Abstract

ABSTRACT Hyperspectral imaging is one of the most promising techniques for intraoperative tissue characterisation. Snapshot mosaic cameras, which can capture hyperspectral data in a single exposure, have the potential to make a real-time hyperspectral imaging system for surgical decision-making possible. However, optimal exploitation of the captured data requires solving an ill-posed demosaicking problem and applying additional spectral corrections. In this work, we propose a supervised learning-based image demosaicking algorithm for snapshot hyperspectral images. Due to the lack of publicly available medical images acquired with snapshot mosaic cameras, a synthetic image generation approach is proposed to simulate snapshot images from existing medical image datasets captured by high-resolution, but slow, hyperspectral imaging devices. Image reconstruction is achieved using convolutional neural networks for hyperspectral image super-resolution, followed by spectral correction using a sensor-specific calibration matrix. The results are evaluated both quantitatively and qualitatively, showing clear improvements in image quality compared to a baseline demosaicking method using linear interpolation. Moreover, the fast processing time of 45 ms of our algorithm to obtain super-resolved RGB or oxygenation saturation maps per image for a state-of-the-art snapshot mosaic camera demonstrates the potential for its seamless integration into real-time surgical hyperspectral imaging applications.

Highlights

  • Reliable discrimination between tumour and surrounding tissues remains a challenging task in surgery and in particular in neuro-oncology surgery

  • Synthetic image generation and demosaicking were performed on the HELICoiD and Oral and Dental Spectral Image Database (ODSI-DB) datasets separately

  • We have proposed a hyperspectral snapshot image demosaicking algorithm for computer-assisted surgery using synthetic image generation and supervised learning

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Summary

Introduction

Reliable discrimination between tumour and surrounding tissues remains a challenging task in surgery and in particular in neuro-oncology surgery. Unlike fluorescence and ultrasound imaging, HSI exploits the inherent optical characteristics of different tissue types It captures the measurements of light which provide quantitative diagnostic information on tissue perfusion and oxygen saturation, enabling improved tissue characterisation relative to fluorescence and ultrasound imaging (Lu and Fei 2014). On the other hand, is able to capture the entire spatial scene at a certain wavelength with a 2D array detector, and switches to different wavelengths over time to complete scanning. These two types of spectral cameras are able to acquire hyperspectral data with high spatial and spectral resolution, but long acquisition times prevent them from providing live image displays suitable for real-time intraoperative use

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