Automated quantification of radiological patterns predicts survival in idiopathic pulmonary fibrosis

Introduction

Baseline measures of disease severity have been used to predict survival in idiopathic pulmonary fibrosis (IPF) and include clinical features, pulmonary function measures, computed tomography (CT) findings and composite scoring indices [1–4]. While these measures have been validated in several studies, they appear inferior to dynamic surrogates of disease progression, such as longitudinal changes in physiological indices, i.e. decline in forced vital capacity (FVC) and diffusing capacity of the lung for carbon monoxide (D_LCO) over 6–12 months [2, 5, 6]. However, the utility of such longitudinal physiological indices for individual patient management is still significantly limited by substantial intra-individual variability, perhaps with confounding by coexisting conditions, such as emphysema or pulmonary hypertension [7, 8].

CALIPER (Computer-Aided Lung Informatics for Pathology Evaluation and Ratings) is an image analysis tool developed by the Biomedical Imaging Resource Laboratory at the Mayo Clinic Rochester (Rochester, MN, USA) for the characterisation and quantification of lung parenchymal findings on high-resolution computed tomography (HRCT). The detection and quantification of pulmonary parenchyma by CALIPER is based on histogram signature mapping techniques trained through expert radiologist consensus assessment of pathologically confirmed training sets obtained through the Lung Tissue Research Consortium (LTRC) [9]. We hypothesised that this novel computer-aided method of analysing pulmonary parenchymal features on chest HRCT would provide a reproducible and accurate assessment of disease that may correlate with the semi-quantitative assessment of radiologists. We further postulated that the overall extent or short-term changes in parenchymal features as detected by CALIPER or radiologists may correlate with and be independently predictive of survival in patients with IPF.

Results

Discussion

CALIPER represents an automated volumetric quantification tool for assessing specific parenchymal radiological features on HRCT. In our study of IPF patients, CALIPER measured short-term (3–15 months) reticular changes, and percentage and total ILD changes were predictive of survival. Correlation between radiologists was moderate to substantial regarding ground glass and reticular findings when estimating to the nearest 5%, and mild to moderate between radiologists and CALIPER for those same ILD findings. No specific parenchymal estimates of ILD were predictive of survival with radiologist assessment, although overall global assessment of disease progression or change by radiologists was predictive in our study.

The absence of a gold standard to validate accuracy of CALIPER volumetric measurements to specific regions in a pathological specimen led us to attempt to correlate longitudinal changes in quantitative estimates of radiological fibrosis to patient outcomes, specifically mortality. As the quantitative assessment of fibrosis by CALIPER is not influenced by confounding conditions such as emphysema or pulmonary hypertension that may affect pulmonary function measures, we felt radiological features may reflect more directly the progression of fibrotic processes and could represent a novel and promising tool in the assessment and management of patients with IPF.

The mild-to-moderate correlation between CALIPER measurements and estimates of extent of fibrosis by two expert radiologists in interstitial lung diseases is reassuring and suggests that CALIPER may indeed allow both accurate and reproducible assessments, though CALIPER’s semiquantitative measurements of specific parenchymal ILD features may prove more advantageous when subtle changes are not readily recognised between serial scans. Estimation using a scoring system to the nearest 5% allowed for moderate-to-substantial correlation between two experienced radiologists in our study, but only had mild-to-moderate correlation with CALIPER. We note that while algorithmic quantitative analysis by CALIPER may detect subtle abnormalities that radiologists may not, misclassification of abnormalities with similar density but different morphology (such as honeycombing versus emphysema) may occur with CALIPER or differ slightly from the radiologist assessment (ground glass versus reticular abnormality), explaining a difference in correlation.

Interestingly, radiologists' global assessment of short-term ILD progression was also predictive of survival in our study. We know, in general, that radiologists' quantitative assessments and diagnostic interpretation are often inconsistent with one another, although our degree of radiologist correlation was higher. Perhaps this may be explained by our reviewing radiologists being subspecialists in thoracic radiology at the same institution, and both having reviewed and standardised cases and terminology as training for other ILD research studies. Nonblinding to time-points 1 and 2 may have increased radiologist vigilance for expected change between interval scans and biased interpretation of disease progression. Nonetheless, this conclusion is gratifying in regards to experienced radiologists detecting progression over shorter time intervals as being statistically predictive of survival, although detection of such subtle changes may not be reproducible or consistent across all practices and institutions. A quantitative method such as CALIPER may provide this consistency, particularly as detection of subtle progression over shorter time intervals may be valuable in estimating survival and perhaps be used as a marker of treatment response in future clinical trials. We are encouraged that correlation of our reproducible quantitative assessments of disease with outcomes is significant, independent of correlation with the subjective descriptions of disease features by a radiologist.

Prognostication of IPF remains challenging due to the paucity of validated surrogate markers of disease progression and an unpredictable natural history. The use of physiological data as surrogate markers has significant limitations. First, physiological measures, such as FVC and D_LCO, are characterised by significant intra-individual variability. In fact, the threshold of 10% decline in FVC is below the degree of normal intra-individual variability, as suggested by recent guidelines [15]. Secondly, physiological measures provide only indirect estimates of the progression of fibrosis, and may be affected by coexisting emphysema and/or pulmonary hypertension that are frequently associated with IPF [7, 8]. Lastly, PFTs may not be sensitive enough to detect subclinical progression of fibrosis: FVC decline as defined by current thresholds is a relatively rare event in IPF clinical trials, which has led some authors to suggest that marginal declines in FVC may be more sensitive, though less specific [16].

A number of other studies suggest that the extent of fibrosis assessed semiquantitatively on HRCT is a strong predictor of outcomes in IPF [1, 4, 17]. Correlation of quantitative estimates of pulmonary fibrosis by automated analysis to mortality has been the object of few reports [1, 18, 19]. This line of research has been hampered by the lack of validation methodology and poor access to high-quality HRCT allowing for volumetric assessment of the lung parenchyma. Most of the available data on quantitative analysis of lung fibrosis have focused on the predictive power of baseline HRCT abnormalities.

The use of longitudinal quantitative indices of lung fibrosis as identified on HRCT could represent an appealing alternative to physiological measures. An accurate and reproducible method allowing monitoring of fibrosis progression on HRCT would be a valuable surrogate marker of disease. Unfortunately, assessment of fibrosis volumes by expert radiologists has been hampered by substantial intra- and interobserver variability, and quantitative CT indices using fractal analysis and global histogram-based methods have not been validated or found helpful in clinical practice thus far [1, 4, 19–24]. CALIPER is based on a texture-sensitive volumetric analysis that allows automated classification of lung parenchyma according to a database of HRCT volumes of interest validated by radiologists using data from the LTRC [9]. The majority of existing expert systems and associated quantitative tools depend on strictly controlled image acquisition protocols to provide consistent results. We believe careful selection of training sets for CALIPER enables more reproducible classification, whose greyscale local histogram-based algorithms are less affected by image noise, reconstruction kernel and other scan parameters.

While our preliminary results are promising, we recognise the limitations of our study. First, the CALIPER technology was developed based on “lung pattern signatures” derived from standardised CT analyses and acquisition protocols used in the LTRC database [9]. Scan parameters used for CT in this retrospective study were different to those used in the LTRC database and were not always identical for the scans at the two time-points. Despite differences in acquisition parameters for some of the data sets, the mild-to-moderate correlation between radiologist semiquantitative assessment and CALIPER analysis supports the validity of our results. We postulate that our histogram signature-based method may be more robust and less sensitive to specific slice thickness or image reconstruction parameters than other texture-based or pixel counting techniques. Secondly, the requirement of two serial HRCT obtained solely for follow-up purposes led us to exclude patients with HRCT obtained for coexisting illnesses (heart failure, infection and acute exacerbation) and others with only one HRCT available. This exclusion criteria arguably limits the external validity of our study, as included patients were more likely to represent a subset of IPF patients with gradual decline rather than stable (less likely to have repeat HRCT) or unstable patients (more likely to be lost to follow-up, die or experience acute exacerbation). However, the fact that the median survival of included patients was similar to that typically seen for patients with IPF is reassuring in this regard. Finally, the number of patients included was small, due to stringent eligibility criteria. While small, the numbers are comparable to those used in prior studies evaluating the value of longitudinal trends in physiological measures. We recognise these limitations and believe that further validation of our preliminary results is warranted, including prospective analysis of standardised HRCT with equivalent time intervals, comparison of IPF abnormalities to those of other ILD and application of short-term changes found with CALIPER to predicting acute exacerbation or the presence of related complications such as pulmonary hypertension.

In conclusion, we have shown that CALIPER characterisation and quantification of lung parenchyma on HRCT correlates with visual assessment by expert radiologists, and that quantitative short-term volumetric longitudinal changes on serial HRCT correlate with IPF mortality. We believe that quantitative features of ILD on HRCT determined by CALIPER may represent an accurate and reproducible biomarker for IPF that warrants further validation studies and application.