A deep learning methodology for the automated detection of end-diastolic frames in intravascular ultrasound images

Retesh Bajaj,Francesca Pugliese,Ajay Jain,Jouke Dijkstra,Anantharaman Ramasamy,Ryo Torii,Tat Koh,Vincenzo Tufaro,Yakup Kilic,Patrick W Serruys,Anthony Mathur,Maurizio K Parker,Xingru Huang,Tom Crake,James Moon,Andreas Baumbach,Christos V Bourantas,Qianni Zhang

doi:10.1007/s10554-021-02162-x

Abstract

Coronary luminal dimensions change during the cardiac cycle. However, contemporary volumetric intravascular ultrasound (IVUS) analysis is performed in non-gated images as existing methods to acquire gated or to retrospectively gate IVUS images have failed to dominate in research. We developed a novel deep learning (DL)-methodology for end-diastolic frame detection in IVUS and compared its efficacy against expert analysts and a previously established methodology using electrocardiographic (ECG)-estimations as reference standard. Near-infrared spectroscopy-IVUS (NIRS-IVUS) data were prospectively acquired from 20 coronary arteries and co-registered with the concurrent ECG-signal to identify end-diastolic frames. A DL-methodology which takes advantage of changes in intensity of corresponding pixels in consecutive NIRS-IVUS frames and consists of a network model designed in a bidirectional gated-recurrent-unit (Bi-GRU) structure was trained to detect end-diastolic frames. The efficacy of the DL-methodology in identifying end-diastolic frames was compared with two expert analysts and a conventional image-based (CIB)-methodology that relies on detecting vessel movement to estimate phases of the cardiac cycle. A window of ± 100 ms from the ECG estimations was used to define accurate end-diastolic frames detection. The ECG-signal identified 3,167 end-diastolic frames. The mean difference between DL and ECG estimations was 3 ± 112 ms while the mean differences between the 1st-analyst and ECG, 2nd-analyst and ECG and CIB-methodology and ECG were 86 ± 192 ms, 78 ± 183 ms and 59 ± 207 ms, respectively. The DL-methodology was able to accurately detect 80.4%, while the two analysts and the CIB-methodology detected 39.0%, 43.4% and 42.8% of end-diastolic frames, respectively (P < 0.05). The DL-methodology can identify NIRS-IVUS end-diastolic frames accurately and should be preferred over expert analysts and CIB-methodologies, which have limited efficacy.

Highlights

Intravascular ultrasound (IVUS) is the preferred intravascular imaging modality for the evaluation of coronary plaque burden and the efficacy of emerging therapies targeting1 3 Vol.:(0123456789)The International Journal of Cardiovascular Imaging (2021) 37:1825–1837 plaque evolution [1]
Grayscale-IVUS analysis in intravascular imaging studies is usually performed at 1-mm intervals ignoring the phase of the cardiac cycle [2], even though this approach neglects cyclical changes in luminal dimensions and the longitudinal motion of the IVUS catheter within the vessel, which can affect accurate quantification of atheroma [3,4,5]
The automated methodologies developed to retrospectively-gate IVUS images, taking advantage of the relative movement of the lumen with regards to the IVUS catheter, have failed to dominate in research as most of them have not been robustly validated against ECG estimations as reference standard or they have not been incorporated in user-friendly software [9,10,11,12,13,14,15,16,17]

Summary

Introduction

Intravascular ultrasound (IVUS) is the preferred intravascular imaging modality for the evaluation of coronary plaque burden and the efficacy of emerging therapies targeting1 3 Vol.:(0123456789)The International Journal of Cardiovascular Imaging (2021) 37:1825–1837 plaque evolution [1]. The automated methodologies developed to retrospectively-gate IVUS images, taking advantage of the relative movement of the lumen with regards to the IVUS catheter, have failed to dominate in research as most of them have not been robustly validated against ECG estimations as reference standard or they have not been incorporated in user-friendly software [9,10,11,12,13,14,15,16,17]. Deep learning (DL) algorithms have gained interest as potential solutions for the rapid and accurate analysis of large datasets in cardiac imaging [18]. These approaches rely on the use of a pre-defined reference standard to train algorithms that can detect features on a training dataset and apply these algorithms on new data. Despite the potential value of this approach, its application in intravascular imaging has not been fully explored yet [19,20,21,22,23,24]

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