Abstract

First-line treatment for small-cell lung cancer (SCLC) involves platinum-based chemotherapy and immunotherapy for extensive (ES) and limited (LM) disease, respectively. Rapid progression and metastasis highlight the need for improved biomarkers. We developed PhenopyCell, a computational pathology tool that quantifies immune-tumor spatial architecture on Hematoxylin and Eosin (H&E) slides to predict outcomes. Developing PhenopyCell for spatial quantification of immune-tumor interactions and clinical outcome prediction. Retrospective study of 281 SCLC patients (149 LM, 132 ES) treated with platinum chemotherapy (2010-2020) from multi-institutional archives, divided into training (D1, n = 101) and validation (D2/D3, n = 180) cohorts. PhenopyCell extracted 101 spatial features (immune clustering, tumor density) from whole-slide images. Overall survival (OS) via Cox models and chemotherapy response through ROC and precision-recall analyses. PhenopyCell-derived features correlated with OS and treatment response across datasets (D₁ HR = 1.66, P = 0.036; D₂ HR = 1.98, P = 0.04; D₃ HR = 2.13, P = 0.04). Stratified analyses showed strong prognostic value for both ES-SCLC (HR up to 5.11) and LM-SCLC (HR up to 34.91). Chemotherapy response prediction achieved AUCs of 0.62-0.79. PhenopyCell independently predicts survival and therapy response in SCLC, outperforming conventional histopathology and supporting personalized treatment approaches.

EDRN PI Authors

• (None specified)

Medline Author List

• Barrera C
• Beshai B
• Corredor G
• Dam T
• Dowlati A
• Higgins K
• Jagirdar J
• Jain P
• Madabhushi A
• Maurya H
• Pathak T
• Perimbeti S

PubMed ID

Appears In

NPJ Precis Oncol, 2026 Mar (issue 1)