lifelines

Complete survival analysis library in Python. Handles right-censored data, Kaplan-Meier curves, and Cox regression. Standard for clinical trial analysis and epidemiology.

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Install skill "lifelines" with this command: npx skills add tondevrel/scientific-agent-skills/tondevrel-scientific-agent-skills-lifelines

Lifelines - Survival Analysis

In medicine, we often care about "Time to Event" (death, recovery, relapse). Lifelines handles the complexity of "censored" data (patients who left the study).

When to Use

  • Analyzing clinical trial data (time to death, disease progression).
  • Comparing survival between treatment groups.
  • Identifying risk factors using Cox Proportional Hazards regression.
  • Building survival models for prognosis.
  • Epidemiology studies (time to infection, recovery).

Core Principles

Censoring

Patients who haven't experienced the event by the end of the study are "censored". Lifelines properly accounts for this.

Hazard Ratios

In Cox regression, a hazard ratio > 1 means increased risk; < 1 means decreased risk.

Survival Curves

Kaplan-Meier estimates the probability of survival over time without assuming a distribution.

Quick Reference

Standard Imports

from lifelines import KaplanMeierFitter, CoxPHFitter
from lifelines.statistics import logrank_test
import pandas as pd

Basic Patterns

# 1. Kaplan-Meier (Visualizing survival)
kmf = KaplanMeierFitter()
kmf.fit(durations=df['days'], event_observed=df['died'])
kmf.plot_survival_function()
kmf.median_survival_time_  # Time when 50% have died

# 2. Cox Proportional Hazards (Risk factors)
cph = CoxPHFitter()
cph.fit(df, duration_col='days', event_col='died')
cph.print_summary() # See hazard ratios for age, drug type, etc.
cph.plot_partial_effects_on_outcome(covariates=['age'], values=[30, 50, 70])

Critical Rules

✅ DO

  • Use event_observed correctly - 1 = event occurred, 0 = censored.
  • Check proportional hazards assumption - Use cph.check_assumptions() to validate Cox model.
  • Compare groups with logrank test - Statistical test for survival curve differences.
  • Plot confidence intervals - Survival estimates have uncertainty, especially with small samples.

❌ DON'T

  • Don't ignore censoring - Treating censored patients as "survived" biases results.
  • Don't use regular regression - Time-to-event data requires specialized methods.
  • Don't assume proportional hazards - If violated, use stratified Cox or parametric models.

Advanced Patterns

Comparing Multiple Groups

from lifelines.statistics import multivariate_logrank_test

# Compare survival across treatment groups
results = multivariate_logrank_test(df['days'], df['group'], df['died'])
print(results.p_value)

Parametric Models

from lifelines import WeibullFitter, ExponentialFitter

# When you need to extrapolate beyond observed data
wf = WeibullFitter()
wf.fit(df['days'], df['died'])
wf.plot()

Lifelines transforms complex survival data into actionable medical insights, enabling evidence-based decisions in clinical research and practice.

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