Application-specific approaches to MicroCT for evaluation of mouse models of pulmonary disease.
Elizabeth F RedenteKatrina W KopfAli N BahadurAnnette RobichaudLennart K LundbladLindsay T McDonaldPublished in: PloS one (2023)
The advent of micro-computed tomography (microCT) has provided significant advancement in our ability to generate clinically relevant assessments of lung health and disease in small animal models. As microCT use to generate outcomes analysis in pulmonary preclinical models has increased there have been substantial improvements in image quality and resolution, and data analysis software. However, there are limited published methods for standardized imaging and automated analysis available for investigators. Manual quantitative analysis of microCT images is complicated by the presence of inflammation and parenchymal disease. To improve the efficiency and limit user-associated bias, we have developed an automated pulmonary air and tissue segmentation (PATS) task list to segment lung air volume and lung tissue volume for quantitative analysis. We demonstrate the effective use of the PATS task list using four distinct methods for imaging, 1) in vivo respiration controlled scanning using a flexiVent, 2) longitudinal breath-gated in vivo scanning in resolving and non-resolving pulmonary disease initiated by lipopolysaccharide-, bleomycin-, and silica-exposure, 3) post-mortem imaging, and 4) ex vivo high-resolution scanning. The accuracy of the PATS task list was compared to manual segmentation. The use of these imaging techniques and automated quantification methodology across multiple models of lung injury and fibrosis demonstrates the broad applicability and adaptability of microCT to various lung diseases and small animal models and presents a significant advance in efficiency and standardization of preclinical microCT imaging and analysis for the field of pulmonary research.
Keyphrases
- high resolution
- pulmonary hypertension
- deep learning
- computed tomography
- data analysis
- image quality
- machine learning
- mass spectrometry
- healthcare
- public health
- convolutional neural network
- type diabetes
- magnetic resonance imaging
- immune response
- high throughput
- magnetic resonance
- high speed
- mesenchymal stem cells
- weight loss