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Correcting common OCT artifacts enhances plaque classification and identification of higher-risk plaque features.

Authors
  • Jessney, Benn
  • Chen, Xu
  • Gu, Sophie
  • Brown, Adam
  • Obaid, Daniel
  • Costopoulos, Charis
  • Goddard, Martin
  • Shah, Nikunj
  • Garcia-Garcia, Hector
  • Onuma, Yoshinobu
  • Serruys, Patrick
  • Hoole, Stephen P
  • Mahmoudi, Michael
  • Roberts, Michael
  • Bennett, Martin
Publication Date
Jul 01, 2024
Source
Apollo - University of Cambridge Repository
Keywords
Language
English
License
Green
External links

Abstract

BACKGROUND: Optical coherence tomography (OCT) is used widely to guide stent placement, identify higher-risk plaques, and assess mechanisms of drug efficacy. However, a range of common artifacts can prevent accurate plaque classification and measurements, and limit usable frames in research studies. We determined whether pre-processing OCT images corrects artifacts and improves plaque classification. METHODS: We examined both ex-vivo and clinical trial OCT pullbacks for artifacts that prevented accurate tissue identification and/or plaque measurements. We developed Fourier transform-based software that reconstructed images free of common OCT artifacts, and compared corrected and uncorrected images. RESULTS: 48 % of OCT frames contained image artifacts, with 62 % of artifacts over or within lesions, preventing accurate measurement in 12 % frames. Pre-processing corrected >70 % of all artifacts, including thrombus, macrophage shadows, inadequate flushing, and gas bubbles. True tissue reconstruction was achieved in 63 % frames that would otherwise prevent accurate clinical measurements. Artifact correction was non-destructive and retained anatomical lumen and plaque parameters. Correction improved accuracy of plaque classification compared against histology and retained accurate assessment of higher-risk features. Correction also changed plaque classification and prevented artifact-related measurement errors in a clinical study, and reduced unmeasurable frames to <5 % ex-vivo and ~1 % in-vivo. CONCLUSIONS: Fourier transform-based pre-processing corrects a wide range of common OCT artifacts, improving identification of higher-risk features and plaque classification, and allowing more of the whole dataset to be used for clinical decision-making and in research. Pre-processing can augment OCT image analysis systems both for stent optimization and in natural history or drug studies.

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