AI-based Hepatic Steatosis Detection and Integrated Hepatic Assessment from Cardiac CT Attenuation Scans Enhances All-cause Mortality Risk Stratification: A Multi-center Study

  1. Jirong Yi
  2. Krishna Patel
  3. Robert JH Miller
  4. Anna M Marcinkiewicz
  5. Aakash Shanbhag
  6. Waseem Hijazi
  7. Naga Dharmavaram
  8. Mark Lemley
  9. Jianhang Zhou
  10. Wenhao Zhang
  11. Joanna X Liang
  12. Giselle Ramirez
  13. Valerie Builoff
  14. Leandro Slipczuk
  15. Mark Travin
  16. Erick Alexanderson
  17. Isabel Carvajal-Juarez
  18. Rene RS Packard
  19. Mouaz Al-Mallah
  20. Terrence D Ruddy
  21. Andrew J Einstein
  22. Attila Feher
  23. Edward J Miller
  24. Wanda Acampa
  25. Stacey Knight
  26. Viet Le
  27. Steve Mason
  28. Vinicius F Calsavara
  29. Panithaya Chareonthaitawee
  30. Samuel Wopperer
  31. Alan Chin Kwan
  32. Lixia Wang
  33. Daniel S Berman
  34. Damini Dey
  35. Marcelo F Di Carli
  36. Piotr Slomka
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Abstract

Background: Hepatic steatosis (HS) is a common cardiometabolic risk factor frequently present but under-diagnosed in patients with suspected or known coronary artery disease. We used artificial intelligence (AI) to automatically quantify hepatic tissue measures for identifying HS from CT attenuation correction (CTAC) scans during myocardial perfusion imaging (MPI) and evaluate their added prognostic value for all-cause mortality prediction. Methods: This study included 27039 consecutive patients [57% male] with MPI scans from nine sites. We used an AI model to segment liver and spleen on low dose CTAC scans and quantify the liver measures, and the difference of liver minus spleen (LmS) measures. HS was defined as mean liver attenuation < 40 Hounsfield units (HU) or LmS attenuation < -10 HU. Additionally, we used seven sites to develop an AI liver risk index (LIRI) for comprehensive hepatic assessment by integrating the hepatic measures and two external sites to validate its improved prognostic value and generalizability for all-cause mortality prediction over HS. Findings: Median (interquartile range [IQR]) age was 67 [58, 75] years and body mass index (BMI) was 29.5 [25.5, 34.7] kg/m2, with diabetes in 8950 (33%) patients. The algorithm identified HS in 6579 (24%) patients. During median [IQR] follow-up of 3.58 [1.86, 5.15] years, 4836 (18%) patients died. HS was associated with increased mortality risk overall (adjusted hazard ratio (HR): 1.14 [1.05, 1.24], p=0.0016) and in subpopulations. LIRI provided higher prognostic value than HS after adjustments overall (adjusted HR 1.5 [1.32, 1.69], p<0.0001 vs HR 1.16 [1.02, 1.31], p=0.0204) and in subpopulations. Interpretations: AI-based hepatic measures automatically identify HS from CTAC scans in patients undergoing MPI without additional radiation dose or physician interaction. Integrated liver assessment combining multiple hepatic imaging measures improved risk stratification for all-cause mortality. Funding: National Heart, Lung, and Blood Institute/National Institutes of Health.

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  1. Version published to 10.1101/2025.06.09.25329157v2 on medRxiv
  2. Version published to 10.1101/2025.06.09.25329157v1 on medRxiv