Metadata-Version: 2.1
Name: biostoch
Version: 0.0.5
Summary: Stochastic and Deterministic Simulation Methods Used in Computational Biology
Home-page: https://github.com/LoqmanSamani/biostoch
Author: Loghman Samani
Author-email: samaniloqman91@gmail.com
Keywords: Stochastic Simulation,Deterministic Simulation,Computational Biology
Classifier: Development Status :: 1 - Planning
Classifier: Intended Audience :: Developers
Classifier: Programming Language :: Python :: 3
Classifier: Operating System :: Unix
Classifier: Operating System :: MacOS :: MacOS X
Classifier: Operating System :: Microsoft :: Windows
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: numpy
Requires-Dist: matplotlib


# BioStoch
<p><b>Simulation in Biology<p></p>

![ssa1.png](https://github.com/LoqmanSamani/biostoch/blob/systembiology/examples/plots/ssa1.png)
<p><i>Simulated with GillespySimulator: Concentration trajectories of species A and B over time. Ten independent simulations were performed, each represented by a different line color<i></p>


### Overview

`biostoch` is a Python library for simulating chemical and biological models using various deterministic and stochastic methods. It provides implementations of methods such as Euler's method, the Runge-Kutta algorithm, the Stochastic Simulation Algorithm (SSA), Tau-Leaping, and the Chemical Langevin Equation (CLE). These methods can be used to model and analyze the dynamics of biochemical reactions, gene regulatory networks, and other biological systems.

### Installation

Install `biostoch` and its dependencies using pip:

```bash
pip install numpy matplotlib 
pip install biostoch
```

### Usage
```python
import numpy
import matplotlib
import time
from biostoch.model import Model
from biostoch.ode import EulerSimulator, RungeKuttaSimulator
from biostoch.ssa import GillespieSimulator
from biostoch.tau_leaping import TauLeaping
from biostoch.cle import ChemicalLangevin
from biostoch.visualization import Visualization

# Define a system of reactions, in this case, a simple system with two reactions: A <-> B; with rate constants K1 = 0.1, K2 = 0.05
model = Model() 

# Add rate constants for each reaction in the system
model.parameters({
    "K1": 0.1, 
    "K2": 0.05
})

# Add species and rate of change for each of them
model.species(
    components={
        "A": 100.0, 
        "B": 0.0
    }, 
    rate_change={
        "A": "K2 * B - K1 * A", 
        "B": "K1 * A - K2 * B"
    }
)

# Add reactions and rate for each of them
model.reactions(
    reacts={
        "reaction1": "A -> B", 
        "reaction2": "B -> A"
    },
    rates={
        "reaction1": "K1 * A", 
        "reaction2": "K2 * B"
    }
)

# Simulate the model using ordinary differential equations (ODE) with the Euler method
euler_model = EulerSimulator(
    model=model, 
    start=0, 
    stop=100, 
    epochs=1000
)
euler_model.reset() # Reset the model to initialize if it has been used before
euler_model.simulate() # Simulate the model 
euler_model.species # Print the model species after the simulation, a dictionary containing the change in species concentration during the simulation time
euler_model.time # Show how long the simulation took to complete

# Simulate the model using ordinary differential equations (ODE) with the Runge-Kutta method
runge_model = RungeKuttaSimulator(
    model=model, 
    start=0, 
    stop=100, 
    epochs=1000
)

runge_model.simulate()
runge_model.species
runge_model.time

# Simulate the model using the Stochastic Simulation Algorithm (SSA)
ssa_model = GillespieSimulator(
    model=model, 
    start=0, 
    stop=100, 
    max_epochs=1000
)

ssa_model.simulate()
ssa_model.species
ssa_model.time

# Simulate the model using the Tau-Leaping method
tau_model = TauLeaping(
    model=model, 
    start=0, 
    stop=100, 
    max_epochs=100
)

tau_model.simulate()
tau_model.species
tau_model.time

# Simulate the model using the Chemical Langevin Equation method
cle_model = ChemicalLangevin(
    model=model,
    start=0,
    stop=100, 
    max_epochs=1000
)

cle_model.simulate()
cle_model.species
cle_model.time

# Visualize the simulated models using integrated matplotlib.pyplot in biostoch
euler_plot = Visualization(euler_model)
runge_plot = Visualization(euler_model)
ssa_plot = Visualization(euler_model)
tau_plot = Visualization(euler_model)
cle_plot = Visualization(euler_model)

euler_plot.plot()
runge_plot.plot()
ssa_plot.plot()
tau_plot.plot()
cle_plot.plot()

```

### License

This project is licensed under the [MIT License](https://github.com/LoqmanSamani/biostoch/blob/systembiology/LICENSE)
