{
 "cells": [
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "# Application of MPBNs to the Bladder Tumorigenesis model by Remy et al. 2015\n",
    "\n",
    "We use Most Permissive Boolean Networks to analyze *reachable* attractors in the logical model published in [(Remy et al., 2015)](https://doi.org/10.1158/0008-5472.CAN-15-0602), by reproducing part of the experiments performed in [Estimating Attractor Reachability in Asynchronous Logical Models (Mendes et al, 2018](https://doi.org/10.3389/fphys.2018.01161) (Table 3).\n",
    "\n",
    "Note that, currently, the `mpbn` tool does not provide quantification of the propensity of reachable attractors. However, it guarantees their exhaustive identification."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 1,
   "metadata": {},
   "outputs": [],
   "source": [
    "import biolqm\n",
    "import ginsim\n",
    "import mpbn\n",
    "from colomoto_jupyter import tabulate"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "## Model\n",
    "\n",
    "### Original multivalued model"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 2,
   "metadata": {},
   "outputs": [
    {
     "data": {
      "text/markdown": [
       "Downloading http://ginsim.org/sites/default/files/Bladder_Model.zginml"
      ],
      "text/plain": [
       "<IPython.core.display.Markdown object>"
      ]
     },
     "metadata": {},
     "output_type": "display_data"
    },
    {
     "data": {
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      "text/plain": [
       "<IPython.core.display.Image object>"
      ]
     },
     "execution_count": 2,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "lrg = ginsim.load(\"http://ginsim.org/sites/default/files/Bladder_Model.zginml\")\n",
    "ginsim.show(lrg)"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "We use `biolqm` to convert it to a pure Boolean model."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 3,
   "metadata": {},
   "outputs": [
    {
     "data": {
      "text/plain": [
       "35"
      ]
     },
     "execution_count": 3,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "bn = biolqm.to_minibn(biolqm.booleanize(lrg.getModel()))\n",
    "mbn = mpbn.MPBooleanNetwork(bn)\n",
    "len(mbn) # display number of components"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 4,
   "metadata": {},
   "outputs": [
    {
     "data": {
      "text/plain": [
       "['DNAdamage', 'EGFR_stimulus', 'FGFR3_stimulus', 'GrowthInhibitors']"
      ]
     },
     "execution_count": 4,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "inputs = bn.inputs()\n",
    "inputs"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 5,
   "metadata": {},
   "outputs": [],
   "source": [
    "outputs = [\"Apoptosis_b1\", \"Growth_Arrest\", \"Proliferation\"]\n",
    "non_outputs = [n for n in bn if n not in outputs]"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "## Attractors\n",
    "\n",
    "We first compute the full list of attractors of the Most Permissive semantics.\n",
    "We recover exactly the same number as reported in the original publication."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 6,
   "metadata": {},
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "CPU times: user 6.12 ms, sys: 1.01 ms, total: 7.14 ms\n",
      "Wall time: 6.82 ms\n"
     ]
    },
    {
     "data": {
      "text/html": [
       "<div>\n",
       "<style scoped>\n",
       "    .dataframe tbody tr th:only-of-type {\n",
       "        vertical-align: middle;\n",
       "    }\n",
       "\n",
       "    .dataframe tbody tr th {\n",
       "        vertical-align: top;\n",
       "    }\n",
       "\n",
       "    .dataframe thead th {\n",
       "        text-align: right;\n",
       "    }\n",
       "</style>\n",
       "<table border=\"1\" class=\"dataframe\">\n",
       "  <thead>\n",
       "    <tr style=\"text-align: right;\">\n",
       "      <th></th>\n",
       "      <th>AKT</th>\n",
       "      <th>ATM_b1</th>\n",
       "      <th>ATM_b2</th>\n",
       "      <th>Apoptosis_b1</th>\n",
       "      <th>Apoptosis_b2</th>\n",
       "      <th>CDC25A</th>\n",
       "      <th>CHEK1_2_b1</th>\n",
       "      <th>CHEK1_2_b2</th>\n",
       "      <th>CyclinA</th>\n",
       "      <th>CyclinD1</th>\n",
       "      <th>CyclinE1</th>\n",
       "      <th>DNAdamage</th>\n",
       "      <th>E2F1_b1</th>\n",
       "      <th>E2F1_b2</th>\n",
       "      <th>E2F3_b1</th>\n",
       "      <th>E2F3_b2</th>\n",
       "      <th>EGFR</th>\n",
       "      <th>EGFR_stimulus</th>\n",
       "      <th>FGFR3</th>\n",
       "      <th>FGFR3_stimulus</th>\n",
       "      <th>GRB2</th>\n",
       "      <th>GrowthInhibitors</th>\n",
       "      <th>Growth_Arrest</th>\n",
       "      <th>MDM2</th>\n",
       "      <th>PI3K</th>\n",
       "      <th>PTEN</th>\n",
       "      <th>Proliferation</th>\n",
       "      <th>RAS</th>\n",
       "      <th>RB1</th>\n",
       "      <th>RBL2</th>\n",
       "      <th>SPRY</th>\n",
       "      <th>TP53</th>\n",
       "      <th>p14ARF</th>\n",
       "      <th>p16INK4a</th>\n",
       "      <th>p21CIP</th>\n",
       "    </tr>\n",
       "  </thead>\n",
       "  <tbody>\n",
       "    <tr>\n",
       "      <th>0</th>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>1</th>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>2</th>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>3</th>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>4</th>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>5</th>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>6</th>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>7</th>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>8</th>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>9</th>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>10</th>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>11</th>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>12</th>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>13</th>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>14</th>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>15</th>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>16</th>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>17</th>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>18</th>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>19</th>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>20</th>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>21</th>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>22</th>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>23</th>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>*</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>1</td>\n",
       "      <td>*</td>\n",
       "    </tr>\n",
       "    <tr>\n",
       "      <th>24</th>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>*</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>*</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>*</td>\n",
       "      <td>*</td>\n",
       "      <td>*</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>*</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "    </tr>\n",
       "  </tbody>\n",
       "</table>\n",
       "</div>"
      ],
      "text/plain": [
       "   AKT  ATM_b1  ATM_b2  Apoptosis_b1  Apoptosis_b2 CDC25A  CHEK1_2_b1  \\\n",
       "0    0       0       0             0             0      0           0   \n",
       "1    0       0       0             0             0      0           0   \n",
       "2    0       0       0             0             0      0           0   \n",
       "3    0       0       0             0             0      0           0   \n",
       "4    0       0       0             0             0      0           0   \n",
       "5    0       0       0             0             0      0           0   \n",
       "6    0       0       0             0             0      0           0   \n",
       "7    0       0       0             0             0      1           0   \n",
       "8    0       0       0             0             0      1           0   \n",
       "9    0       0       0             0             0      1           0   \n",
       "10   0       0       0             0             0      1           0   \n",
       "11   0       1       0             1             0      0           1   \n",
       "12   0       1       0             1             0      0           1   \n",
       "13   0       1       0             1             0      0           1   \n",
       "14   0       1       0             1             0      0           1   \n",
       "15   0       1       0             1             0      0           1   \n",
       "16   0       1       0             1             0      0           1   \n",
       "17   0       1       0             1             0      0           1   \n",
       "18   0       1       0             1             0      0           1   \n",
       "19   0       1       0             1             0      0           1   \n",
       "20   0       1       0             1             0      0           1   \n",
       "21   0       1       0             1             0      0           1   \n",
       "22   0       1       0             1             0      0           1   \n",
       "23   *       0       0             0             0      0           0   \n",
       "24   *       0       0             0             0      *           0   \n",
       "\n",
       "    CHEK1_2_b2 CyclinA CyclinD1 CyclinE1  DNAdamage E2F1_b1  E2F1_b2 E2F3_b1  \\\n",
       "0            0       0        0        0          0       0        0       0   \n",
       "1            0       0        0        0          0       0        0       0   \n",
       "2            0       0        0        0          0       0        0       0   \n",
       "3            0       0        0        0          0       0        0       0   \n",
       "4            0       0        0        0          0       0        0       0   \n",
       "5            0       0        0        0          0       0        0       1   \n",
       "6            0       0        0        0          0       0        0       1   \n",
       "7            0       1        0        1          0       1        0       1   \n",
       "8            0       1        0        1          0       1        0       1   \n",
       "9            0       1        1        1          0       1        0       1   \n",
       "10           0       1        1        1          0       1        0       1   \n",
       "11           0       0        0        0          1       0        0       0   \n",
       "12           0       0        0        0          1       0        0       0   \n",
       "13           0       0        0        0          1       0        0       0   \n",
       "14           0       0        0        0          1       0        0       0   \n",
       "15           0       0        0        0          1       0        0       0   \n",
       "16           0       0        0        0          1       0        0       0   \n",
       "17           0       0        0        0          1       0        0       0   \n",
       "18           0       0        0        0          1       0        0       0   \n",
       "19           0       0        0        0          1       0        0       0   \n",
       "20           0       0        0        0          1       0        0       1   \n",
       "21           0       0        0        0          1       0        0       1   \n",
       "22           0       0        0        0          1       0        0       *   \n",
       "23           0       0        0        0          0       0        0       *   \n",
       "24           0       *        *        *          0       *        0       *   \n",
       "\n",
       "    E2F3_b2 EGFR  EGFR_stimulus  FGFR3  FGFR3_stimulus GRB2  GrowthInhibitors  \\\n",
       "0         0    0              0      0               0    0                 0   \n",
       "1         0    0              0      0               0    0                 1   \n",
       "2         0    0              0      0               0    0                 1   \n",
       "3         0    0              0      1               1    0                 1   \n",
       "4         0    0              1      1               1    0                 1   \n",
       "5         0    0              0      1               1    0                 1   \n",
       "6         0    0              1      1               1    0                 1   \n",
       "7         0    0              0      1               1    0                 1   \n",
       "8         0    0              1      1               1    0                 1   \n",
       "9         0    0              0      1               1    0                 0   \n",
       "10        0    0              1      1               1    0                 0   \n",
       "11        0    0              0      0               0    0                 0   \n",
       "12        0    0              0      0               0    0                 1   \n",
       "13        0    0              0      0               0    0                 1   \n",
       "14        0    0              0      1               1    0                 0   \n",
       "15        0    0              0      1               1    0                 1   \n",
       "16        0    0              1      1               1    0                 0   \n",
       "17        0    0              1      1               1    0                 1   \n",
       "18        0    *              1      0               0    *                 0   \n",
       "19        0    *              1      0               0    *                 1   \n",
       "20        0    0              0      1               1    0                 1   \n",
       "21        0    0              1      1               1    0                 1   \n",
       "22        0    *              1      0               0    *                 1   \n",
       "23        0    *              1      0               0    *                 1   \n",
       "24        0    *              1      0               0    *                 0   \n",
       "\n",
       "   Growth_Arrest MDM2 PI3K  PTEN Proliferation RAS RB1 RBL2 SPRY  TP53 p14ARF  \\\n",
       "0              1    0    0     0             0   0   1    1    0     0      0   \n",
       "1              1    0    0     0             0   0   0    1    0     0      0   \n",
       "2              1    0    0     0             0   0   1    1    0     0      0   \n",
       "3              1    0    0     0             0   1   1    1    1     0      0   \n",
       "4              1    0    0     0             0   1   1    1    1     0      0   \n",
       "5              1    0    0     0             0   1   0    1    1     0      0   \n",
       "6              1    0    0     0             0   1   0    1    1     0      0   \n",
       "7              0    0    0     0             1   1   0    0    1     0      1   \n",
       "8              0    0    0     0             1   1   0    0    1     0      1   \n",
       "9              0    0    0     0             1   1   0    0    1     0      1   \n",
       "10             0    0    0     0             1   1   0    0    1     0      1   \n",
       "11             1    0    0     1             0   0   1    1    0     1      0   \n",
       "12             1    0    0     1             0   0   0    1    0     1      0   \n",
       "13             1    0    0     1             0   0   1    1    0     1      0   \n",
       "14             1    0    0     1             0   1   1    1    1     1      0   \n",
       "15             1    0    0     1             0   1   1    1    1     1      0   \n",
       "16             1    0    0     1             0   1   1    1    1     1      0   \n",
       "17             1    0    0     1             0   1   1    1    1     1      0   \n",
       "18             1    0    0     1             0   *   1    1    *     1      0   \n",
       "19             1    0    0     1             0   *   1    1    *     1      0   \n",
       "20             1    0    0     1             0   1   0    1    1     1      0   \n",
       "21             1    0    0     1             0   1   0    1    1     1      0   \n",
       "22             1    0    0     1             0   *   0    1    *     1      0   \n",
       "23             1    *    *     0             0   *   0    1    *     0      0   \n",
       "24             *    *    *     0             *   *   *    *    *     0      *   \n",
       "\n",
       "    p16INK4a p21CIP  \n",
       "0          0      0  \n",
       "1          1      1  \n",
       "2          0      1  \n",
       "3          0      1  \n",
       "4          0      1  \n",
       "5          1      1  \n",
       "6          1      1  \n",
       "7          1      0  \n",
       "8          1      0  \n",
       "9          0      0  \n",
       "10         0      0  \n",
       "11         0      1  \n",
       "12         1      1  \n",
       "13         0      1  \n",
       "14         0      1  \n",
       "15         0      1  \n",
       "16         0      1  \n",
       "17         0      1  \n",
       "18         0      1  \n",
       "19         0      1  \n",
       "20         1      1  \n",
       "21         1      1  \n",
       "22         1      1  \n",
       "23         1      *  \n",
       "24         0      0  "
      ]
     },
     "execution_count": 6,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "%time a = list(mbn.attractors())\n",
    "tabulate(a)"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "To have a better overview of the input/output behaviour, we display the attractors by selecting only input and output components and then only output components."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 7,
   "metadata": {},
   "outputs": [
    {
     "data": {
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       "      <td>1</td>\n",
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       "      <td>1</td>\n",
       "      <td>1</td>\n",
       "      <td>0</td>\n",
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       "      <td>1</td>\n",
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       "  </tbody>\n",
       "</table>\n",
       "</div>"
      ],
      "text/plain": [
       "    DNAdamage  EGFR_stimulus  FGFR3_stimulus  GrowthInhibitors  Apoptosis_b1  \\\n",
       "0           0              0               0                 0             0   \n",
       "1           0              0               0                 1             0   \n",
       "2           0              0               1                 0             0   \n",
       "3           0              0               1                 1             0   \n",
       "4           0              0               1                 1             0   \n",
       "5           0              1               0                 0             0   \n",
       "6           0              1               0                 1             0   \n",
       "7           0              1               1                 0             0   \n",
       "8           0              1               1                 1             0   \n",
       "9           0              1               1                 1             0   \n",
       "10          1              0               0                 0             1   \n",
       "11          1              0               0                 1             1   \n",
       "12          1              0               1                 0             1   \n",
       "13          1              0               1                 1             1   \n",
       "14          1              1               0                 0             1   \n",
       "15          1              1               0                 1             1   \n",
       "16          1              1               1                 0             1   \n",
       "17          1              1               1                 1             1   \n",
       "\n",
       "   Growth_Arrest Proliferation  \n",
       "0              1             0  \n",
       "1              1             0  \n",
       "2              0             1  \n",
       "3              0             1  \n",
       "4              1             0  \n",
       "5              *             *  \n",
       "6              1             0  \n",
       "7              0             1  \n",
       "8              0             1  \n",
       "9              1             0  \n",
       "10             1             0  \n",
       "11             1             0  \n",
       "12             1             0  \n",
       "13             1             0  \n",
       "14             1             0  \n",
       "15             1             0  \n",
       "16             1             0  \n",
       "17             1             0  "
      ]
     },
     "execution_count": 7,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "tabulate(a, columns=inputs+outputs)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 8,
   "metadata": {},
   "outputs": [
    {
     "data": {
      "text/html": [
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      "text/plain": [
       "   Apoptosis_b1 Growth_Arrest Proliferation\n",
       "0             0             0             1\n",
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       "2             0             *             *\n",
       "3             1             1             0"
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     "execution_count": 8,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "tabulate(a, columns=outputs)"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "## Reachable attractors\n",
    "\n",
    "For different input settings, and starting from all the other nodes being inactive, we compute the reachable attractors in the wild-type model."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 9,
   "metadata": {},
   "outputs": [],
   "source": [
    "all_zero = dict([(n,0) for n in bn])"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 10,
   "metadata": {},
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "CPU times: user 8.46 ms, sys: 27 µs, total: 8.48 ms\n",
      "Wall time: 7.92 ms\n"
     ]
    },
    {
     "data": {
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       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
       "      <td>0</td>\n",
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       "      <td>0</td>\n",
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      ],
      "text/plain": [
       "   Apoptosis_b1  Growth_Arrest  Proliferation  AKT  ATM_b1  ATM_b2  \\\n",
       "0             0              1              0    0       0       0   \n",
       "1             0              1              0    0       0       0   \n",
       "\n",
       "   Apoptosis_b2  CDC25A  CHEK1_2_b1  CHEK1_2_b2  CyclinA  CyclinD1  CyclinE1  \\\n",
       "0             0       0           0           0        0         0         0   \n",
       "1             0       0           0           0        0         0         0   \n",
       "\n",
       "   DNAdamage  E2F1_b1  E2F1_b2  E2F3_b1  E2F3_b2  EGFR  EGFR_stimulus  FGFR3  \\\n",
       "0          0        0        0        0        0     0              0      0   \n",
       "1          0        0        0        0        0     0              0      0   \n",
       "\n",
       "   FGFR3_stimulus  GRB2  GrowthInhibitors  MDM2  PI3K  PTEN  RAS  RB1  RBL2  \\\n",
       "0               0     0                 1     0     0     0    0    0     1   \n",
       "1               0     0                 1     0     0     0    0    1     1   \n",
       "\n",
       "   SPRY  TP53  p14ARF  p16INK4a  p21CIP  \n",
       "0     0     0       0         1       1  \n",
       "1     0     0       0         0       1  "
      ]
     },
     "execution_count": 10,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "init = all_zero.copy()\n",
    "init[\"GrowthInhibitors\"] = 1\n",
    "%time a = list(mbn.attractors(reachable_from=init))\n",
    "tabulate(a, columns=outputs+non_outputs)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 11,
   "metadata": {},
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "CPU times: user 10.2 ms, sys: 60 µs, total: 10.2 ms\n",
      "Wall time: 9.19 ms\n"
     ]
    },
    {
     "data": {
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       "      <th>E2F3_b1</th>\n",
       "      <th>E2F3_b2</th>\n",
       "      <th>EGFR</th>\n",
       "      <th>EGFR_stimulus</th>\n",
       "      <th>FGFR3</th>\n",
       "      <th>FGFR3_stimulus</th>\n",
       "      <th>GRB2</th>\n",
       "      <th>GrowthInhibitors</th>\n",
       "      <th>MDM2</th>\n",
       "      <th>PI3K</th>\n",
       "      <th>PTEN</th>\n",
       "      <th>RAS</th>\n",
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       "      <th>RBL2</th>\n",
       "      <th>SPRY</th>\n",
       "      <th>TP53</th>\n",
       "      <th>p14ARF</th>\n",
       "      <th>p16INK4a</th>\n",
       "      <th>p21CIP</th>\n",
       "    </tr>\n",
       "  </thead>\n",
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       "      <td>0</td>\n",
       "    </tr>\n",
       "  </tbody>\n",
       "</table>\n",
       "</div>"
      ],
      "text/plain": [
       "   Apoptosis_b1 Growth_Arrest Proliferation AKT  ATM_b1  ATM_b2  Apoptosis_b2  \\\n",
       "0             0             *             *   *       0       0             0   \n",
       "\n",
       "  CDC25A  CHEK1_2_b1  CHEK1_2_b2 CyclinA CyclinD1 CyclinE1  DNAdamage E2F1_b1  \\\n",
       "0      *           0           0       *        *        *          0       *   \n",
       "\n",
       "   E2F1_b2 E2F3_b1  E2F3_b2 EGFR  EGFR_stimulus  FGFR3  FGFR3_stimulus GRB2  \\\n",
       "0        0       *        0    *              1      0               0    *   \n",
       "\n",
       "   GrowthInhibitors MDM2 PI3K  PTEN RAS RB1 RBL2 SPRY  TP53 p14ARF  p16INK4a  \\\n",
       "0                 0    *    *     0   *   *    *    *     0      *         0   \n",
       "\n",
       "   p21CIP  \n",
       "0       0  "
      ]
     },
     "execution_count": 11,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "init = all_zero.copy()\n",
    "init[\"EGFR_stimulus\"] = 1\n",
    "%time a = list(mbn.attractors(reachable_from=init))\n",
    "tabulate(a, columns=outputs+non_outputs)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 12,
   "metadata": {},
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "CPU times: user 10.3 ms, sys: 7 µs, total: 10.3 ms\n",
      "Wall time: 9.25 ms\n"
     ]
    },
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       "   Apoptosis_b1  Growth_Arrest  Proliferation AKT  ATM_b1  ATM_b2  \\\n",
       "0             0              1              0   *       0       0   \n",
       "\n",
       "   Apoptosis_b2  CDC25A  CHEK1_2_b1  CHEK1_2_b2  CyclinA  CyclinD1  CyclinE1  \\\n",
       "0             0       0           0           0        0         0         0   \n",
       "\n",
       "   DNAdamage  E2F1_b1  E2F1_b2 E2F3_b1  E2F3_b2 EGFR  EGFR_stimulus  FGFR3  \\\n",
       "0          0        0        0       *        0    *              1      0   \n",
       "\n",
       "   FGFR3_stimulus GRB2  GrowthInhibitors MDM2 PI3K  PTEN RAS  RB1  RBL2 SPRY  \\\n",
       "0               0    *                 1    *    *     0   *    0     1    *   \n",
       "\n",
       "   TP53  p14ARF  p16INK4a p21CIP  \n",
       "0     0       0         1      *  "
      ]
     },
     "execution_count": 12,
     "metadata": {},
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    }
   ],
   "source": [
    "init = all_zero.copy()\n",
    "init[\"EGFR_stimulus\"] = 1\n",
    "init[\"GrowthInhibitors\"] = 1\n",
    "%time a = list(mbn.attractors(reachable_from=init))\n",
    "tabulate(a, columns=outputs+non_outputs)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 13,
   "metadata": {},
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "CPU times: user 11 ms, sys: 0 ns, total: 11 ms\n",
      "Wall time: 9.83 ms\n"
     ]
    },
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       "   Apoptosis_b1  Growth_Arrest  Proliferation  AKT  ATM_b1  ATM_b2  \\\n",
       "0             0              0              1    0       0       0   \n",
       "1             0              1              0    0       0       0   \n",
       "2             0              1              0    0       0       0   \n",
       "\n",
       "   Apoptosis_b2  CDC25A  CHEK1_2_b1  CHEK1_2_b2  CyclinA  CyclinD1  CyclinE1  \\\n",
       "0             0       1           0           0        1         0         1   \n",
       "1             0       0           0           0        0         0         0   \n",
       "2             0       0           0           0        0         0         0   \n",
       "\n",
       "   DNAdamage  E2F1_b1  E2F1_b2  E2F3_b1  E2F3_b2  EGFR  EGFR_stimulus  FGFR3  \\\n",
       "0          0        1        0        1        0     0              1      1   \n",
       "1          0        0        0        0        0     0              1      1   \n",
       "2          0        0        0        1        0     0              1      1   \n",
       "\n",
       "   FGFR3_stimulus  GRB2  GrowthInhibitors  MDM2  PI3K  PTEN  RAS  RB1  RBL2  \\\n",
       "0               1     0                 1     0     0     0    1    0     0   \n",
       "1               1     0                 1     0     0     0    1    1     1   \n",
       "2               1     0                 1     0     0     0    1    0     1   \n",
       "\n",
       "   SPRY  TP53  p14ARF  p16INK4a  p21CIP  \n",
       "0     1     0       1         1       0  \n",
       "1     1     0       0         0       1  \n",
       "2     1     0       0         1       1  "
      ]
     },
     "execution_count": 13,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "init = all_zero.copy()\n",
    "init[\"EGFR_stimulus\"] = 1\n",
    "init[\"FGFR3_stimulus\"] = 1\n",
    "init[\"GrowthInhibitors\"] = 1\n",
    "%time a = list(mbn.attractors(reachable_from=init))\n",
    "tabulate(a, columns=outputs+non_outputs)"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "## Attractors with model perturbations\n",
    "\n",
    "We reproduce the analysis of attractors under various mutations, focusing when `DNAdamage` is off. They match with Table 2 of [(Remy et al., 2015)](https://doi.org/10.3389/fbioe.2014.00086)."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 14,
   "metadata": {},
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "CPU times: user 7.73 ms, sys: 1.04 ms, total: 8.77 ms\n",
      "Wall time: 7.45 ms\n"
     ]
    },
    {
     "data": {
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       "   Apoptosis_b1 Growth_Arrest Proliferation\n",
       "0             0             0             1\n",
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     "execution_count": 14,
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   ],
   "source": [
    "%time a = list(mbn.attractors(constraints={\"DNAdamage\":0}))\n",
    "tabulate(a, columns=outputs)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 15,
   "metadata": {},
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "CPU times: user 6.33 ms, sys: 905 µs, total: 7.24 ms\n",
      "Wall time: 6.42 ms\n"
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     "execution_count": 15,
     "metadata": {},
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   "source": [
    "bn_mut = mbn.copy()\n",
    "bn_mut[\"FGFR3\"] = 1\n",
    "%time a = list(bn_mut.attractors(constraints={\"DNAdamage\":0}))\n",
    "tabulate(a, columns=outputs)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 16,
   "metadata": {},
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "CPU times: user 7.59 ms, sys: 6 µs, total: 7.6 ms\n",
      "Wall time: 6.67 ms\n"
     ]
    },
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    "bn_mut = mbn.copy()\n",
    "bn_mut[\"PI3K\"] = 1\n",
    "%time a = list(bn_mut.attractors(constraints={\"DNAdamage\":0}))\n",
    "tabulate(a, columns=outputs)"
   ]
  },
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   "cell_type": "code",
   "execution_count": 17,
   "metadata": {},
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "CPU times: user 8.13 ms, sys: 6 µs, total: 8.14 ms\n",
      "Wall time: 7.05 ms\n"
     ]
    },
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    "bn_mut = mbn.copy()\n",
    "bn_mut[\"PI3K\"] = 1\n",
    "bn_mut[\"FGFR3\"] = 1\n",
    "%time a = list(bn_mut.attractors(constraints={\"DNAdamage\":0}))\n",
    "tabulate(a, columns=outputs)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 18,
   "metadata": {},
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    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "CPU times: user 6.14 ms, sys: 65 µs, total: 6.2 ms\n",
      "Wall time: 5.33 ms\n"
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     "execution_count": 18,
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   "source": [
    "bn_mut = mbn.copy()\n",
    "bn_mut[\"PI3K\"] = 1\n",
    "bn_mut[\"FGFR3\"] = 1\n",
    "bn_mut[\"p16INK4a\"] = 0\n",
    "%time a = list(bn_mut.attractors(constraints={\"DNAdamage\":0}))\n",
    "tabulate(a, columns=outputs)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": null,
   "metadata": {},
   "outputs": [],
   "source": []
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