Abstract

.Significance: The non-destructive characterization of cardiac tissue composition provides essential information for both planning and evaluating the effectiveness of surgical interventions such as ablative procedures. Although several methods of tissue characterization, such as optical coherence tomography and fiber-optic confocal microscopy, show promise, many barriers exist that reduce effectiveness or prevent adoption, such as time delays in analysis, prohibitive costs, and limited scope of application. Developing a rapid, low-cost non-destructive means of characterizing cardiac tissue could improve planning, implementation, and evaluation of cardiac surgical procedures.Aim: To determine whether a new light-scattering spectroscopy (LSS) system that analyzes spectra via neural networks is capable of predicting the nuclear densities (NDs) of ventricular tissues.Approach: We developed an LSS system with a fiber-optics probe and applied it for measurements on cardiac tissues from an ovine model. We quantified the ND in the cardiac tissues using fluorescent labeling, confocal microscopy, and image processing. Spectra acquired from the same cardiac tissues were analyzed with spectral clustering and convolutional neural networks (CNNs) to assess the feasibility of characterizing the ND of tissue via LSS.Results: Spectral clustering revealed distinct groups of spectra correlated to ranges of ND. CNNs classified three groups of spectra with low, medium, or high ND with an accuracy of (mean and standard deviation). Our analyses revealed the sensitivity of the classification accuracy to wavelength range and subsampling of spectra.Conclusions: LSS and machine learning are capable of assessing ND in cardiac tissues. We suggest that the approach is useful for the diagnosis of cardiac diseases associated with changes of ND, such as hypertrophy and fibrosis.

Highlights

  • Optical technologies for medical diagnosis have advanced rapidly over the last several decades

  • light-scattering spectroscopy (LSS) and machine learning are capable of assessing nuclear densities (NDs) in cardiac tissues

  • We suggest that the approach is useful for the diagnosis of cardiac diseases associated with changes of ND, such as hypertrophy and fibrosis

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Summary

Introduction

Optical technologies for medical diagnosis have advanced rapidly over the last several decades. Interaction of light with tissue for its in-vivo characterization and disease diagnosis—in effect replacing traditional biopsy based on tissue extraction These light-tissue interactions are leveraged for tissue characterization by various optical modalities, including fluorescence imaging, multi-photon microscopy, spectroscopy, and tomography. Fiber-optic confocal microscopy (FCM) and optical coherence tomography (OCT) are examples of optical technologies being explored for use in the heart.[1–4] These imaging modalities show promise in interventional cardiology and cardiac electrophysiology.[5]. Clinical studies and related research with FCM have shown the ability to identify conductive tissue regions during congenital heart surgery, e.g., the sinoatrial and atrioventricular nodes.[8,9] These technologies have been shown to provide useful information during cardiac procedures, the significant cost and technical complexity associated with their implementation hinder widespread adoption. Shallow imaging field depths limit the application of these technologies to only a few specific use cases in the heart.[10,11]

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