Point-of-care detection of fibrosis in liver transplant surgery using near-infrared spectroscopy and machine learning

Varun J Sharma; John A Adegoke; Michael Fasulakis; Alexander Green; Su K Goh; Xiuwen Peng; Yifan Liu; Louise Jackett; Angela Vago; Eric K W Poon; Graham Starkey; Sarina Moshfegh; Ankita Muthya; Rohit D'Costa; Fiona James; Claire L Gordon; Robert Jones; Isaac O Afara; Bayden R Wood; Jaishankar Raman

doi:10.1002/hsr2.1652

Point-of-care detection of fibrosis in liver transplant surgery using near-infrared spectroscopy and machine learning

Health Sci Rep. 2023 Oct 31;6(11):e1652. doi: 10.1002/hsr2.1652. eCollection 2023 Nov.

Authors

Varun J Sharma^{1

2}, John A Adegoke³, Michael Fasulakis⁴, Alexander Green³, Su K Goh^{1

5}, Xiuwen Peng⁴, Yifan Liu⁴, Louise Jackett⁶, Angela Vago^{1

5}, Eric K W Poon⁷, Graham Starkey^{1

5}, Sarina Moshfegh¹, Ankita Muthya¹, Rohit D'Costa^{8

9}, Fiona James¹⁰, Claire L Gordon^{7

10}, Robert Jones^{1

5}, Isaac O Afara^{11

12}, Bayden R Wood³, Jaishankar Raman^{1

2}

Affiliations

¹ Department of Surgery, Melbourne Medical School University of Melbourne Melbourne Victoria Australia.
² Brian F. Buxton Department of Cardiac and Thoracic Aortic Surgery Austin Hospital Melbourne Victoria Australia.
³ Centre for Biospectroscopy Monash University Melbourne Victoria Australia.
⁴ Department of Engineering University of Melbourne Melbourne Victoria Australia.
⁵ Liver & Intestinal Transplant Unit Austin Health Melbourne Victoria Australia.
⁶ Department of Anatomical Pathology Austin Health Melbourne Victoria Australia.
⁷ Department of Microbiology and Immunology, Peter Doherty Institute for Infection and Immunity University of Melbourne Melbourne Victoria Australia.
⁸ DonateLife Victoria Carlton Victoria Australia.
⁹ Department of Intensive Care Medicine Melbourne Health Melbourne Victoria Australia.
¹⁰ Department of Infectious Diseases Austin Health Melbourne Victoria Australia.
¹¹ School of Information Technology and Electrical Engineering Faculty of Engineering, Architecture, and Information Technology Brisbane Queensland Australia.
¹² Biomedical Spectroscopy Laboratory, Department of Applied Physics University of Eastern Finland Kuopio Finland.

Abstract

Introduction: Visual assessment and imaging of the donor liver are inaccurate in predicting fibrosis and remain surrogates for histopathology. We demonstrate that 3-s scans using a handheld near-infrared-spectroscopy (NIRS) instrument can identify and quantify fibrosis in fresh human liver samples.

Methods: We undertook NIRS scans on 107 samples from 27 patients, 88 from 23 patients with liver disease, and 19 from four organ donors.

Results: Liver disease patients had a median immature fibrosis of 40% (interquartile range [IQR] 20-60) and mature fibrosis of 30% (10%-50%) on histopathology. The organ donor livers had a median fibrosis (both mature and immature) of 10% (IQR 5%-15%). Using machine learning, this study detected presence of cirrhosis and METAVIR grade of fibrosis with a classification accuracy of 96.3% and 97.2%, precision of 96.3% and 97.0%, recall of 96.3% and 97.2%, specificity of 95.4% and 98.0% and area under receiver operator curve of 0.977 and 0.999, respectively. Using partial-least square regression machine learning, this study predicted the percentage of both immature (R ² = 0.842) and mature (R ² = 0.837) with a low margin of error (root mean square of error of 9.76% and 7.96%, respectively).

Conclusion: This study demonstrates that a point-of-care NIRS instrument can accurately detect, quantify and classify liver fibrosis using machine learning.

Keywords: chemometrics; liver; near‐infrared spectroscopy; spectromics; transplant; vibrational spectroscopy.