Difference between revisions of "Tools Comparison 2022"

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| Generic nonlinear optimization
 
| Generic nonlinear optimization
 
| Markov Chain analysis<br> using state-based abstraction
 
| Markov Chain analysis<br> using state-based abstraction
| Provides a special notation for biochemical reaction networks (i.e. CellDesigner notation)
+
| Provides a special notation<br>for biochemical reaction networks<br> (i.e. CellDesigner notation)
 
|  
 
|  
 
| MopheusML language for<br> multicellular and multiscale modeling,<br>spatial models,<br>Cellular Potts models
 
| MopheusML language for<br> multicellular and multiscale modeling,<br>spatial models,<br>Cellular Potts models

Latest revision as of 13:50, 28 March 2022

Here we collect information about similar software and their features in comparison with BioUML.

[edit] Comparisons made by third parties

  • Support of SBML standard can be measured by percentage of passed tests from test suite presented on SBML web site.
  • Extensive comparison of different simulators according to their speed and percentage of passed SBML tests was performed by Maggioli et al.[1]

[edit] Modeling tools comparison

This comparison was made in February 2022. Previous was done in 2019 and is available at separate page Tools Comparison.

BioUML [2] COPASI [3] iBioSim [4]. CellDesigner [5] Tellurium[6] Morpheus[7] libRoadRunner
Current version
(stable)
2021.3
(Sep 2021)
4.34
(Aug 2021)
3.0.0
(Sep 2017)
4.4.2
(Jun 2020)
2.2.0
(Dec 2019)
2.2.6
(Feb 2022)
1.4.18
(May 2017)
Capabilities
1. Model creation visual\text-based via tables visual visual text-based via tables via direct API
2. Simulation + + + + + + +
3. Parameter fitting + + - - +/- (3rd party
python libraries)
+ via python/Julia
4. Model analysis + + + - + + +
5. Unique or rare features Parameter identifiability,
Manual parameter fitting
Generic nonlinear optimization Markov Chain analysis
using state-based abstraction
Provides a special notation
for biochemical reaction networks
(i.e. CellDesigner notation)
MopheusML language for
multicellular and multiscale modeling,
spatial models,
Cellular Potts models
6. Database access + - + + +/- (3rd party
python libraries)
- -
7. Jupyter notebooks + + + - + - +
Model formalism
1. ODE + + + + + + +
2. Stochastic Gillespie-type + + + + + + +
3. Algebraic + - + - + + -
4. Discrete + + + + + + +
5. Flux balance + - + - - - -
6. Modular modeling + - + - + + +
7. Mixed formalisms + - + - - + -
8. Agent-based + - + - - + -
9. Rule-based + - - - - + -
10. Population-based + - + - - + -
11. Cellular Potts Models - - - - - + -
Systems Biology Markup Language
1. level and version l3v2 (all tests passed) l3v2 except
algebraic
l3v2 l2v4 l3v2, except
algebraic, delay
l3v2, except
algebraic
l3v2 except
algebraic, delay
2. comp fully (all tests passed) import fully (all tests passed) - partially partially partially
3. fbc + - + - - - -
4. arrays - - + - - - -
5. distrib - - + - - - -
6. layout - - + - - - -
Other Standards
1. SBGN PD + export - + - - -
2. SBGN-ML + - - + - - -
3. SedML + + + + + - -
4. Combine archive + + + - + - -
5. SBOL - - + - +/- (3rd party
python libraries)
- -
6. Antimony + - - - + - -
7. Bionetgen + (standalone) - - - - - -
8. BioPAX + - - + - - -
Availability
1. Windows + + + + + + +
2. Linux + + + + + + +
3. MacOS + + + + + + +
4. Web application + + - - via Colab - via Colab
Programming Language Java C++ Java/С Java Python/Julia C++ C/C++/Pyhton/Julia

[edit] References

  1. Maggioli, F., Mancini, T., Tronci, E. (2020). SBML2Modelica: integrating biochemical models within open-sThis comparison was made in February 2022. Previous was done in 2019 and is available at separate page Tools Comparison.tandard simulation ecosystems. Bioinformatics, 36(7), 2165-2172. doi:https://doi.org/10.1093/bioinformatics/btz860
  2. Kolpakov, F., Akberdin, I., Kashapov, T., Kiselev, L., Kolmykov, S., Kondrakhin, Y., Kutumova, E., Mandrik, N., Pintus, S., Ryabova, A. and Sharipov, R. (2019). BioUML: an integrated environment for systems biology and collaborative analysis of biomedical data. Nucleic acids research, 47(W1), W225-W233. doi:https://doi.org/10.1093/nar/gkz440
  3. Hoops S., Sahle S., Gauges R., Lee C., Pahle J., Simus N., Singhal M., Xu L., Mendes P. and Kummer U. (2006). COPASI: a COmplex PAthway SImulator. Bioinformatics 22, 3067-74.
  4. Watanabe, L., Nguyen, T., Zhang, M., Zundel, Z., Zhang, Z., Madsen, C., Roehner, N., Myers, C. (2018). iBioSim 3: a tool for model-based genetic circuit design. ACS synthetic biology, 8(7), 1560-1563. doi:https://doi.org/10.1021/acssynbio.8b00078
  5. Funahashi, A., Tanimura, N., Morohashi, M., and Kitano, H., CellDesigner: a process diagram editor for gene-regulatory and biochemical networks, BIOSILICO, 1:159-162, 2003
  6. Choi K., Medley K., König M., Stocking K., Smith L., Gu S., Sauro, H.M. Tellurium: An extensible python-based modeling environment for systems and synthetic biology, Biosystems, Volume 171, 2018, Pages 74-79. doi:https://doi.org/10.1016/j.biosystems.2018.07.006.
  7. J. Starruß, W. de Back, L. Brusch and A. Deutsch. Morpheus: a user-friendly modeling environment for multiscale and multicellular systems biology. Bioinformatics, 30 (9): 1331-1332, 2014.
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