Science and Research

Facilitated Diagnosis of Pneumothoraces in Newborn Mice Using X-ray Dark-Field Radiography

OBJECTIVE: The aim of this study was to evaluate the diagnostic value of x-ray dark-field imaging in projection radiography-based depiction of pneumothoraces in the neonatal murine lung, a potentially life-threatening medical condition that requires a timely and correct diagnosis. MATERIALS AND METHODS: By the use of a unique preclinical model, 7-day-old C57Bl/6N mice received mechanical ventilation for 2 or 8 hours with oxygen-rich gas (FIO2 = 0.4; n = 24). Unventilated mice either spontaneously breathed oxygen-rich gas (FIO2 = 0.4) for 2 or 8 hours or room air (n = 22). At the end of the experiment, lungs were inflated with a standardized volume of air after a lethal dose of pentobarbital was administered to the pups. All lungs were imaged with a prototype grating-based small-animal scanner to acquire x-ray transmission and dark-field radiographs. Image contrast between the air-filled pleural space and lung tissue was quantified for both transmission and dark-field radiograms. After the independent expert's assessment, 2 blinded readers evaluated all dark-field and transmission images for the presence or absence of pneumothoraces. Contrast ratios, diagnostic accuracy, as well as reader's confidence and interreader agreement were recorded for both imaging modalities. RESULTS: Evaluation of both x-ray transmission and dark-field radiographs by independent experts revealed the development of a total of 10 pneumothoraces in 8 mice. Here, the contrast ratio between the air-filled pleural space of the pneumothoraces and the lung tissue was significantly higher in the dark field (8.4 +/- 3.5) when compared with the transmission images (5.1 +/- 2.8; P < 0.05). Accordingly, the readers' diagnostic confidence for the diagnosis of pneumothoraces was significantly higher for dark-field compared with transmission images (P = 0.001). Interreader agreement improved from moderate for the analysis of transmission images alone (kappa = 0.41) to very good when analyzing dark-field images alone (kappa = 0.90) or in combination with transmission images (kappa = 0.88). Diagnostic accuracy significantly improved for the analysis of dark-field images alone (P = 0.04) or in combination with transmission images (P = 0.02), compared with the analysis of transmission radiographs only. CONCLUSIONS: The significant improvement in contrast ratios between lung parenchyma and free air in the dark-field images allows the facilitated detection of pneumothoraces in the newborn mouse. These preclinical experiments indicate the potential of the technique for future clinical applications.
  • Hellbach, K.
  • Yaroshenko, A.
  • Willer, K.
  • Pritzke, T.
  • Baumann, A.
  • Hesse, N.
  • Auweter, S.
  • Reiser, M. F.
  • Eickelberg, O.
  • Pfeiffer, F.
  • Hilgendorff, A.
  • Meinel, F. G.

Keywords

  • Animals
  • Animals, Newborn
  • Disease Models, Animal
  • Lung/diagnostic imaging
  • Mice
  • Mice, Inbred C57BL
  • Pneumothorax/*diagnostic imaging
  • Radiography/*methods
  • X-Rays
Publication details
DOI: 10.1097/RLI.0000000000000285
Journal: Invest Radiol
Pages: 597-601 
Number: 10
Work Type: Original
Location: CPC-M
Disease Area: PLI
Partner / Member: KUM, LMU, HMGU
Access-Number: 27603110
See publication on PubMed

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