QVT Score, a radiomic biomarker of vascular complexity, enables prognostication and monitoring of NSCLC immunotherapy

  1. Young Kwae Chae
  2. Vamsidhar Velcheti
  3. Kai Zhang
  4. Amogh Hiremath
  5. Liam Il-Young Chung
  6. Omid Haji-Maghsoudi
  7. Rhea Chitalia
  8. Jeeyeon Lee
  9. Haojia Li
  10. Seyoung Lee
  11. Pushkar Mutha
  12. Rushil Nagabhushan
  13. David Levy
  14. Diego Cantor
  15. Yuchan Kim
  16. Peter Haseok Kim
  17. Amit Gupta
  18. Trishan Arul
  19. Anant Madabhushi
  20. Nathaniel Braman
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Abstract

Background

Immune checkpoint inhibitors (ICIs) improve survival in advanced non-small cell lung cancer (NSCLC), yet current biomarkers such as PD-L1 expression and response criteria (RECIST v1.1) align poorly with long-term survival. Radiomics has been proposed as a source of novel biomarkers, but standard radiomic approaches suffer from limited biological interpretability and poor generalizability across treatment settings. We address these gaps by developing the Quantitative Vessel Tortuosity (QVT) Score, a biologically interpretable imaging biomarker that quantifies tumor vascular complexity -a known mediator of immune evasion - from routine imaging. We hypothesized that QVT Score would improve prognostication and enable treatment response monitoring in ICI-treated NSCLC, independent of current biomarkers.

Methods

This retrospective, multicenter study analyzed 1,301 CT scans from 682 ICI-treated NSCLC patients. An automated pipeline segmented lesions and tumor-associated vasculature within each scan, extracting 910 QVT features measuring vascular shape and complexity. Unsupervised clustering of these features in a discovery cohort (N=375) was performed to identify fundamental vascular phenotypes. A continuous QVT score was then derived using regularized logistic regression to map patients along this phenotypic spectrum. QVT Score was externally validated in ICI monotherapy (N=172) and chemoimmunotherapy (N=135) cohorts. In a longitudinal cohort (n=143), early on-treatment QVT Score changes were evaluated for overall survival (OS) association.

Results

Two robust vascular phenotypes emerged in the discovery cohort: a highly vascularized, chaotic “QVT High” phenotype with poor post-ICI OS and a “QVT Low” phenotype with normalized vasculature and improved ICI outcomes. The continuous QVT Score was prognostic for ICI monotherapy (HR = 1.17 per 0.1 increase, p = 0.0028) and chemoimmunotherapy (HR = 1.23 per 0.1 increase, p = 4.9×10⁻⁵). High QVT status remained prognostic for both treatments after adjustment for PD-L1 and clinical variables (adjusted HR range: 2.13–2.38, p ≤ 0.002). Early decreases in QVT Score during therapy, indicating vascular normalization, were associated with improved OS (HR = 1.93, p = 0.0022) independent of RECIST best overall response and tumor volume change.

Conclusions

QVT Score is a novel, biologically interpretable imaging biomarker that quantifies vascular complexity. It enables automated, non-invasive prediction and monitoring of ICI outcomes by capturing treatment-induced vascular remodeling. Integrating QVT Score into clinical decision-making and drug development can address critical gaps in precision oncology.

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  1. Version published to 10.1101/2025.09.08.25335020 on medRxiv