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import streamlit as st |
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import pandas as pd |
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import numpy as np |
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import plotly.graph_objects as go |
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import plotly.express as px |
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from plotly.subplots import make_subplots |
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from scipy import stats |
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import py3Dmol |
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from streamlit.components.v1 import html |
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import networkx as nx |
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from sklearn.model_selection import train_test_split |
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from sklearn.ensemble import GradientBoostingClassifier |
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from sklearn.metrics import classification_report, confusion_matrix |
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import shap |
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from sklearn.cluster import KMeans |
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from sklearn.preprocessing import StandardScaler |
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from scipy.integrate import odeint |
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st.set_page_config(layout="wide", page_title="Computational Biology Analysis") |
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BACKGROUND_COLOR = 'rgb(28, 28, 28)' |
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TEXT_COLOR = 'white' |
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ACCENT_COLOR = '#FFA500' |
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PLOT_FACE_COLOR = '#1c1c1c' |
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st.markdown(f""" |
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<style> |
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@import url('https://fonts.googleapis.com/css2?family=Roboto:wght@400;700&display=swap'); |
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html, body, [class*="st-"], .main, .stApp {{ |
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background-color: {BACKGROUND_COLOR}; |
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color: {TEXT_COLOR}; |
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font-family: 'Roboto', 'Funnel Sans', sans-serif; |
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}} |
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.stTabs [data-baseweb="tab-list"] {{ |
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gap: 24px; |
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}} |
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.stTabs [data-baseweb="tab"] {{ |
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height: 50px; |
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white-space: pre-wrap; |
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background-color: transparent; |
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border-radius: 4px 4px 0px 0px; |
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gap: 1px; |
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padding-top: 10px; |
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padding-bottom: 10px; |
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}} |
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/* --- FIX STARTS HERE --- */ |
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.stTabs [aria-selected="true"] {{ |
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background-color: {PLOT_FACE_COLOR}; |
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border-bottom: 3px solid {ACCENT_COLOR}; |
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}} |
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/* --- FIX ENDS HERE --- */ |
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h1, h2, h3, h4, h5, h6 {{ |
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color: {TEXT_COLOR}; |
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}} |
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.stButton>button {{ |
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background-color: {ACCENT_COLOR}; |
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color: black; |
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border: none; |
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padding: 10px 20px; |
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border-radius: 8px; |
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}} |
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</style> |
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""", unsafe_allow_html=True) |
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@st.cache_data |
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def generate_ml_data(): |
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np.random.seed(42) |
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n_samples = 300 |
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tnf_a = np.concatenate([np.random.normal(95, 10, 100), np.random.normal(155, 15, 100), np.random.normal(145, 15, 100)]) |
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myhc_ratio = np.concatenate([np.random.normal(1.1, 0.1, 100), np.random.normal(0.8, 0.1, 100), np.random.normal(1.2, 0.1, 100)]) |
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prob_dysfunction = 1 / (1 + np.exp(-(0.05 * (tnf_a - 150) - 7 * (myhc_ratio - 1.0)))) |
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systolic_dysfunction = np.random.binomial(1, prob_dysfunction) |
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df_ml = pd.DataFrame({'TNF_alpha': tnf_a, 'MyHC_Ratio': myhc_ratio, 'Dysfunction': systolic_dysfunction}) |
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return df_ml |
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@st.cache_resource |
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def train_model(df_ml): |
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X = df_ml[['TNF_alpha', 'MyHC_Ratio']] |
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y = df_ml['Dysfunction'] |
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X_train, X_test, y_train, y_test = train_test_split(X, y, test_size=0.3, random_state=42, stratify=y) |
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model = GradientBoostingClassifier(n_estimators=100, learning_rate=0.1, max_depth=3, random_state=42) |
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model.fit(X_train, y_train) |
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return model, X_train, X_test, y_train, y_test |
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def myhc_model_odes(y, t, params): |
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k_on, k_off, k_activate_tf, k_tf_bind_myh6, k_tf_unbind_myh6, k_tf_bind_myh7, k_tf_unbind_myh7, k_produce_myh6_base, k_produce_myh6_repressed, k_produce_myh7_base, k_produce_myh7_activated, k_degrade_myhc = params |
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TNFa_free, TNFR_free, TNFa_TNFR, TF_inactive, TF_active_free, Gene_myh6_free, Gene_myh6_TF, Gene_myh7_free, Gene_myh7_TF, MyHC_alpha, MyHC_beta = y |
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dydt = np.zeros(11) |
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dydt[0] = -k_on * TNFa_free * TNFR_free + k_off * TNFa_TNFR |
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dydt[1] = -k_on * TNFa_free * TNFR_free + k_off * TNFa_TNFR |
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dydt[2] = k_on * TNFa_free * TNFR_free - k_off * TNFa_TNFR |
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dydt[3] = -k_activate_tf * TNFa_TNFR * TF_inactive |
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dydt[4] = (k_activate_tf * TNFa_TNFR * TF_inactive - k_tf_bind_myh6 * TF_active_free * Gene_myh6_free + k_tf_unbind_myh6 * Gene_myh6_TF - k_tf_bind_myh7 * TF_active_free * Gene_myh7_free + k_tf_unbind_myh7 * Gene_myh7_TF) |
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dydt[5] = -k_tf_bind_myh6 * TF_active_free * Gene_myh6_free + k_tf_unbind_myh6 * Gene_myh6_TF |
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dydt[6] = k_tf_bind_myh6 * TF_active_free * Gene_myh6_free - k_tf_unbind_myh6 * Gene_myh6_TF |
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dydt[7] = -k_tf_bind_myh7 * TF_active_free * Gene_myh7_free + k_tf_unbind_myh7 * Gene_myh7_TF |
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dydt[8] = k_tf_bind_myh7 * TF_active_free * Gene_myh7_free - k_tf_unbind_myh7 * Gene_myh7_TF |
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dydt[9] = (k_produce_myh6_base * Gene_myh6_free + k_produce_myh6_repressed * Gene_myh6_TF - k_degrade_myhc * MyHC_alpha) |
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dydt[10] = (k_produce_myh7_base * Gene_myh7_free + k_produce_myh7_activated * Gene_myh7_TF - k_degrade_myhc * MyHC_beta) |
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return dydt |
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@st.cache_data |
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def run_ode_simulation(): |
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params = [1.0, 0.1, 1e-2, 1e-3, 0.5, 1e-3, 0.5, 1e-1, 1e-3, 1e-2, 1e-1, 5e-3] |
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y0 = [100, 20, 0, 50, 0, 10, 0, 10, 0, 0, 0] |
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t = np.linspace(0, 5000, 1001) |
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solution = odeint(myhc_model_odes, y0, t, args=(params,)) |
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return t, solution |
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def render_py3dmol(pdb_id, chain_styles, label_text, label_options, bg_color='0x1c1c1c'): |
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view = py3Dmol.view(query=f'pdb:{pdb_id}', width='100%', height=400) |
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for chain, style in chain_styles.items(): |
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view.setStyle({chain: chain}, style) |
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view.addLabel(label_text, {'fontColor':'white', 'backgroundColor':'#333333', 'fontSize':16, **label_options.get('style', {})}, label_options.get('position', {})) |
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view.setBackgroundColor(bg_color) |
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view.zoomTo() |
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html_string = view._make_html() |
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html(html_string, height=400) |
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st.title("TNF-α Mediated Cardiac Dysfunction: A Computational Analysis") |
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st.markdown("This application explores the findings of Manilall et al. (2023), who investigated how Tumor Necrosis Factor-alpha (TNF-α) mediates early-stage left ventricular (LV) systolic dysfunction. We replicate key findings and enhance the analysis with computational biology tools.") |
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tab1, tab2 = st.tabs(["General Lab / Analysis", "AI & Machine Learning"]) |
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with tab1: |
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st.header("Visual and Systems Biology Analysis") |
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st.markdown("---") |
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with st.container(): |
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st.subheader("3D Visualization of the Mediator: TNF-α") |
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st.write("TNF-α is a cytokine crucial to the immune response. In chronic inflammatory conditions, its elevated levels can have damaging effects. It typically functions as a homotrimer (a complex of three identical protein chains). We visualize the PDB structure 1TNF.") |
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chain_styles_tnf = { |
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'A': {'cartoon': {'color': 'salmon'}}, |
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'B': {'cartoon': {'color': 'lightblue'}}, |
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'C': {'cartoon': {'color': 'lightgreen'}} |
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} |
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render_py3dmol('1TNF', chain_styles_tnf, "TNF-α Trimer", {'position': {'resi': 50, 'chain': 'A'}}) |
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st.markdown("---") |
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with st.container(): |
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st.subheader("The Molecular Target: Myosin Heavy Chain (MyHC)") |
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st.write("The study's central finding is a TNF-α-induced switch from the faster α-MyHC (`Myh6`) to the slower β-MyHC (`Myh7`), impairing heart function. We visualize the human cardiac myosin motor domain (PDB: 5N6A).") |
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myosin_tab1, myosin_tab2 = st.tabs(["3D Model", "Functional Info"]) |
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with myosin_tab1: |
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chain_styles_myosin = { |
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'protein': {'cartoon': {'color':'#A9A9A9'}}, |
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} |
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view = py3Dmol.view(query='pdb:5N6A', width='100%', height=450) |
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view.setStyle({'cartoon': {'color':'#A9A9A9'}}) |
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view.addStyle({'resn': 'ADP'}, {'stick': {'colorscheme': 'magentaCarbon'}}) |
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view.addStyle({'resn': 'MG'}, {'sphere': {'color': 'purple'}}) |
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view.addLabel("Myosin Motor Domain", {'fontColor':'white', 'backgroundColor':'#333333'}, {'resi': 1, 'chain': 'A'}) |
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view.addLabel("ADP (Energy)", {'fontColor':'magenta'}, {'resn': 'ADP'}) |
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view.setBackgroundColor('0x1c1c1c') |
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view.zoomTo() |
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html(view._make_html(), height=450) |
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with myosin_tab2: |
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st.info(""" |
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**α-MyHC (Myh6) Function:** Major contractile protein in the atria. In the ventricle, it is the predominant isoform in small mammals and in fetal human heart but it is replaced by MYH7 after birth. Contributes to cardiac muscle contraction. |
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**β-MyHC (Myh7) Function:** Muscle contraction. The major contractile protein in the ventricular myocardium. |
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""") |
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st.markdown("---") |
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with st.container(): |
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st.subheader("Integrated Heatmap of Key Study Findings") |
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st.write("A heatmap consolidating data on inflammation, cardiac function, and gene expression. The anti-TNF-α treatment clearly reverses the pathological changes seen in the CIA group.") |
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data = { |
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'Circulating TNF-α (pg/mL)': [93.9, 155.8, 145.6], |
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'Global Longitudinal Strain (%)': [-19.6, -16.7, -19.0], |
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'Myh6 mRNA (α-MyHC)': [1.03, 0.89, 1.11], |
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'Myh7 mRNA (β-MyHC)': [0.96, 1.25, 0.91], |
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'Myh6/Myh7 Ratio': [1.13, 0.79, 1.24], |
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'IL-6 mRNA': [0.79, 1.65, 1.15] |
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} |
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df_heatmap = pd.DataFrame(data, index=['Control', 'CIA', 'CIA+anti-TNF-α']) |
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df_normalized = (df_heatmap - df_heatmap.mean()) / df_heatmap.std() |
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fig_heatmap = px.imshow(df_normalized.T, |
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text_auto=True, |
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aspect="auto", |
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color_continuous_scale='RdBu_r', |
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labels=dict(x="Experimental Group", y="Parameter", color="Normalized Value"), |
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x=df_heatmap.index, |
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y=df_heatmap.columns) |
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fig_heatmap.update_layout( |
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title_text='Integrated Heatmap of Key Study Findings', |
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title_x=0.5, |
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height=600, |
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xaxis_title='Experimental Group', |
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yaxis_title='Parameter', |
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paper_bgcolor=BACKGROUND_COLOR, |
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plot_bgcolor=PLOT_FACE_COLOR, |
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font=dict(color=TEXT_COLOR), |
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coloraxis_colorbar=dict(title="Normalized Value", thicknessmode="pixels", thickness=20, lenmode="pixels", len=300) |
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) |
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fig_heatmap.update_traces(text=df_heatmap.T.values.round(2), texttemplate="%{text}", hovertemplate="<b>%{y}</b><br>Group: %{x}<br>Value: %{text}<extra></extra>") |
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st.plotly_chart(fig_heatmap, use_container_width=True) |
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st.markdown("---") |
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with st.container(): |
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st.subheader("Simulating the TNF-α Signaling Pathway") |
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st.write("A simplified computational model to simulate the paper's central hypothesis: increased TNF-α leads to a decrease in the Myh6/Myh7 ratio over time.") |
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t, solution = run_ode_simulation() |
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MyHC_alpha = solution[:, 9] |
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MyHC_beta = solution[:, 10] |
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TF_active_total = solution[:, 4] + solution[:, 6] + solution[:, 8] |
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fig_sim = make_subplots(rows=2, cols=1, |
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shared_xaxes=True, |
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vertical_spacing=0.1, |
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subplot_titles=("Simulated MyHC Isoform Switch Induced by TNF-α", "Transcription Factor Dynamics")) |
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fig_sim.add_trace(go.Scatter(x=t, y=MyHC_alpha, mode='lines', name='α-MyHC (Myh6)', |
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line=dict(color='blue', width=2)), |
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row=1, col=1) |
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fig_sim.add_trace(go.Scatter(x=t, y=MyHC_beta, mode='lines', name='β-MyHC (Myh7)', |
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line=dict(color='red', width=2, dash='dash')), |
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row=1, col=1) |
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fig_sim.update_yaxes(title_text='MyHC Protein Level (Arbitrary Units)', row=1, col=1) |
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fig_sim.update_xaxes(title_text='Time (Arbitrary Units)', row=1, col=1, showticklabels=False) |
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fig_sim.add_trace(go.Scatter(x=t, y=solution[:, 2], mode='lines', name='TNF-α:TNFR Complex', |
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line=dict(color='green', width=2)), |
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row=2, col=1) |
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fig_sim.add_trace(go.Scatter(x=t, y=TF_active_total, mode='lines', name='Active TF (Total)', |
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line=dict(color='orange', width=2)), |
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row=2, col=1) |
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fig_sim.update_yaxes(title_text='Concentration (Arbitrary Units)', row=2, col=1) |
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fig_sim.update_xaxes(title_text='Time (Arbitrary Units)', row=2, col=1) |
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fig_sim.update_layout( |
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height=700, |
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paper_bgcolor=BACKGROUND_COLOR, |
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plot_bgcolor=PLOT_FACE_COLOR, |
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font=dict(color=TEXT_COLOR), |
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legend=dict(x=1.02, y=1, yanchor="top", xanchor="left", bgcolor='rgba(0,0,0,0)'), |
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margin=dict(l=40, r=40, t=80, b=40) |
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) |
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st.plotly_chart(fig_sim, use_container_width=True) |
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st.markdown("---") |
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with st.container(): |
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st.subheader("Network Analysis of Pathological Relationships") |
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st.write("A high-level overview of the proposed pathophysiology, from inflammation to systolic dysfunction.") |
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G = nx.DiGraph() |
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nodes_data = [ |
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("Systemic Inflammation\n(CIA Model)", 'red', 3500, 0.0), ("↑ Circulating TNF-α", 'orange', 3500, 0.5), |
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("↓ Myh6/Myh7 Ratio", 'purple', 3500, 0.5), ("Impaired Systolic Function\n(↓ Strain & Velocity)", 'darkred', 4000, -0.5), |
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("↑ IL-6 Expression", 'gold', 3000, 0.5), ("Anti-TNF-α\nTreatment", 'green', 3000, 1.0) |
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] |
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for name, color, size, z in nodes_data: |
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G.add_node(name, color=color, size=size, z=z) |
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G.add_edge("Systemic Inflammation\n(CIA Model)", "↑ Circulating TNF-α") |
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G.add_edge("↑ Circulating TNF-α", "↓ Myh6/Myh7 Ratio", label="mediates") |
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G.add_edge("↑ Circulating TNF-α", "↑ IL-6 Expression", label="mediates") |
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G.add_edge("↓ Myh6/Myh7 Ratio", "Impaired Systolic Function\n(↓ Strain & Velocity)", label="underlies") |
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G.add_edge("Anti-TNF-α\nTreatment", "↓ Myh6/Myh7 Ratio", label="prevents", type='inhibit') |
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G.add_edge("Anti-TNF-α\nTreatment", "Impaired Systolic Function\n(↓ Strain & Velocity)", label="prevents", type='inhibit') |
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pos_2d = nx.spring_layout(G, k=1.8, seed=42) |
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node_trace = go.Scatter3d( |
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x=[pos_2d[node][0] for node in G.nodes()], y=[pos_2d[node][1] for node in G.nodes()], z=[G.nodes[node]['z'] for node in G.nodes()], |
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mode='markers+text', |
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marker=dict(size=[G.nodes[node]['size']/300 for node in G.nodes()], color=[G.nodes[node]['color'] for node in G.nodes()], opacity=0.9), |
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text=list(G.nodes()), textposition="top center", textfont=dict(size=10, color=TEXT_COLOR), name="Nodes" |
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) |
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edge_traces = [] |
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for edge in G.edges(): |
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x0, y0 = pos_2d[edge[0]]; x1, y1 = pos_2d[edge[1]] |
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z0, z1 = G.nodes[edge[0]]['z'], G.nodes[edge[1]]['z'] |
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color = 'green' if G.edges[edge].get('type') == 'inhibit' else TEXT_COLOR |
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dash = 'dash' if G.edges[edge].get('type') == 'inhibit' else 'solid' |
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edge_trace = go.Scatter3d(x=[x0, x1, None], y=[y0, y1, None], z=[z0, z1, None], mode='lines', line=dict(color=color, width=4, dash=dash), showlegend=False) |
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edge_traces.append(edge_trace) |
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fig_3d = go.Figure(data=[node_trace] + edge_traces) |
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fig_3d.update_layout( |
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title="Interactive 3D Network", |
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height=600, |
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scene=dict(xaxis_title="X", yaxis_title="Y", zaxis_title="Hierarchy", |
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xaxis=dict(showbackground=False, visible=False), |
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yaxis=dict(showbackground=False, visible=False), |
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zaxis=dict(showbackground=False, visible=False)), |
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paper_bgcolor=BACKGROUND_COLOR, |
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plot_bgcolor=BACKGROUND_COLOR, |
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font=dict(color=TEXT_COLOR), |
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showlegend=False, |
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margin=dict(l=0, r=0, b=0, t=40) |
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) |
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st.plotly_chart(fig_3d, use_container_width=True) |
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with tab2: |
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st.header("AI & Machine Learning Insights") |
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st.markdown("---") |
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df_ml = generate_ml_data() |
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model, X_train, X_test, y_train, y_test = train_model(df_ml) |
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with st.container(): |
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st.subheader("Predictive Modeling: Can Biomarkers Predict Dysfunction?") |
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st.write("We train a Gradient Boosting model to predict systolic dysfunction based on TNF-α levels and the Myh6/Myh7 ratio. Below is the model's performance on the test dataset.") |
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y_pred = model.predict(X_test) |
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col1, col2 = st.columns(2) |
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with col1: |
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st.text("Classification Report") |
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report = classification_report(y_test, y_pred, target_names=['Normal', 'Dysfunction'], output_dict=True) |
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st.dataframe(pd.DataFrame(report).transpose()) |
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|
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with col2: |
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cm = confusion_matrix(y_test, y_pred, labels=model.classes_) |
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fig_cm = px.imshow(cm, |
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text_auto=True, |
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labels=dict(x="Predicted", y="True", color="Count"), |
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x=['Normal', 'Dysfunction'], |
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y=['Normal', 'Dysfunction'], |
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color_continuous_scale='Blues') |
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|
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fig_cm.update_layout( |
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title_text='Confusion Matrix', |
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|
title_x=0.5, |
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|
xaxis_title="Predicted Label", |
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|
yaxis_title="True Label", |
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|
paper_bgcolor=BACKGROUND_COLOR, |
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|
plot_bgcolor=PLOT_FACE_COLOR, |
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|
font=dict(color=TEXT_COLOR) |
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|
) |
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|
st.plotly_chart(fig_cm, use_container_width=True) |
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|
st.markdown("---") |
|
|
|
|
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|
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|
with st.container(): |
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|
st.subheader("Traditional Feature Importance") |
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|
st.write("Here, we visualize the importance of each feature as determined by the Gradient Boosting model. Features with higher importance contribute more significantly to the model's predictions.") |
|
|
|
|
|
|
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|
feature_importances = pd.DataFrame({ |
|
|
'Feature': X_train.columns, |
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|
'Importance': model.feature_importances_ |
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|
}).sort_values('Importance', ascending=False) |
|
|
|
|
|
|
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|
fig_importance = px.bar(feature_importances, |
|
|
x='Importance', |
|
|
y='Feature', |
|
|
orientation='h', |
|
|
title='Feature Importance from Gradient Boosting Model', |
|
|
color_discrete_sequence=[ACCENT_COLOR]) |
|
|
|
|
|
fig_importance.update_layout( |
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|
paper_bgcolor=BACKGROUND_COLOR, |
|
|
plot_bgcolor=PLOT_FACE_COLOR, |
|
|
font=dict(color=TEXT_COLOR), |
|
|
xaxis_title='Importance', |
|
|
yaxis_title='Feature', |
|
|
yaxis={'categoryorder':'total ascending'} |
|
|
) |
|
|
|
|
|
st.plotly_chart(fig_importance, use_container_width=True) |
|
|
|
|
|
st.markdown("---") |
|
|
|
|
|
with st.container(): |
|
|
st.subheader("Unsupervised Learning: Identifying Patient Subgroups") |
|
|
st.write("K-Means clustering can identify natural groupings in the data without predefined labels. This technique could help discover patient subgroups in a real clinical dataset. The clusters found here align well with the original experimental groups (Control, CIA, Treated).") |
|
|
|
|
|
X_cluster = df_ml[['TNF_alpha', 'MyHC_Ratio']] |
|
|
scaler = StandardScaler() |
|
|
X_scaled = scaler.fit_transform(X_cluster) |
|
|
kmeans = KMeans(n_clusters=3, random_state=42, n_init=10) |
|
|
df_ml['Cluster'] = kmeans.fit_predict(X_scaled).astype(str) |
|
|
|
|
|
centroids = scaler.inverse_transform(kmeans.cluster_centers_) |
|
|
centroids_df = pd.DataFrame(centroids, columns=['TNF_alpha', 'MyHC_Ratio']) |
|
|
centroids_df['Cluster'] = ['Centroid 0', 'Centroid 1', 'Centroid 2'] |
|
|
|
|
|
fig_cluster = px.scatter( |
|
|
df_ml, x='TNF_alpha', y='MyHC_Ratio', color='Cluster', |
|
|
color_discrete_sequence=px.colors.qualitative.Vivid, |
|
|
title='K-Means Clustering of Biomarker Data', |
|
|
labels={'TNF_alpha': 'Circulating TNF-α (pg/mL)', 'MyHC_Ratio': 'Myh6/Myh7 Ratio'} |
|
|
) |
|
|
|
|
|
fig_cluster.add_trace( |
|
|
go.Scatter( |
|
|
x=centroids_df['TNF_alpha'], |
|
|
y=centroids_df['MyHC_Ratio'], |
|
|
mode='markers', |
|
|
marker=dict(symbol='x', size=15, color='red', line=dict(width=2, color='darkred')), |
|
|
name='Centroids', |
|
|
showlegend=True |
|
|
) |
|
|
) |
|
|
|
|
|
|
|
|
fig_cluster.update_layout( |
|
|
paper_bgcolor=BACKGROUND_COLOR, |
|
|
plot_bgcolor=PLOT_FACE_COLOR, |
|
|
font=dict(color=TEXT_COLOR), |
|
|
xaxis_title='Circulating TNF-α (pg/mL)', |
|
|
yaxis_title='Myh6/Myh7 Ratio', |
|
|
height=600, |
|
|
width=600, |
|
|
showlegend=True |
|
|
) |
|
|
st.plotly_chart(fig_cluster, use_container_width=True) |
|
|
|
