| INTRODUCTION |
The history of usual interstitial pneumonia (UIP) dates back to 1969 when Liebow and Carrington [1], pathologists at Yale University, defined it as “the largest group, the most heterogeneous in terms of structure and causation, corresponding to the classic, undifferentiated” or “usual” description. It results from the failed resolution of lesions caused by injury to the alveolar lining cells, the capillary endothelium, or both, while the basement membrane is relatively intact. Hyaline membrane formation and the most variegated proteinaceous and cellular exudate may persist for several years. In 1994, Katzenstein and Fiorelli [2] defined nonspecific interstitial pneumonia (NSIP) as “characterized by varying proportion of interstitial inflammation and fibrosis that appeared to be occurring over a single time span (i.e., the process was temporally uniform)” with a better prognosis and different treatment options. The concept of UIP and NSIP evolved within the pathology domain until the 1990s when Nishimura et al. in 1992 [3], Müller and Coiby in 1997 [4], and Johkoh et al. in 1999 [5] reported the histopathologic-radiologic correlation of UIP using high-resolution CT (HRCT). The American Thoracic Society (ATS)/European Respiratory Society (ERS) International Multidisciplinary Consensus Classification on Idiopathic Interstitial Pneumonia published in 2002 reflected the trend of the multidisciplinary approach by pulmonologists, radiologists, and pathologists [6]. The concept and definition of UIP continued to evolve with pathologic and CT criteria in addition to the ATS/ERS/Japanese Respiratory Society (JRS)/Latin American Thoracic Association (ALAT) Guidelines in 2011 [7] and 2018 [8] and the Fleischner Society White Paper in 2018 [9]. In 2020, the Fleischner Society Position Paper on Interstitial Lung Abnormality (ILA), which defined the abnormality as lung lesions detected incidentally on CT, was published with its subcategorizations of non-subpleural ILA, subpleural non-fibrotic ILA, and subpleural fibrotic ILA based on data from multiple large investigational cohort studies including thousands of CT scans [10]. It is expected that ILAs, particularly the subpleural fibrotic, include earlier or subclinical forms of fibrotic lung diseases. Throughout the course of concept evolution from UIP to ILA via NSIP, histopathology and CT have become a partner and they have played an important role in the multidisciplinary team approach. At the same time, traction bronchiectasis/bronchiolectasis is recognized as the most persistent and important index of severity for fibrosis and prognosis [11, 12]. A recent report by Hida et al. [13] indicated that the Traction Bronchiectasis Index (TBI) helps stratify the prognoses of subjects with ILA. In this review, the evolutionary concepts of UIP, NSIP, and ILA are summarized using tables, figures, and CT-pathologic correlation. Finally, the proposal of CT-based UIP scoring was proposed to facilitate a better understanding of the spectrum from ILA to UIP with attention to traction bronchiectasis.
| Brief History of Fibrotic Lung Disease, UIP, and Traction Bronchiectasis |
Liebow and Carrington [1] first defined UIP in 1969; chronic interstitial pneumonia was classified into five histopathological categories: UIP, desquamative interstitial pneumonia (DIP), bronchiolitis obliterans interstitial pneumonia and diffuse alveolar damage (BIP), lymphocytic interstitial pneumonia (LIP), and giant cell interstitial pneumonia (GIP). NSIP was first defined as a category of pulmonary fibrosis in 1994 by Katzenstein and Fiorelli [2]. Acute interstitial pneumonia (AIP), respiratory bronchiolitis-interstitial lung disease (RB-ILD), and bronchiolitis obliterans with organizing pneumonia (BOOP) as a substitute for bronchiolitis with interstitial pneumonia were also added to the category of idiopathic interstitial pneumonias [4, 14, 15]. GIP was considered idiopathic and excluded from the category of idiopathic interstitial pneumonia [4, 16, 17]. Both pathological and clinical classifications of idiopathic pulmonary fibrosis (IPF; pathologic counterpart, UIP) were reviewed [18]. In 2001, the classification evolved into the diagnostic criteria for IPF by the ATS with consensus [6]; the characteristic HRCT features were as follows: patterns of honeycombing and reticular opacities and the distribution of bilateral and symmetric basal or subpleural predominance (Table 1, Fig. 1).
|
|
Traction bronchiectasis was described as a finding of CT UIP in the 2011 statement, which was subsequently added as a criterion of probable CT UIP pattern in the 2018 statement [8, 9]. In the 1950s, traction bronchiectasis was initially regarded as the progression of cystic changes in the lungs [19]. A comparison between the pathologic and chest radiographic features of end-stage fibrosis was performed by Genereux [20], and in this study, the possible relationship between traction bronchiectasis and pulmonary fibrosis was highlighted. The association between pathological and radiological traction bronchiectasis was reported by Westcott and Cole [21]. They considered the mechanism of traction bronchiectasis as the response to abnormal intraluminal pressure caused by increased elasticity and mechanical distortion of the bronchi. Radiological bronchiectasis was described in 2009 [22]; traction bronchiectasis was described as a frequently accompanying feature of UIP. Traction bronchiectasis is now defined as irregular and bronchiolar dilation caused by surrounding retractile pulmonary fibrosis (Fig. 1) [23].
| Overview of NSIP |
Kitaichi [24] was the first to report the cases of idiopathic interstitial pneumonia that were not covered by the previous classification of idiopathic interstitial pneumonia, including UIP and DIP. The concept of NSIP was developed by Katzenstein and Fiorelli [2]. They reported that NSIP had pathological features of inflammation and pulmonary fibrosis, the proportion of which could help classify NSIP into subtypes [2]. Fibrotic and cellular patterns are included in the classification of NSIP [2, 18, 25, 26, 27]. Cellular NSIP mainly consists of inflammatory cell infiltration [2, 25]. The typical pathological features of fibrotic NSIP (fNSIP) are characterized by homogeneous and diffuse fibrosis with interstitial deposition of collagen and chronic inflammatory cells [24, 27]. The fNSIP had a larger architectural distortion than the cellular NSIP; it was smaller than that of UIP [18, 25]. Fibroblastic foci, myogenesis, and honeycombing in pathology, which are pathognomonic of UIP, are not usually observed in fNSIP [18, 28, 29]. In addition to pathological viewpoints, NSIP was also different from UIP based on the following clinical characteristics: younger age, susceptibility to steroid therapy, longer overall survival, and relatively preserved pulmonary function [2, 18, 27, 28, 30]. NSIP is associated with connective tissue disease more frequently than UIP. This relationship with connective tissue disease can influence the overall survival of patients depending on the type of underlying connective tissue disease (Tables 1, 2) [31, 32].
|
HRCT is useful for identifying NSIP; a 78% diagnostic accuracy was reported by Silva et al. [33]. Typical features of fNSIP on HRCT are subpleural-dominant ground-glass opacities and reticular lesions sometimes with mild traction bronchiectasis. The lesions may show a distribution along the bronchovascular bundles and subpleural lungs (Fig. 2). In fNSIP related to connective tissue disease, the lesions demonstrated a lower lung zone predominance (Fig. 3). Honeycombing in fNSIP is rarely observed on HRCT and during pathological evaluations (Figs. 2, 3) [34, 35, 36, 37]. On the other hand, the presence of ground-glass opacities is insufficient for CT distinction between fNSIP and UIP [5, 11, 36, 38]; interobserver variation was also not negligible [5]. Therefore, pathological examination is often required to confirm the diagnosis of fNSIP [5, 11, 38, 39]. However, radiologic UIP features can overlap with those of fNSIP, with subpleural fibrosis accompanying traction bronchiectasis/bronchiolectasis. Similarly, UIP can overlap with fNSIP with patchy involvement and a subpleural or paraseptal distribution of fibrosis [5, 11, 29, 30, 34, 35, 36, 37, 38]. The interobserver agreement between radiological and pathological observations can also be a problem [11, 30, 39, 40]. Additionally, the distinction between cellular NSIP and fNSIP, as well as NSIP and chronic hypersensitivity pneumonitis, based on HRCT is often difficult [33]. Regardless of these issues, radiological assessments of fNSIP are important because of the difference between patient management approaches and patient survival (effective corticosteroid and cytotoxic drug use and longer overall survival in fNSIP, compared with UIP) [30, 41].
|
|
| Significance of Classifying ILD Depending on the Presence of Traction Bronchiectasis |
An international consensus statement about interstitial pneumonia was first made in 2002 [6]. Interstitial pneumonia was classified based on the pathological pattern and the categorization of IPF or non-IPF. The radiologic features of interstitial pneumonia were also based on previous studies that reported a high diagnostic performance of HRCT [37, 42]. Quadrelli et al. [43] reported that the performance of HRCT and pathological assessments in diagnosing IPF were comparable. Thus, differentiating between pathological and radiological patterns was considered important for the diagnosis of interstitial lung disease (ILD). An official ATS/ERS/JRS/ALAT statement in 2011 addressed the efficacy of the radiological approach [7]. The statement established the CT criteria of UIP patterns where “UIP pattern,” “Possible UIP pattern,” and “Inconsistent with UIP Pattern” were included. A possible UIP pattern was determined to meet the three following features: subpleural and basal predominance, reticular abnormality, and the absence of the feature of “Inconsistent with UIP Pattern.” Therefore, lung biopsy can be exempted for the definite diagnosis of IPF after the confirmation of the CT “UIP Pattern” (Table 3).
|
Sumikawa et al. [11] reported that survival curves are affected by HRCT patterns of chronic fibrotic ILD; cases with UIP patterns show significantly shorter overall survival than those with possible UIP patterns and fNSIP patterns (mean overall survival times of typical UIP, possible UIP, and fNSIP: 33.5, 73.0, and 140.2 months, respectively). Regarding the cases with fNSIP patterns, significant differences in survival curves stratified by pathological patterns were observed [30]. Several previous studies have shown an association between HRCT patterns and the histopathological pattern of UIP [8, 38, 44, 45]. Raghu et al. [46] reported that in an appropriate clinical setting, surgical lung biopsy may not be necessary for diagnosing IPF if the CT “possible UIP pattern” can be assessed by CT-reading experts.
Because 80% or more of patients with CT “probable UIP pattern” proved to have histopathological UIP, Chung et al. [45] insisted that the CT “possible UIP pattern” should be classified into probable and indeterminate UIP patterns on HRCT to maintain consistency with the pathological UIP classification. Brownell et al. [47] reported that the addition of traction bronchiectasis to the CT “possible UIP pattern” can increase the positive predictive value for histopathologic UIP diagnosis (Fig. 4).
|
Therefore, the statement was modified and published as a clinical practice guideline in 2018 [8]. A possible UIP pattern can be replaced with a probable UIP pattern based on the presence of traction bronchiectasis/bronchiolectasis (Figs. 4, 5). Traction bronchiectasis was also indicated as an important feature of interstitial fibrosis in the Fleischner Society White Paper [9]. The distinction between traction bronchiectasis and honeycombing based on HCRT is often difficult, and adding multi-planar (coronal or sagittal reformation) images may facilitate a somewhat easier reading for the distinction. However, the importance of such a distinction cannot be emphasized more because the probable UIP pattern on HRCT shows a strong correlation with pathologic UIP [45].
|
| Emerging Therapies for UIP and Emerging Concept of ILA |
Several clinical trials have been performed to prove the benefit of selected drug therapy. The importance of monotherapy with corticosteroids was demonstrated only in a retrospective study [48]. The effect of corticosteroids on acute exacerbation of IPF was also unclear, although they were commonly prescribed [49]. The combination of corticosteroids and immunosuppressants was considered equivocal [50, 51]. Rituximab and cyclophosphamide were significantly effective for progressive ILD other than IPF in previous studies [52, 53]. However, pharmacotherapy for IPF has no conclusive evidence [7]. Some studies have shown that lung transplantation can improve the overall survival of patients with IPF [54]. Recently, the introduction of pirfenidone, an oral antifibrotic drug, and nintedanib, a tyrosine kinase inhibitor, has gained increasing attention. Both pirfenidone and nintedanib proved to be effective in controlling declining lung function or improving overall survival in phase III clinical trials (Fig. 5) [55, 56, 57]. Previous studies reported that immediate treatment with antifibrotic drugs can improve the overall survival and quality of life in patients with IPF [58, 59]. Therefore, the need for early detection of IPF has become pressing.
Subclinical and early ILD has been recognized broadly in several reports [60, 61, 62, 63, 64]. Rosas et al. [60] identified the radiological features of asymptomatic ILD with CT features such as subpleural ground-glass opacities and reticulation or peribronchovascular thickening. Similar findings of pulmonary interstitial changes, which may be collectively called ILA, were reported in subclinical older adults, smokers, and rheumatoid arthritis-related ILD [61, 62, 63, 64, 65]. The radiological features of ILA are defined as nondependent lung changes on CT affecting more than 5% of any lung zone, including non-dependent ground-glass opacities or reticular abnormalities, architectural distortion, diffuse centrilobular nodularity, nonemphysematous cysts, honeycombing, and traction bronchiolectasis [66, 67, 68]. The Fleischner Society White Paper also highlighted that ILA may be a crucial predictor of ILD [9]. In 2020, the Fleischner Society Position Paper on ILAs was published. ILAs are defined radiologically as incidental non-dependent abnormalities, including ground-glass opacities or reticular abnormalities, architectural distortion, traction bronchiolectasis, honeycombing, and nonemphysematous cysts involving at least 5% of a lung zone in individuals without suspected ILD [10]. ILAs were further subclassified as non-subpleural, subpleural non-fibrotic, and subpleural fibrotic (Table 4) (Figs. 6, 7). There has been a debate on the treatment of early fibrotic ILD or fibrotic ILA with antifibrotic drugs, which is based on the idea that early fibrotic ILD or fibrotic ILA eventually evolves and progresses to overt fibrotic ILD. Early treatment with antifibrotic drugs may prevent the ongoing progression of pulmonary fibrosis and help maintain healthy lives.
|
|
|
| How Do We Understand the Whole Gamut of the ILD Spectrum from ILA to UIP with a Special Focus on Traction Bronchiectasis/Bronchiolectasis? |
The radiologic features of ILA overlap with those of NSIP, except for the relative paucity of clinical symptoms in the former [10, 34, 35, 36, 66, 67, 68]. NSIP can be diagnosed based on pathologic and clinical characteristics, whereas ILA can be diagnosed based on incidental findings on CT [10, 68]. ILAs are associated with smoking, old age, declining pulmonary function, increased mortality, and a positive mucin 5B (MUC5B) gene [10, 66, 67, 68, 69, 70, 71, 72]. Some of these associated factors of ILAs are similar to those of IPF [7, 8, 9, 10, 66, 67, 68, 69, 70, 71, 72, 73]. During long-term follow-up, the radiological findings of ILAs may evolve depending on the background and degree of lung disease [11, 12, 71, 72, 74, 75, 76, 77].
An increase in the extent of architectural distortion or honeycombing, as well as the decrease in the extent of ground-glass opacities, is often detected on the HRCT of pathologically diagnosed fNSIP patients [11, 74]. In approximately 30% of cases with a suggested diagnosis of NSIP on initial CT examination, the disease shows progression, which was suggestive of IPF on follow-up CT in a previous study [74]. For ILAs and other ILDs, several studies have reported the progression of lung abnormalities on HRCT [12, 71, 72, 75, 76, 77]. NSIP, ILA, and ILD are considered to belong to the same spectrum as IPF based on their progressions [78, 79]. ILAs and early interstitial fibrosis are not necessarily interchangeable because ILAs are frequently observed with advanced age and associated with smoking and environmental pollution [80]. However, early diagnosis or more careful follow-up of ILAs may be required with the possibility of progression in mind. Increased comorbidities, such as lung cancer and other respiratory diseases, should also be considered during follow-up (Table 5) [72, 81, 82, 83, 84].
|
The onset of pulmonary fibrosis may indicate a dysfunction of epithelial cells. The release of profibrotic mediators and the acquisition of the features of mesenchymal cells occurred subsequently. The release of profibrotic mediators may lead to the activation of mesenchymal cells, an increase in the extracellular matrix, the differentiation of fibroblasts, and apoptosis of epithelial cells. The repetitive and complicated mechanism, including the aforementioned processes, was considered to cause interstitial fibrosis or alveolar wall collapse [73, 85]. Simultaneously, lung remodeling occurs as an aberrant process. Injury to epithelial cells induces the activation of basal airway cells and causes aberrant re-epithelization or bronchiolization [85, 86]. These are considered to result in traction bronchiectasis or honeycombing. However, there are problems in clinical settings related to the discordance between radiologic and pathologic features; the difficulty in distinguishing microcystic honeycombing from traction bronchiectasis may cause a discrepancy [9, 87, 88]. Indeed, histopathological honeycombing does not necessarily coincide with radiological honeycombing owing to the difference in their definitions [88]. On the other hand, traction bronchiectasis is closely related to honeycombing pathologically and radiologically. Staats et al. [89] reported that the degree of histopathological traction bronchiolectasis correlates with the degree of honeycombing on HRCT and honeycombing on HRCT correlates with histopathological traction bronchiolectasis after an explanted lung evaluation. This implied that lung remodeling was associated with the spectrum spanning traction bronchiectasis to honeycombing [84, 89, 90]. This observation was also consistent with that of a previous study; the extent of traction bronchiectasis and reticulation was associated with the severity of pulmonary fibrosis [91]. Jacob et al. [92] reported that the progression of traction bronchiectasis in IPF patients is the most significant factor associated with mortality. Therefore, identifying the presence, extent, and progression of traction bronchiectasis on HRCT is considered important for the diagnosis and prognostic predictions of IPF.
The results of previous studies suggested that traction bronchiectasis is also associated with prognosis in patients with ILD and chronic hypersensitivity pneumonitis [87, 93, 94]. Edey et al. [95] first reported that the quantification (with a three-point scale) of the severity of traction bronchiectasis is important for patient prognosis; in other words, increasing the severity of traction bronchiectasis is indicative of higher mortality irrespective of the HRCT pattern and disease extent. Walsh et al. [96] reported that there is a significant difference between the survival curves stratified by the severity of traction bronchiectasis in chronic hypersensitivity pneumonitis. However, the standard for the classification of the severity of traction bronchiectasis is not defined in these studies. Recently, traction bronchiectasis/bronchiolectasis proved to be the most influential factor associated with the progression of ILAs [78]. Thus, the association between ILAs and traction bronchiectasis/bronchiolectasis is gaining more attention.
Hida et al. [13] classified ILA patients into 4 according to TBI. The four-point scales were based on the evaluation of the diameter of dilated bronchi or bronchioles on HRCT: TBI = 0, ILA without traction bronchiectasis or bronchiolectasis; TBI = 1, ILA with bronchiolectasis but without bronchiectasis or architectural distortion; TBI = 2, ILA with mild to moderate traction bronchiectasis; TBI = 3, ILA and severe traction bronchiectasis and/or honeycombing. As illustrated in Figure 8A, dilated airways in the subpleural area within 2 cm from the pleural or fissural surfaces with concurrent ILAs should be regarded indicative of bronchiolectasis, whereas dilated airways that are more proximal represent bronchiectasis, as shown in Figure 8B. They concluded that the extent of TBI is associated with overall survival or survival curves in ILA patients [13]. Traction bronchiolectasis on HRCT may be characterized by the results of interstitial inflammation, a non-fibrotic ILA, or gravity-dependent phenomena because the radiologic-pathologic correlation on the nature of the presumed traction bronchiolectasis has not been established. However, TBI on HRCT may be indicative of a substantial degree of interstitial pulmonary fibrosis (Fig. 8).
|
ILAs have been reported to progress at several yearly intervals [12, 71, 77]. Jin et al. [77] reported the relationship between fibrotic ILAs and their progression. Putman et al. [12] reported that ILA progression is associated with the following radiological features: subpleural reticulation, lower lung zone predominance, and traction bronchiectasis/bronchiolectasis. Traction bronchiectasis/bronchiolectasis may be predictive not only of the degree of pulmonary fibrosis but also the progression of ILAs. On the other hand, serial changes in traction bronchiectasis/bronchiolectasis, which are frequently observed in clinical settings, have been mentioned only in a few studies [33, 92]. Silva et al. [33] showed changes in lung abnormalities in patients with NSIP on HRCT. Several cases showed an increase in the severity of traction bronchiectasis. Further assessment will be necessary to confirm the presence and extent of traction bronchiectasis in fibrotic ILDs or ILAs as radiological biomarkers for pulmonary fibrosis.
| A Proposal of UIP Score Based on CT with a Special Focus on Traction Bronchiectasis/Bronchiolectasis |
In this article, we have reviewed the history and evolution of the concepts and classification of UIP and traction bronchiectasis based on the tremendous work of several pathologists, pulmonologists, radiologists, and investigators on ILA and TBI. Naturally, we may derive a simple scoring system for UIP based on CT findings with special emphasis on traction bronchiectasis/bronchiolectasis (Table 6) (Figs. 9, 10).
|
|
|
| Future Directions and Conclusion |
Traction bronchiectasis may facilitate a better understanding of the spectrum of ILD from ILA to IPF. The graded severity of traction bronchiectasis may facilitate the prediction of prognosis in ILAs. The progression of traction bronchiectasis is often observed in ILD patients during long-term follow-up evaluation. However, only a few studies have elaborated on the degree of or progression of traction bronchiectasis in ILD patients. Further studies are required to assess the exact extent of traction bronchiectasis from various viewpoints, including deep learning and artificial intelligence approaches, alternative approaches to quantitative analysis, and the correlation between radiology and pathology.
Notes
Conflicts of Interest: Dr. Hatabu reports grants from Canon Medical Systems Inc, grants from Konica Minolta Inc, personal fees from Mitsubishi Chemical Co, personal fees from Canon Medical Systems Inc, outside the submitted work. Other authors have no potential conflicts of interest to disclose.
Author Contributions:
1. Liebow AA, Carrington CB. The interstitial pneumonias. In: Simon M, Potchen EJ, LeMay M, editors. Frontiers of pulmonary radiology. 1st ed. New York: Grune & Stratton; 1969. pp. 102-141.
2. Katzenstein AL, Fiorelli RF. Nonspecific interstitial pneumonia/fibrosis. Histologic features and clinical significance. Am J Surg Pathol 1994;18:136–147.
3. Nishimura K, Kitaichi M, Izumi T, Nagai S, Kanaoka M, Itoh H. Usual interstitial pneumonia: histologic correlation with high-resolution CT. Radiology 1992;182:337–342.
4. Müller NL, Coiby TV. Idiopathic interstitial pneumonias: high-resolution CT and histologic findings. Radiographics 1997;17:1016–1022.
5. Johkoh T, Müller NL, Cartier Y, Kavanagh PV, Hartman TE, Akira M, et al. Idiopathic interstitial pneumonias: diagnostic accuracy of thin-section CT in 129 patients. Radiology 1999;211:555–560.
6. American Thoracic Society; European Respiratory Society. American Thoracic Society/European Respiratory Society International Multidisciplinary Consensus Classification of the Idiopathic Interstitial Pneumonias. This joint statement of the American Thoracic Society (ATS), and the European Respiratory Society (ERS) was adopted by the ATS board of directors, June 2001 and by the ERS Executive Committee, June 2001. Am J Respir Crit Care Med 2002;165:277–304.
7. Raghu G, Collard HR, Egan JJ, Martinez FJ, Behr J, Brown KK, et al. An official ATS/ERS/JRS/ALAT statement: idiopathic pulmonary fibrosis: evidence-based guidelines for diagnosis and management. Am J Respir Crit Care Med 2011;183:788–824.
8. Raghu G, Remy-Jardin M, Myers JL, Richeldi L, Ryerson CJ, Lederer DJ, et al. Diagnosis of idiopathic pulmonary fibrosis. An official ATS/ERS/JRS/ALAT clinical practice guideline. Am J Respir Crit Care Med 2018;198:e44–e68.
9. Lynch DA, Sverzellati N, Travis WD, Brown KK, Colby TV, Galvin JR, et al. Diagnostic criteria for idiopathic pulmonary fibrosis: a Fleischner Society White Paper. Lancet Respir Med 2018;6:138–153.
10. Hatabu H, Hunninghake GM, Richeldi L, Brown KK, Wells AU, Remy-Jardin M, et al. Interstitial lung abnormalities detected incidentally on CT: a Position Paper from the Fleischner Society. Lancet Respir Med 2020;8:726–737.
11. Sumikawa H, Johkoh T, Fujimoto K, Arakawa H, Colby TV, Fukuoka J, et al. Pathologically proved nonspecific interstitial pneumonia: CT pattern analysis as compared with usual interstitial pneumonia CT pattern. Radiology 2014;272:549–556.
12. Putman RK, Gudmundsson G, Axelsson GT, Hida T, Honda O, Araki T, et al. Imaging patterns are associated with interstitial lung abnormality progression and mortality. Am J Respir Crit Care Med 2019;200:175–183.
13. Hida T, Nishino M, Hino T, Lu J, Putman RK, Gudmundsson EF, et al. Traction bronchiectasis/bronchiolectasis is associated with interstitial lung abnormality mortality. Eur J Radiol 2020;129:109073
14. Katzenstein AL, Myers JL, Mazur MT. Acute interstitial pneumonia. A clinicopathologic, ultrastructural, and cell kinetic study. Am J Surg Pathol 1986;10:256–267.
15. Myers JL, Veal CF Jr, Shin MS, Katzenstein AL. Respiratory bronchiolitis causing interstitial lung disease. A clinicopathologic study of six cases. Am Rev Respir Dis 1987;135:880–884.
16. Ohori NP, Sciurba FC, Owens GR, Hodgson MJ, Yousem SA. Giant-cell interstitial pneumonia and hard-metal pneumoconiosis. A clinicopathologic study of four cases and review of the literature. Am J Surg Pathol 1989;13:581–587.
17. Gibbs AR, Seal RM. Primary lymphoproliferative conditions of lung. Thorax 1978;33:140–152.
18. Katzenstein AL, Myers JL. Idiopathic pulmonary fibrosis: clinical relevance of pathologic classification. Am J Respir Crit Care Med 1998;157:1301–1315.
19. Heppleston AG. The pathology of honeycomb lung. Thorax 1956;11:77–93.
20. Genereux GP. The end-stage lung: pathogenesis, pathology, and radiology. Radiology 1975;116:279–289.
21. Westcott JL, Cole SR. Traction bronchiectasis in end-stage pulmonary fibrosis. Radiology 1986;161:665–669.
22. Cantin L, Bankier AA, Eisenberg RL. Bronchiectasis. AJR Am J Roentgenol 2009;193:W158–W171.
23. Hansell DM, Bankier AA, MacMahon H, McLoud TC, Müller NL, Remy J. Fleischner Society: glossary of terms for thoracic imaging. Radiology 2008;246:697–722.
24. Kitaichi M. Pathologic features and the classification of interstitial pneumonia of unknown etiology. Bull Chest Dis Res Inst Kyoto Univ 1990;23:1–18.
25. Nagai S, Kitaichi M, Itoh H, Nishimura K, Izumi T, Colby TV. Idiopathic nonspecific interstitial pneumonia/fibrosis: comparison with idiopathic pulmonary fibrosis and BOOP. Eur Respir J 1998;12:1010–1019.
26. Travis WD, Matsui K, Moss J, Ferrans VJ. Idiopathic nonspecific interstitial pneumonia: prognostic significance of cellular and fibrosing patterns: survival comparison with usual interstitial pneumonia and desquamative interstitial pneumonia. Am J Surg Pathol 2000;24:19–33.
27. Bjoraker JA, Ryu JH, Edwin MK, Myers JL, Tazelaar HD, Schroeder DR, et al. Prognostic significance of histopathologic subsets in idiopathic pulmonary fibrosis. Am J Respir Crit Care Med 1998;157:199–203.
28. Katzenstein AL, Mukhopadhyay S, Myers JL. Diagnosis of usual interstitial pneumonia and distinction from other fibrosing interstitial lung diseases. Hum Pathol 2008;39:1275–1294.
29. Li X, Chen C, Xu J, Liu J, Yi X, Sun X, et al. Nonspecific interstitial pneumonia and usual interstitial pneumonia: comparison of the clinicopathologic features and prognosis. J Thorac Dis 2014;6:1476–1481.
30. Flaherty KR, Travis WD, Colby TV, Toews GB, Kazerooni EA, Gross BH, et al. Histopathologic variability in usual and nonspecific interstitial pneumonias. Am J Respir Crit Care Med 2001;164:1722–1727.
31. du Bois R, King TE Jr. Challenges in pulmonary fibrosis × 5: the NSIP/UIP debate. Thorax 2007;62:1008–1012.
32. Nunes H, Schubel K, Piver D, Magois E, Feuillet S, Uzunhan Y, et al. Nonspecific interstitial pneumonia: survival is influenced by the underlying cause. Eur Respir J 2015;45:746–755.
33. Silva CI, Müller NL, Lynch DA, Curran-Everett D, Brown KK, Lee KS, et al. Chronic hypersensitivity pneumonitis: differentiation from idiopathic pulmonary fibrosis and nonspecific interstitial pneumonia by using thin-section CT. Radiology 2008;246:288–297.
34. Kligerman SJ, Groshong S, Brown KK, Lynch DA. Nonspecific interstitial pneumonia: radiologic, clinical, and pathologic considerations. Radiographics 2009;29:73–87.
35. Kim TS, Lee KS, Chung MP, Han J, Park JS, Hwang JH, et al. Nonspecific interstitial pneumonia with fibrosis: high-resolution CT and pathologic findings. AJR Am J Roentgenol 1998;171:1645–1650.
36. Mink SN, Maycher B. Comparative manifestations and diagnostic accuracy of high-resolution computed tomography in usual interstitial pneumonia and nonspecific interstitial pneumonia. Curr Opin Pulm Med 2012;18:530–534.
37. Travis WD, Hunninghake G, King TE Jr, Lynch DA, Colby TV, Galvin JR, et al. Idiopathic nonspecific interstitial pneumonia: report of an American Thoracic Society project. Am J Respir Crit Care Med 2008;177:1338–1347.
38. MacDonald SL, Rubens MB, Hansell DM, Copley SJ, Desai SR, du Bois RM, et al. Nonspecific interstitial pneumonia and usual interstitial pneumonia: comparative appearances at and diagnostic accuracy of thin-section CT. Radiology 2001;221:600–605.
39. Hunninghake GW, Zimmerman MB, Schwartz DA, King TE Jr, Lynch J, Hegele R, et al. Utility of a lung biopsy for the diagnosis of idiopathic pulmonary fibrosis. Am J Respir Crit Care Med 2001;164:193–196.
40. Sverzellati N, Wells AU, Tomassetti S, Desai SR, Copley SJ, Aziz ZA, et al. Biopsy-proved idiopathic pulmonary fibrosis: spectrum of nondiagnostic thin-section CT diagnoses. Radiology 2010;254:957–964.
41. Lee HY, Lee KS, Jeong YJ, Hwang JH, Kim HJ, Chung MP, et al. High-resolution CT findings in fibrotic idiopathic interstitial pneumonias with little honeycombing: serial changes and prognostic implications. AJR Am J Roentgenol 2012;199:982–989.
42. Lynch DA, Newell JD, Logan PM, King TE Jr, Müller NL. Can CT distinguish hypersensitivity pneumonitis from idiopathic pulmonary fibrosis? AJR Am J Roentgenol 1995;165:807–811.
43. Quadrelli S, Molinari L, Ciallella L, Spina JC, Sobrino E, Chertcoff J. Radiological versus histopathological diagnosis of usual interstitial pneumonia in the clinical practice: does it have any survival difference? Respiration 2009;79:32–37.
44. Yagihashi K, Huckleberry J, Colby TV, Tazelaar HD, Zach J, Sundaram B, et al. Radiologic-pathologic discordance in biopsy-proven usual interstitial pneumonia. Eur Respir J 2016;47:1189–1197.
45. Chung JH, Chawla A, Peljto AL, Cool CD, Groshong SD, Talbert JL, et al. CT scan findings of probable usual interstitial pneumonitis have a high predictive value for histologic usual interstitial pneumonitis. Chest 2015;147:450–459.
46. Raghu G, Lynch D, Godwin JD, Webb R, Colby TV, Leslie KO, et al. Diagnosis of idiopathic pulmonary fibrosis with high-resolution CT in patients with little or no radiological evidence of honeycombing: secondary analysis of a randomised, controlled trial. Lancet Respir Med 2014;2:277–284.
47. Brownell R, Moua T, Henry TS, Elicker BM, White D, Vittinghoff E, et al. The use of pretest probability increases the value of high-resolution CT in diagnosing usual interstitial pneumonia. Thorax 2017;72:424–429.
48. Flaherty KR, Toews GB, Lynch JP 3rd, Kazerooni EA, Gross BH, Strawderman RL, et al. Steroids in idiopathic pulmonary fibrosis: a prospective assessment of adverse reactions, response to therapy, and survival. Am J Med 2001;110:278–282.
49. Parambil JG, Myers JL, Ryu JH. Histopathologic features and outcome of patients with acute exacerbation of idiopathic pulmonary fibrosis undergoing surgical lung biopsy. Chest 2005;128:3310–3315.
50. Collard HR, Ryu JH, Douglas WW, Schwarz MI, Curran-Everett D, King TE Jr, et al. Combined corticosteroid and cyclophosphamide therapy does not alter survival in idiopathic pulmonary fibrosis. Chest 2004;125:2169–2174.
51. Pereira CA, Malheiros T, Coletta EM, Ferreira RG, Rubin AS, Otta JS, et al. Survival in idiopathic pulmonary fibrosis-cytotoxic agents compared to corticosteroids. Respir Med 2006;100:340–347.
52. Tashkin DP, Elashoff R, Clements PJ, Goldin J, Roth MD, Furst DE, et al. Cyclophosphamide versus placebo in scleroderma lung disease. N Engl J Med 2006;354:2655–2666.
53. Keir GJ, Maher TM, Ming D, Abdullah R, de Lauretis A, Wickremasinghe M, et al. Rituximab in severe, treatment-refractory interstitial lung disease. Respirology 2014;19:353–359.
54. Mason DP, Brizzio ME, Alster JM, McNeill AM, Murthy SC, Budev MM, et al. Lung transplantation for idiopathic pulmonary fibrosis. Ann Thorac Surg 2007;84:1121–1128.
55. King TE Jr, Bradford WZ, Castro-Bernardini S, Fagan EA, Glaspole I, Glassberg MK, et al. A phase 3 trial of pirfenidone in patients with idiopathic pulmonary fibrosis. N Engl J Med 2014;370:2083–2092.
56. Richeldi L, du Bois RM, Raghu G, Azuma A, Brown KK, Costabel U, et al. Efficacy and safety of nintedanib in idiopathic pulmonary fibrosis. N Engl J Med 2014;370:2071–2082.
57. Collins BF, Raghu G. Antifibrotic therapy for fibrotic lung disease beyond idiopathic pulmonary fibrosis. Eur Respir Rev 2019;28:190022
58. Lamas DJ, Kawut SM, Bagiella E, Philip N, Arcasoy SM, Lederer DJ. Delayed access and survival in idiopathic pulmonary fibrosis: a cohort study. Am J Respir Crit Care Med 2011;184:842–847.
59. Maher TM, Strek ME. Antifibrotic therapy for idiopathic pulmonary fibrosis: time to treat. Respir Res 2019;20:205
60. Rosas IO, Ren P, Avila NA, Chow CK, Franks TJ, Travis WD, et al. Early interstitial lung disease in familial pulmonary fibrosis. Am J Respir Crit Care Med 2007;176:698–705.
61. Copley SJ, Wells AU, Hawtin KE, Gibson DJ, Hodson JM, Jacques AE, et al. Lung morphology in the elderly: comparative CT study of subjects over 75 years old versus those under 55 years old. Radiology 2009;251:566–573.
62. Lederer DJ, Enright PL, Kawut SM, Hoffman EA, Hunninghake G, van Beek EJ, et al. Cigarette smoking is associated with subclinical parenchymal lung disease: the Multi-Ethnic Study of Atherosclerosis (MESA)-lung study. Am J Respir Crit Care Med 2009;180:407–414.
63. Gückel C, Hansell DM. Imaging the ‘dirty lung’--has high resolution computed tomography cleared the smoke? Clin Radiol 1998;53:717–722.
64. Gochuico BR, Avila NA, Chow CK, Novero LJ, Wu HP, Ren P, et al. Progressive preclinical interstitial lung disease in rheumatoid arthritis. Arch Intern Med 2008;168:159–166.
65. Miller ER, Putman RK, Vivero M, Hung Y, Araki T, Nishino M, et al. Histopathology of interstitial lung abnormalities in the context of lung nodule resections. Am J Respir Crit Care Med 2018;197:955–958.
66. Hatabu H, Hunninghake GM, Lynch DA. Interstitial lung abnormality: recognition and perspectives. Radiology 2019;291:1–3.
67. Washko GR, Lynch DA, Matsuoka S, Ross JC, Umeoka S, Diaz A, et al. Identification of early interstitial lung disease in smokers from the COPDGene Study. Acad Radiol 2010;17:48–53.
68. Washko GR, Hunninghake GM, Fernandez IE, Nishino M, Okajima Y, Yamashiro T, et al. Lung volumes and emphysema in smokers with interstitial lung abnormalities. N Engl J Med 2011;364:897–906.
69. Hunninghake GM, Hatabu H, Okajima Y, Gao W, Dupuis J, Latourelle JC, et al. MUC5B promoter polymorphism and interstitial lung abnormalities. N Engl J Med 2013;368:2192–2200.
70. Doyle TJ, Washko GR, Fernandez IE, Nishino M, Okajima Y, Yamashiro T, et al. Interstitial lung abnormalities and reduced exercise capacity. Am J Respir Crit Care Med 2012;185:756–762.
71. Araki T, Putman RK, Hatabu H, Gao W, Dupuis J, Latourelle JC, et al. Development and progression of interstitial lung abnormalities in the Framingham Heart Study. Am J Respir Crit Care Med 2016;194:1517–1522.
72. Putman RK, Hatabu H, Araki T, Gudmundsson G, Gao W, Nishino M, et al. Association between interstitial lung abnormalities and all-cause mortality. JAMA 2016;315:672–681.
73. Richeldi L, Collard HR, Jones MG. Idiopathic pulmonary fibrosis. Lancet 2017;389:1941–1952.
74. Silva CI, Müller NL, Hansell DM, Lee KS, Nicholson AG, Wells AU. Nonspecific interstitial pneumonia and idiopathic pulmonary fibrosis: changes in pattern and distribution of disease over time. Radiology 2008;247:251–259.
75. Tsushima K, Sone S, Yoshikawa S, Yokoyama T, Suzuki T, Kubo K. The radiological patterns of interstitial change at an early phase: over a 4-year follow-up. Respir Med 2010;104:1712–1721.
76. Sverzellati N, Guerci L, Randi G, Calabrò E, La Vecchia C, Marchianò A, et al. Interstitial lung diseases in a lung cancer screening trial. Eur Respir J 2011;38:392–400.
77. Jin GY, Lynch D, Chawla A, Garg K, Tammemagi MC, Sahin H, et al. Interstitial lung abnormalities in a CT lung cancer screening population: prevalence and progression rate. Radiology 2013;268:563–571.
78. Putman RK, Rosas IO, Hunninghake GM. Genetics and early detection in idiopathic pulmonary fibrosis. Am J Respir Crit Care Med 2014;189:770–778.
79. Hunninghake GM. Interstitial lung abnormalities: erecting fences in the path towards advanced pulmonary fibrosis. Thorax 2019;74:506–511.
80. Antoniou KM, Tzilas V, Vasarmidi E, Symvoulakis EK, Tzouvelekis A, Bouros D. Interstitial lung abnormalities: ignotum per ignotius. Lancet Respir Med 2019;7:376–378.
81. Hoyer N, Thomsen LH, Wille MMW, Wilcke T, Dirksen A, Pedersen JH, et al. Increased respiratory morbidity in individuals with interstitial lung abnormalities. BMC Pulm Med 2020;20:67
82. Hoyer N, Wille MMW, Thomsen LH, Wilcke T, Dirksen A, Pedersen JH, et al. Interstitial lung abnormalities are associated with increased mortality in smokers. Respir Med 2018;136:77–82.
83. Whittaker Brown SA, Padilla M, Mhango G, Powell C, Salvatore M, Henschke C, et al. Interstitial lung abnormalities and lung cancer risk in the National Lung Screening Trial. Chest 2019;156:1195–1203.
84. Putman RK, Hunninghake GM, Dieffenbach PB, Barragan-Bradford D, Serhan K, Adams U, et al. Interstitial lung abnormalities are associated with acute respiratory distress syndrome. Am J Respir Crit Care Med 2017;195:138–141.
85. Wolters PJ, Collard HR, Jones KD. Pathogenesis of idiopathic pulmonary fibrosis. Annu Rev Pathol 2014;9:157–179.
86. Chilosi M, Poletti V, Murer B, Lestani M, Cancellieri A, Montagna L, et al. Abnormal re-epithelialization and lung remodeling in idiopathic pulmonary fibrosis: the role of deltaN-p63. Lab Invest 2002;82:1335–1345.
87. Mohning MP, Richards JC, Huie TJ. Idiopathic pulmonary fibrosis: the radiologist’s role in making the diagnosis. Br J Radiol 2019;92:20181003
88. Watadani T, Sakai F, Johkoh T, Noma S, Akira M, Fujimoto K, et al. Interobserver variability in the CT assessment of honeycombing in the lungs. Radiology 2013;266:936–944.
89. Staats P, Kligerman S, Todd N, Tavora F, Xu L, Burke A. A comparative study of honeycombing on high resolution computed tomography with histologic lung remodeling in explants with usual interstitial pneumonia. Pathol Res Pract 2015;211:55–61.
90. Piciucchi S, Tomassetti S, Ravaglia C, Gurioli C, Gurioli C, Dubini A, et al. From “traction bronchiectasis” to honeycombing in idiopathic pulmonary fibrosis: a spectrum of bronchiolar remodeling also in radiology? BMC Pulm Med 2016;16:87
91. Johkoh T, Müller NL, Colby TV, Ichikado K, Taniguchi H, Kondoh Y, et al. Nonspecific interstitial pneumonia: correlation between thin-section CT findings and pathologic subgroups in 55 patients. Radiology 2002;225:199–204.
92. Jacob J, Aksman L, Mogulkoc N, Procter AJ, Gholipour B, Cross G, et al. Serial CT analysis in idiopathic pulmonary fibrosis: comparison of visual features that determine patient outcome. Thorax 2020;75:648–654.
93. Sumikawa H, Johkoh T, Colby TV, Ichikado K, Suga M, Taniguchi H, et al. Computed tomography findings in pathological usual interstitial pneumonia: relationship to survival. Am J Respir Crit Care Med 2008;177:433–439.
94. Yamauchi H, Bando M, Baba T, Kataoka K, Yamada Y, Yamamoto H, et al. Clinical course and changes in high-resolution computed tomography findings in patients with idiopathic pulmonary fibrosis without honeycombing. PLoS One 2016;11:e0166168
95. Edey AJ, Devaraj AA, Barker RP, Nicholson AG, Wells AU, Hansell DM. Fibrotic idiopathic interstitial pneumonias: HRCT findings that predict mortality. Eur Radiol 2011;21:1586–1593.
96. Walsh SL, Sverzellati N, Devaraj A, Wells AU, Hansell DM. Chronic hypersensitivity pneumonitis: high resolution computed tomography patterns and pulmonary function indices as prognostic determinants. Eur Radiol 2012;22:1672–1679.
Takuya Hino
Center for Pulmonary Functional Imaging, Department of Radiology, Brigham and Women\'s Hospital and Harvard Medical School, Boston, MA
Kyung Soo Lee
Department of Radiology, Samsung Medical Center, Sungkyunkwan University School of Medicine (SKKU-SOM), Seoul
Joungho Han
Department of Pathology, Samsung Medical Center, Sungkyunkwan University School of Medicine (SKKU-SOM), Seoul
Akinori Hata
Center for Pulmonary Functional Imaging, Department of Radiology, Brigham and Women\'s Hospital and Harvard Medical School, Boston, MA
Kousei Ishigami
Department of Clinical Radiology, Graduate School of Medical Sciences, Kyushu University, Fukuoka
Hiroto Hatabu
Center for Pulmonary Functional Imaging, Department of Radiology, Brigham and Women\'s Hospital and Harvard Medical School, Boston, MA
© 2021. This work is published under http://creativecommons.org/licenses/by-nc/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.
Details
; Lee, Kyung Soo
; Han, Joungho
; Hata, Akinori
; Ishigami, Kousei
; Hatabu, Hiroto