducing experimental pre-compiled binaries, available via python beta/download_binary.py.
- Non-monotonic rules: a single signal can now both cause an increase and a decrease in a behavior for a cell type (bringing the implementation in better compliance with the specification at https://www.biorxiv.org/content/10.1101/2023.09.17.557982)
- Initialize substrate initial conditions using a .mat or .csv file
- implemented in PhysiCell Studio; see output there for formatting of the csv
- Substrate heatmaps on SVGs improvements:
- set colormaps in the config file
- set the svg substrate color function by default for config-only based implementation
- Scripts in
/beta
to help with testing, both manually and via GitHub Actions:test_build_samples.sh
andtest*.py
- The Makefiles for all sample projects now do a recursive copy (
cp -r
) for files in the /config directory - throw error if duplicate substrate or user_parameter name found
sample_projects_intracellular/ode/ode_energy/main.cpp
was updated to usesave_PhysiCell_to_MultiCellDS_v2
Cell::convert_to_cell_definition
now retains the cell volume- fix bug in storing rules that occasionally resulted in seg faults
-
Future releases may further refine
Cell_Integrity
with more specific forms of damage (and accompanying damage and repair rates). -
We intend to deprecate the unused phenotype variables
relative_maximum_attachment_distance
,relative_detachment_distance
, andmaximum_attachment_rate
fromphenotype.mechanics.
-
We intend to merge
Custom_Variable
andCustom_Vector_Variable
in the future. -
We may change the role of
operator()
andoperator[]
inCustom_Variable
to more closely mirror the functionality inParameters<T>
. -
Additional search functions (e.g., to find a substrate or a custom variable) will start to return -1 if no matches are found, rather than 0.
-
We will change the timing of when
entry_function
s are executed within cycle models. Right now, they are evaluated immediately after the exit from the preceding phase (and prior to any cell division events), which means that only the parent cell executes it, rather than both daughter cells. Instead, we'll add an internal Boolean for "just exited a phase", and use this to execute the entry function at the next cycle call. This should make daughter cells independently execute the entry function. -
We might make
trigger_death
clear out all the cell's functions, or at least add an option to do this. -
We might change the behavior of copied Custom Data when a cell changes type (changes to a new cell definition). Currently, all custom data elements in a cell are overwritten based on those in the new cell definition. This is not the best behavior for custom data elements that represent state variables instead of type-dependent parameters.
-
Further XML-based simulation setup.
-
Read saved simulation states (as MultiCellDS digital snapshots)
-
Create an angiogenesis sample project
-
Create a small library of angiogenesis and vascularization codes as an optional standard module in ./modules (but not as a core component)
-
Further update sample projects to make use of more efficient interaction testing available
-
Major refresh of documentation.