AI Article Synopsis

  • Idiopathic pulmonary fibrosis (IPF) poses a challenge due to its poor prognosis and the low agreement among specialists in diagnosing it, prompting the development of a non-invasive automated algorithm to identify IPF.
  • The study involved analyzing HRCT images from over a thousand ILD patients, achieving an impressive 96.1% accuracy in image segmentation and an 83.6% accuracy in diagnosing IPF through a mix of deep learning and machine learning methods.
  • The algorithm proved effective even in cases with usual interstitial pneumonia patterns, demonstrating that it can serve as a reliable tool for diagnosing IPF while minimizing risks associated with surgical lung biopsies.

Article Abstract

Background And Objective: Idiopathic pulmonary fibrosis (IPF) has poor prognosis, and the multidisciplinary diagnostic agreement is low. Moreover, surgical lung biopsies pose comorbidity risks. Therefore, using data from non-invasive tests usually employed to assess interstitial lung diseases (ILDs), we aimed to develop an automated algorithm combining deep learning and machine learning that would be capable of detecting and differentiating IPF from other ILDs.

Methods: We retrospectively analysed consecutive patients presenting with ILD between April 2007 and July 2017. Deep learning was used for semantic image segmentation of HRCT based on the corresponding labelled images. A diagnostic algorithm was then trained using the semantic results and non-invasive findings. Diagnostic accuracy was assessed using five-fold cross-validation.

Results: In total, 646,800 HRCT images and the corresponding labelled images were acquired from 1068 patients with ILD, of whom 42.7% had IPF. The average segmentation accuracy was 96.1%. The machine learning algorithm had an average diagnostic accuracy of 83.6%, with high sensitivity, specificity and kappa coefficient values (80.7%, 85.8% and 0.665, respectively). Using Cox hazard analysis, IPF diagnosed using this algorithm was a significant prognostic factor (hazard ratio, 2.593; 95% CI, 2.069-3.250; p < 0.001). Diagnostic accuracy was good even in patients with usual interstitial pneumonia patterns on HRCT and those with surgical lung biopsies.

Conclusion: Using data from non-invasive examinations, the combined deep learning and machine learning algorithm accurately, easily and quickly diagnosed IPF in a population with various ILDs.

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Source
http://dx.doi.org/10.1111/resp.14310DOI Listing

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