Towards a point-of-care multimodal spectroscopy instrument for the evaluation of human cardiac tissue

Varun J Sharma; Alexander Green; Aaron McLean; John Adegoke; Claire L Gordon; Graham Starkey; Rohit D'Costa; Fiona James; Isaac Afara; Sean Lal; Bayden Wood; Jaishankar Raman

doi:10.1007/s00380-023-02292-3

Towards a point-of-care multimodal spectroscopy instrument for the evaluation of human cardiac tissue

Heart Vessels. 2023 Dec;38(12):1476-1485. doi: 10.1007/s00380-023-02292-3. Epub 2023 Aug 22.

Authors

Varun J Sharma^{1

2

3}, Alexander Green^{4

5}, Aaron McLean^{4

5}, John Adegoke^{4

5}, Claire L Gordon^{6

7

8}, Graham Starkey⁹, Rohit D'Costa^{10

11}, Fiona James^{6

8}, Isaac Afara¹², Sean Lal^{13

14}, Bayden Wood^{4

5}, Jaishankar Raman^{15

16

4}

Affiliations

¹ Department of Surgery, Melbourne Medical School, University of Melbourne, Melbourne, Australia. vjs.cts@gmail.com.
² Brian F. Buxton Department of Cardiac Surgery, Austin Hospital, Melbourne, Australia. vjs.cts@gmail.com.
³ Spectromix Laboratory, Melbourne, VIC, Australia. vjs.cts@gmail.com.
⁴ Spectromix Laboratory, Melbourne, VIC, Australia.
⁵ Monash Biospectroscopy, Monash University, Melbourne, Australia.
⁶ Department of Infectious Diseases, Austin Health, Melbourne, VIC, Australia.
⁷ Department of Microbiology and Immunology, The University of Melbourne, The Peter Doherty Institute for Infection and Immunity, Melbourne, VIC, Australia.
⁸ North Eastern Public Health Unit, Austin Health, Melbourne, VIC, Australia.
⁹ Liver Transplant Unit, Austin Hospital, Melbourne, Australia.
¹⁰ DonateLife Victoria, Carlton, Melbourne, VIC, Australia.
¹¹ Department of Intensive Care Medicine, Melbourne Health, Melbourne, VIC, Australia.
¹² School of Information Technology and Electrical Engineering, The University of Queensland, Brisbane, Australia.
¹³ Department of Cardiology, Royal Prince Alfred Hospital, Sydney, Australia.
¹⁴ Faculty of Medicine and Health, University of Sydney, Sydney, NSW, Australia.
¹⁵ Department of Surgery, Melbourne Medical School, University of Melbourne, Melbourne, Australia.
¹⁶ Brian F. Buxton Department of Cardiac Surgery, Austin Hospital, Melbourne, Australia.

Abstract

To demonstrate that point-of-care multimodal spectroscopy using Near-Infrared (NIR) and Raman Spectroscopy (RS) can be used to diagnose human heart tissue. We generated 105 spectroscopic scans, which comprised 4 NIR and 3 RS scans per sample to generate a "multimodal spectroscopic scan" (MSS) for each heart, done across 15 patients, 5 each from the dilated cardiomyopathy (DCM), Ischaemic Heart Disease (IHD) and Normal pathologies. Each of the MSS scans was undertaken in 3 s. Data were entered into machine learning (ML) algorithms to assess accuracy of MSS in diagnosing tissue type. The median age was 50 years (IQR 49-52) for IHD, 47 (IQR 45-50) for DCM and 36 (IQR 33-52) for healthy patients (p = 0.35), 60% of which were male. MSS identified key differences in IHD, DCM and normal heart samples in regions typically associated with fibrosis and collagen (NIR wavenumbers: 1433, 1509, 1581, 1689 and 1725 nm; RS wavelengths: 1658, 1450 and 1330 cm^-1). In principal component (PC) analyses, these differences explained 99.2% of the variation in 4 PCs for NIR, 81.6% in 10 PCs for Raman, and 99.0% in 26 PCs for multimodal spectroscopic signatures. Using a stack machine learning algorithm with combined NIR and Raman data, our model had a precision of 96.9%, recall of 96.6%, specificity of 98.2% and Area Under Curve (AUC) of 0.989 (Table 1). NIR and Raman modalities alone had similar levels of precision at 94.4% and 89.8% respectively (Table 1). MSS combined with ML showed accuracy of 90% for detecting dilated cardiomyopathy, 100% for ischaemic heart disease and 100% for diagnosing healthy tissue. Multimodal spectroscopic signatures, based on NIR and Raman spectroscopy, could provide cardiac tissue scans in 3-s to aid accurate diagnoses of fibrosis in IHD, DCM and normal hearts. Table 1 Machine learning performance metrics for validation data sets of (a) Near-Infrared (NIR), (b) Raman and (c and d) multimodal data using logistic regression (LR), stochastic gradient descent (SGD) and support vector machines (SVM), with combined "stack" (LR + SGD + SVM) AUC Precision Recall Specificity (a) NIR model Logistic regression 0.980 0.944 0.933 0.967 SGD 0.550 0.281 0.400 0.700 SVM 0.840 0.806 0.800 0.900 Stack 0.933 0.794 0.800 0.900 (b) Raman model Logistic regression 0.985 0.940 0.929 0.960 SGD 0.892 0.869 0.857 0.932 SVM 0.992 0.940 0.929 0.960 Stack 0.954 0.869 0.857 0.932 (c) MSS: multimodal (NIR + Raman) to detect DCM vs. IHD vs. normal patients Logistic regression 0.975 0.841 0.828 0.917 SGD 0.847 0.803 0.793 0.899 SVM 0.971 0.853 0.828 0.917 Stack 0.961 0.853 0.828 0.917 (d) MSS: multimodal (NIR + Raman) to detect pathological vs. normal patients Logistic regression 0.961 0.969 0.966 0.984 SGD 0.944 0.967 0.966 0.923 SVM 1.000 1.000 1.000 1.000 Stack 1.000 0.944 0.931 0.969 Bold values indicate values obtained from the stack algorithm and used for analyses.

Keywords: Cardiomyopathy; Fibrosis; Point-of-care; Vibrational spectroscopy.

MeSH terms

Algorithms
Cardiomyopathy, Dilated* / diagnosis
Female
Fibrosis
Humans
Male
Middle Aged
Myocardial Ischemia*
Point-of-Care Systems
Spectroscopy, Near-Infrared / methods