367-06-003 ISMRM Abstract

Application of Renal Pseudo-Continuous Arterial Spin Labeling Radiomics in Early Diagnosis and Staging of Chronic Kidney Dise

Primary: Body - Kidney

Secondary: Body - Urogenital

367-06-003 · Advanced Methods in Renal MRI · Monday, 11 May, 5:05 PM–6:00 PM · Digital Posters Row H

Keywords: Radiomics Deep learning Chronic Kidney Disease Nomogram Pseudocontinuous Arterial Spin Labeling

Accepted

Haiyun Xu ¹, Wei Mao², Fang Lu³, Caixia Fu⁴, Bernd Kuehn⁵, Guang Yang⁶, Shuohui Yang¹

¹Department of Radiology, Shanghai Municipal Hospital of Traditional Chinese Medicine, Shanghai University of Traditional Chinese Medicine, Shanghai, China

²Zhongshan Hospital, Fudan University, Shanghai Institute of Medical Imaging, Shanghai, China

³Shuguang Hospital Affiliated to Shanghai University of Traditional Chinese Medicine, Shanghai, China

⁴MR Application Development, Siemens Shenzhen Magnetic Resonance Ltd., Shenzhen, China

⁵Research & Clinical Translation, Magnetic Resonance, Siemens Healthineers AG, Erlangen, Germany

⁶Shanghai Key Laboratory of Magnetic Resonance, Shanghai, China

Presenting Author: Haiyun Xu

Synopsis

Motivation:

Goals:

Approach:

Results:

Full abstract & presentation

The full text, figures, and any recorded presentation for this abstract are not shown here. Log in if you are a member or registered attendee with access.

Full abstracts, figures, and presentations for Cape Town - 2026 ISMRM-ISMRT Annual Meeting and Exhibition are available to registered attendees. This content becomes freely available to the public roughly two years after the meeting.

To request or purchase access, contact the ISMRM Central Office at info@ismrm.org.

References

1. Lameire NH, Levin A, Kellum JA, et al. Harmonizing acute and chronic kidney disease definition and classification: report of a Kidney Disease: Improving Global Outcomes (KDIGO) Consensus Conference. Kidney international. 2021;100(3):516-26.

2. Foreman KJ, Marquez N, Dolgert A, et al. Forecasting life expectancy, years of life lost, and all-cause and cause-specific mortality for 250 causes of death: reference and alternative scenarios for 2016-40 for 195 countries and territories. Lancet (London, England). 2018;392(10159):2052-90.

3. Succar L, Pianta TJ, Davidson T, et al. Subclinical chronic kidney disease modifies the diagnosis of experimental acute kidney injury. Kidney international. 2017;92(3):680-92.

4. Kim DW, Shim WH, Yoon SK, et al. Measurement of arterial transit time and renal blood flow using pseudocontinuous ASL MRI with multiple post-labeling delays: Feasibility, reproducibility, and variation. Journal of magnetic resonance imaging : JMRI. 2017;46(3):813-9.

5. Gillis KA, McComb C, Foster JE, et al. Inter-study reproducibility of arterial spin labelling magnetic resonance imaging for measurement of renal perfusion in healthy volunteers at 3 Tesla. BMC nephrology. 2014;15:23.

6. Artz NS, Sadowski EA, Wentland AL, et al. Reproducibility of renal perfusion MR imaging in native and transplanted kidneys using non-contrast arterial spin labeling. Journal of magnetic resonance imaging : JMRI. 2011;33(6):1414-21.

7. Odudu A, Nery F, Harteveld AA, et al. Arterial spin labelling MRI to measure renal perfusion: a systematic review and statement paper. Nephrology, dialysis, transplantation : official publication of the European Dialysis and Transplant Association - European Renal Association. 2018;33(suppl_2):ii15-ii21.

8. Lu F, Yang J, Yang S, et al. Use of Three-Dimensional Arterial Spin Labeling to Evaluate Renal Perfusion in Patients With Chronic Kidney Disease. Journal of magnetic resonance imaging : JMRI. 2021;54(4):1152-63.

9. Gillis KA, McComb C, Patel RK, et al. Non-Contrast Renal Magnetic Resonance Imaging to Assess Perfusion and Corticomedullary Differentiation in Health and Chronic Kidney Disease. Nephron. 2016;133(3):183-92.

10. Li LP, Tan H, Thacker JM, et al. Evaluation of Renal Blood Flow in Chronic Kidney Disease Using Arterial Spin Labeling Perfusion Magnetic Resonance Imaging. Kidney international reports. 2017;2(1):36-43.

11. Artz NS, Sadowski EA, Wentland AL, et al. Arterial spin labeling MRI for assessment of perfusion in native and transplanted kidneys. Magnetic resonance imaging. 2011;29(1):74-82.

12. Brown RS, Sun MRM, Stillman IE, et al. The utility of magnetic resonance imaging for noninvasive evaluation of diabetic nephropathy. Nephrology, dialysis, transplantation : official publication of the European Dialysis and Transplant Association - European Renal Association. 2020;35(6):970-8.

13. Chen X, Wang X, Zhang K, et al. Recent advances and clinical applications of deep learning in medical image analysis. Medical image analysis. 2022;79:102444.

14. Isensee F, Jaeger PF, Kohl SAA, et al. nnU-Net: a self-configuring method for deep learning-based biomedical image segmentation. Nature methods. 2021;18(2):203-11.

15. Singla R, Ringstrom C, Hu R, et al. Automatic measurement of kidney dimensions in two-dimensional ultrasonography is comparable to expert sonographers. Journal of medical imaging (Bellingham, Wash). 2023;10(3):034003.

16. Luo H, Li J, Huang H, et al. AI-based segmentation of renal enhanced CT images for quantitative evaluate of chronic kidney disease. Scientific reports. 2024;14(1):16890.

17. Zhang H, Botler M, Kooman JP. Deep Learning for Image Analysis in Kidney Care. Advances in kidney disease and health. 2023;30(1):25-32.

18. Tian S, Yu Y, Shi K, et al. Deep learning radiomics based on ultrasound images for the assisted diagnosis of chronic kidney disease. Nephrology (Carlton, Vic). 2024;29(11):748-57.

19. Ge XY, Lan ZK, Lan QQ, et al. Diagnostic accuracy of ultrasound-based multimodal radiomics modeling for fibrosis detection in chronic kidney disease. European radiology. 2023;33(4):2386-98.

20. Pruijm M, Milani B, Pivin E, et al. Reduced cortical oxygenation predicts a progressive decline of renal function in patients with chronic kidney disease. Kidney international. 2018;93(4):932-40.

Cite this abstract

http://echo.ismrm.org/p/ISMRM2026/367-06-003