Abstract
Pulmonary disease caused by the fungus Aspergillus has traditionally been regarded as belonging to one of the following, apparently distinct, entities: saprophytic aspergilloma; allergic bronchopulmonary aspergillosis (ABPA); and invasive aspergillosis (IPA); which may be further categorised as angioinvasive, acute or chronic airway invasive) [1]. It is not always obvious that there is overlap between these entities, and that in any given patient more than one Aspergillus-related pathological process can co-exist [2]. The aim of this article is to review the clinical and imaging features of the main categories of Aspergillus-related pulmonary disease and, in particular, to highlight the overlap between them.
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Introduction
The recognition of the diversity of diseases caused by Aspergillus in the lung has increased over recent years. Broadly there are three main categories: saprophytic aspergilloma; allergic bronchopulmonary aspergillosis; and invasive aspergillosis [3]. Invasive aspergillosis has been further subdivided in recent years to angioinvasive and airway invasive aspergillosis [4, 5]. The form that Aspergillus lung disease takes is heavily dependent on the immune response of the patient [6]. Indolent forms of locally invasive aspergillosis in the form of chronic necrotising or semi-invasive aspergillosis in apparently immune competent individuals are now recognised [7]. There is considerable, and sometimes surprising, overlap between the main categories of Aspergillus-related disease, and often more than one form can co-exist (e.g. aspergilloma in allergic bronchopulmonary aspergillosis).
In this review we discuss the issues of classification, the main categories of Aspergillus disease and, more particularly, the potential for overlap between these entities.
Historical background
The Aspergillus genus of moulds was probably first described by Micheli in 1729 [8]. The name probably comes from the similarity between fruiting heads of this particular fungus, and the brush, or aspergillum, used for the sprinkling of holy water.
The spores of the Aspergillus fungus are ubiquitous and are found in the soil, in decaying organic matter, and even in the sand of the Sahara Desert. By far the most common pathogenic species is Aspergillus fumigatus (also a common avian pathogen). There are at least 17 other Aspergillus species known to cause respiratory disease in humans [8, 9].
Reports of human cases of Aspergillus infection date back to the mid-nineteenth century when a post-mortem study described the fungus in the lungs of a patient who died of an undiagnosed pulmonary disease. Aspergillus growing as a fungus ball in tuberculous cavities was first reported in pathological specimens in 1856 by Freidreich. The first English report was by Wheaton in 1890, who described disseminated Aspergillus in the lungs and nodes of a 2-year-old child who died from "pneumonia" [10].
At around this time the term "aspergillosis" referred to any infection of the lung caused by Aspergillus. In 1928 it was suggested that the diagnosis of aspergillosis could be made in symptomatic individuals by the culture of Aspergillus from their sputum [8].
Hemphill in 1936 described the radiological appearance of a "loose body within a cavity which shifted with change of position" in a patient with previous tuberculous disease. The "loose body" was shown at resection to be composed of mycotic material [11]. Twinning and Kerley later illustrated this in their radiological text, and coined the term "mycetoma" [12]. Hinson et al. in 1952 described three patients with wheezy bronchitis, fever, consolidation, peripheral eosinophilia and bronchi plugged by viscid secretions containing scanty Aspergillus fumigatus hyphae. They termed this allergic bronchopulmonary aspergillosis [8]. In their report they segregated Aspergillus pulmonary disease into three groups, and it is this basic clinical classification that is still used presently: (a) saprophytic growth in cavities (mycetoma); (b) allergic bronchopulmonary aspergillosis (ABPA); and (c) invasive aspergillosis [8]. Finegold et al. subsequently modified this classification subdividing the aspergilloses into primary (absence of underlying disease or other predisposing factors), and secondary (associated with a pre-existing lung disease or host immune deficiency; see Table 1) [13]. This classification was confusing, and with the discovery of a more indolent invasive form of Aspergillus (semi-invasive/chronic necrotising aspergillosis) a modified version of the classification of Hinson et al. [8] was proposed by Gefter [6]. More recent literature, in particular CT studies, have further subdivided invasive aspergillosis into angioinvasive and airway invasive (Table 1). It has become increasingly evident over the past decade that Aspergillus colonisation or infection, and its consequences, may be highly variable and complex, and depend to a large extent on local and systemic host immunity [6, 14].
Immune considerations
Local response to inhaled Aspergillus spores in the normal host involves alveolar macrophage phagocytosis which kills the spores before they convert to potentially invasive hyphal forms. Germinating spores and hyphal forms which are too large in size to be phagocytosed by macrophages are inactivated by neutrophils [15].
Aspergillus colonises cavities in the lung where conditions are favourable for growth, and where local host defences are impaired (particularly in large avascular cavities and bronchiectactic airways).
Qualitative and quantitative deficiencies in neutrophil function can allow hyphal growth and invasion, initially through the bronchiole walls, with subsequent invasion of blood vessels and systemic dissemination.
Immunocompromised patients, particularly with neutropaenia, are susceptible to acute airway invasive and angioinvasive aspergillosis in the absence of pre-existing lung pathology. Patients with modest immunodeficiency (e.g. an elderly patient with a connective tissue disorder), with or without pre-existing local lung pathology, are susceptible to localised chronic airway invasive Aspergillus infection [1, 7].
Patients may also exhibit a hyperimmune response to Aspergillus. Allergic bronchopulmonary aspergillosis is usually encountered in asthmatics, and is characterised by both type-I and type-III immune reactions to Aspergillus. Type-I reaction results in elevated serum IgE, eosinophilia in the blood, sputum, and lung tissue, and immediate skin test reactivity to Aspergillus antigens. Confusingly, approximately 25% of patients with chronic asthma show an immediate cutaneous reactivity to Aspergillus species, whether or not they have other features of ABPA; however, patients with ABPA have consistently far greater levels of isotypic antibodies to Aspergillus fumigatus ( IgE-a-Af, IgG-a-Af, and IgA-a-Af) than patients with allergic asthma or non-atopic controls [16]. The immune complex driven type-III reactions accounts for a positive late (Arthrus) skin reaction. The combination of these two immune responses leads to a marked inflammatory reaction with consequent bronchospasm, bronchial oedema, bronchial plugging, bronchial wall damage, and bronchiectasis [6]. Hyphae grow in the thickened bronchial secretions perpetuating reaction and damage. Aspergillus fumigatus, the usual culprit in ABPA, produces a chymotrypsin-like proteinase which causes bronchial epithelial damage [17]. There are also some features of a type-IV (cell-mediated) reaction producing a granulomatous reaction. In advanced cases severe granulomatous fibrosis supervenes. Up to one-third of cases of bronchocentric granulomatosis are associated with ABPA. It is thought to represent a response to endobronchial aspergillosis [18]. This is reflected by the abundance of eosinophils at the site of inflammation in pathological specimens [19].
Immediate hypersensitivity may also be seen as a reaction to Aspergillus, where Aspergillus acts as an inhaled antigen similar to other organic dusts producing an allergic alveolitis (hypersensitivity pneumonitis). This reaction is mediated by type I (IgE) with contributions from cell-mediated (type IV) and immune complex (type III), and can be seen in some asthmatic patients inhaling a heavy spore load [20, 21].
Although it is clear that immune defects play a central role in the evolution of invasive aspergillosis, a few cases of invasive aspergillosis in apparently healthy individuals are described in the literature [22, 23, 24, 25]. It seems likely that such patients have an occult immune deficiency, but this is a matter of speculation.
The predominant pathology caused by Aspergillus is largely dependent on systemic and local host immunity, the presence or absence of pre-existing parenchymal lung damage, and the load of spores inhaled [2, 3, 6].
Aspergilloma
The term mycetoma is used to describe a mobile fungus ball within a pre-existing, usually fibrotic, lung cavity. Mycetomas are usually caused by Aspergillus (aspergilloma), but other fungi may occasionally be responsible including Candida, streptomycetes, coccidioides and phycomycetes [6]. Pathologically, aspergillomas consist of a tangled growth of Aspergillus hyphae admixed with mucous and cellular debris in a cavity. The cavity wall is often thick and consists of a zone of fibrotic tissue, with necrosis of the inner layer [4, 11]. The cavity wall has a rich blood supply from the bronchial and other branches of the systemic circulation, and thus has a propensity to bleed [26].
Aspergillomas have been most frequently documented as occurring in residual tuberculous cavities. A survey in Britain in 1970 showed that 11–20% of patients with residual tuberculous cavities of 2.5 cm diameter or greater had radiographic evidence of aspergilloma [27]. Aspergillomas are also a common accompaniment to advanced fibrotic disease in sarcoidosis, with up to 53% of such patients having radiographic evidence of aspergillomas [28]. Indeed, any cavity within the lung is a potential focus for the development of aspergilloma, and predisposing conditions include bulla in emphysematous lung [29], cystic spaces from end-stage fibrosis [29], pneumatocoeles caused by Pneumocystis carinii [30], miscellaneous cavitatory infections (e.g. histoplasmosis) [26, 31], bronchogenic/congenital lung cysts [31], Wegener's granulomatosis [32], cavitary pulmonary infarction [29] and lung fibrosis from radiotherapy [26]. The most common location, whatever the predisposing cause, is the upper lobes.
Bronchiectatic airways may also harbour aspergillomas, and the location of the aspergillomas in these cases is more variable. Jewkes et al. found that of 85 patients with symptomatic aspergillomas, 16 patients were within bronchiectatic airways (10 with allergic bronchopulmonary aspergillosis, and 6 with other causes of bronchiectasis) [29].
The typical radiographic appearances are of a rounded mass sitting inside a cavity (usually thick walled), with air around the mass (crescent sign; Fig. 1). The mass is seen to gravitate freely on images of the patient in different positions [11]. The air-crescent sign is often considered to be characteristic of mycetomas but has also been described in bronchogenic carcinoma [33], retained foreign body following thoracotomy [34], haemorrhage into a cavity [35], Wegener's granulomatosis, sclerosing haemangioma [36], echinococcal cyst [37], tuberculosis, and Rasmussen aneurysm in a tuberculous cavity [38]. Confusingly, the air-crescent sign may also be seen in angioinvasive aspergillosis, where it corresponds pathologically to a space caused by retraction of an area of retracted infarcted lung (Fig. 2) [39].The diagnosis of aspergilloma is usually presumptive and made on radiographic findings. An early sign of aspergilloma formation in a cavity is pleural thickening which often antedates the radiographic features of an obvious intracavitary fungus ball [40]. An increase in wall thickness of the lateral aspect of a fibrotic cavity, reflecting a combination of pleural and cavity wall thickening, may be a helpful sign of radiographically cryptic aspergilloma (Fig. 3) [41]. This feature is a reactive phenomenon, with regression of the aspergilloma leading to a normalisation of the pleural thickness [42]. Thin-section CT can demonstrate the early stages of aspergilloma much more readily than chest radiography. Fungal fronds can be seen arising from the cavity wall, often intersecting each other (Fig. 4a). These fronds coalesce and break away from the cavity wall to form a mature fungus ball (Fig. 4b), which may contain small foci of high attenuation, presumably representing calcifications [43]. Not surprisingly, CT also demonstrates additional smaller aspergillomas that are not evident on chest radiograph. Computed tomography is a useful adjunct in cases where an aspergilloma is suspected but the chest radiograph is inconclusive, and in assessment prior to resection (to evaluate the extent of the aspergilloma, and to assess the integrity of the remaining lung). In a few patients aspergillomas appear to regress, sometimes following a superadded bacterial infection [27], but apparently spontaneous resolution has also been reported [44]. The treatment options are dependent on symptomatology, the severity of underlying lung disease and the general condition of the patient. Surgical resection in specialist centres provides the best overall result, but because most patients have advanced diffuse lung disease, few patients are suitable surgical candidates [26, 29, 45]. Other treatment strategies are palliative and involve control of haemopytsis with bronchial embolisation or intracavitary anti-fungal therapy (under CT guidance or fluoroscopy) [46, 47, 48].
Invasive aspergillosis
The term invasive aspergillosis is often used in the context of aggressive disease in immunocompromised patients; however, this form of Aspergillus infection may be more indolent and occurs in patients with mycetoma or ABPA, and in patients with chronic debilitation [1, 7, 49]. By definition, the hyphae invade the adjacent lung parenchyma, first bronchial wall and subsequently the accompanying arterioles. There are two main forms: angioinvasive (predominantly involving invasion of the pulmonary artery branches) and airway invasive (predominantly involving the bronchi and bronchioles); however, given the anatomic proximity of the bronchi and pulmonary arteries, it is not surprising that the two forms co-exist in the same patient, and that it is not always possible to distinguish between the two types. As well as blood dissemination, Aspergillus is seen rarely to invade locally into the adjacent mediastinum or pleura (Fig. 5) [25, 50, 51].
Angioinvasive aspergillosis
Angioinvasive aspergillosis is the classical form of invasive aspergillosis which is characterised clinically by haemorrhagic bronchopneumonia. The hallmark is hyphal invasion of blood vessels with consequent infarction and necrosis [52]. Associated extrapulmonary foci are found in 10–25% of patients at autopsy, with the gastrointestinal tract, brain, heart, liver, spleen and thyroid the most frequently affected organs [23]. Florid angioinvasive aspergillosis is seen almost exclusively in severely immunocompromised patients (particularly those with neutropaenia), most commonly after bone marrow transplant for haematological malignancy, after solid organ transplant, following cytotoxic chemotherapy inducing a neutropaenia, and in a few patients with AIDS.
There have been a few cases described in which the patient had no known prior immunodeficiency. Orr et al. documented two patients with normal host defences dying of disseminated aspergillosis at post-mortem studies (one patient had a previous history of coronary heart disease, and the other acute renal failure following gangrenous appendicitis) [52].
In up to 25% of patients with invasive aspergillosis, the chest radiograph may appear normal [23]. Radiographic abnormalities include: single or multiple nodular infiltrates; segmental or subsegmental consolidation; diffuse ground-glass pattern (often progressing to consolidation); and cavitation (air-crescent sign) [23, 39]. The air-crescent sign in angioinvasive aspergillosis is seen in up to 48% of patients (with biopsy-proven invasive aspergillosis) in the recovery phase [53], and relates to hyphal invasion of blood vessels leading to an area of infarcted lung (sequestrum), in which resorption of necrotic tissue in the periphery or retraction of the sequestrum from viable lung parenchyma leads to a crescent of air surrounding the sequestrum [39]. Cavitation is more likely to occur in larger areas of consolidation or nodules [53], and is associated with a higher risk of massive haemopytsis which may require prophylactic lobar/segmental resection [53, 54]. Cavitation is more frequently seen during the recovery phase of neutropaenia, and it has been postulated that potent proteolytic enzymes are released by the influx of neutrophils, causing tissue destruction with subsequent air-crescent formation [54].
High-resolution CT shows nodules surrounded by areas of ground-glass attenuation (halo sign; Fig. 6), and areas of segmental and non-segmental consolidation with or without a halo [55, 56, 57]. The halo sign represents haemorrhage around a nodule [57, 52, 50] and is seen much earlier (on average 1–2 weeks), and with greater frequency, than the air-crescent sign [56]. In early reports much was made of the sensitivity of the halo sign [55, 56, 57, 58] in immunocompromised patients, and in the appropriate clinical setting it is highly suggestive of angioinvasive aspergillosis; however, this feature has been described in the same group of patients found to have mucormycosis, Candida, cytomegalovirus (CMV) infection, herpes infection, organizing pneumonia and pulmonary haemorrhage [59]. It may also be seen in non-immunocompromised patients with Wegener's granulomatosis, Kaposi's sarcoma and metastatic angiosarcomas [60]. Concomitant infections are not infrequently seen in these patients and include viral infection (CMV, hepatitis B, herpes simplex particularly in the AIDS patients), bacterial infection and other fungal infection (e.g. Candida) emphasising the need for diagnostic confirmation by more definitive means such as bronchoalveolar lavage (BAL) and/or biopsy in patients not responding to empirical systemic antifungal therapy.
i) Airway invasive aspergillosis
The pathological definition of airway invasive aspergillosis is the presence of Aspergillus organisms deep to the basement membrane of the bronchial tree [5]. This form of aspergillosis is divided into: (a) acute airway invasive aspergillosis; and (b) chronic airway invasive aspergillosis (also known as semi-invasive aspergillosis or chronic necrotising aspergillosis [1, 7])
Acute airway invasive aspergillosis
Acute airway invasive aspergillosis occurs most frequently in the same group of immunocompromised patients as angioinvasive aspergillosis, but accounts for less than one-third of all cases of invasive aspergillosis [52]. Acute airway invasive aspergillosis causes a spectrum of disease from acute tracheobronchitis, exudative bronchiolitis and a bronchopneumonia. The radiographic findings in biopsy of autopsy-proven cases include patchy consolidation of lower lobe predominance, ill-defined nodules, and a normal chest radiograph [5]. The HRCT findings mirror the pathogenesis of the disease and include peribronchiolar consolidation, centrilobular micronodules (<5 mm), ground-glass attenuation and lobar consolidation (reflecting an exudative bronchiolitis and air-space infiltration; Fig. 7). Aspergillus is seen deep to the basement membrane of the bronchioles at histology, and is usually seen within the airway lumen [5]. It is noteworthy, but perhaps unsurprising, that positive yield from BAL is more likely in airway- than in angioinvasive aspergillosis (8 of 10 vs 2 of 10, respectively in one study [58]). Occasionally, Aspergillus can invade the trachea and cause pseudomembranous necrotising tracheal aspergillosis which has a high mortality [61]. Imaging features include opacification of paratracheal fat on CT, tracheal narrowing, and pneumomediastinum in immunocompromised patients (including AIDS patients) [61, 62].
ii) Chronic airway invasive aspergillosis
Chronic airway invasive (chronic necrotising/semi-invasive) aspergillosis is a relatively rare condition characterised by an indolent granulomatous cavitatory Aspergillus infection [6] which may mimic reactivation tuberculosis radiographically [1, 6]. The diagnosis relies on biopsy specimens showing local tissue invasion with Aspergillus, and thus it can be argued that this entity should correctly be called the chronic airway invasive form. Tissue necrosis and granulomatous inflammation then ensues. This entity was first described in the early 1980s by Gefter et al. [1] and Binder et al. [7]. Since then, over 100 cases have been reported [1, 7, 14]. Patients present with a variety of symptoms including haemoptysis, sputum production, weight loss and fever.
Over one-third of patients have multiple risk factors (some of which are shown in Table 2) [14]. Radiographically, chronic airway invasive aspergillosis starts as a focus of consolidation (usually in the upper lobes), which progresses with time to cavitation, and subsequent aspergilloma formation with associated adjacent pleural thickening. The process progresses slowly often over months [1, 7, 63]. Patients are treated with systemic antifungals (itraconazole orally, or intravenous amphotericin B), surgery and, in a few cases, intracavity amphotericin B. Mortality is between 10 and 34% (often from the underlying disease of the patient rather than the Aspergillus infection itself) [14]. An interesting observation is the co-existence of chronic airway invasive aspergillosis in a few patients with atypical mycobacterial infection, as the same risk factors apply to both infections [64].
Allergic bronchopulmonary aspergillosis
The complex pathology that characterises ABPA results in tenacious secretions, inflammatory bronchial wall damage and eventually bronchiectasis and fibrosis. It is most often encountered in patients with a history of asthma (of variable severity) [65, 66], but also occurs in patients with cystic fibrosis [67, 68]. Familial occurrence has also been reported [69, 70]. The criteria for a secure diagnosis of ABPA ([71, 72, 73]) are: (a) bronchial asthma; (b) blood eosinophilia (>1000/ul); (c) immediate cutaneous reactivity to Aspergillus fumigatus antigen; (d) precipitating antibodies to Aspergillus fumigatus antigen; (e) elevated serum immunoglobulin IgE concentration; (f) a history of transient or fixed pulmonary infiltrates; (g) central bronchiectasis; and (h) elevated serum IgG and IgE to Aspergillus fumigatus antigen. The diagnosis is usually made on the basis of clinical history, immune criteria, and central bronchiectasis. Only rarely do patients with ABPA exhibit all the diagnostic criteria at any given time (Table 3) [71].
ABPA has been classified into five clinical subgroups [74]: (a) acute stage (classic signs, symptoms, and laboratory findings present at diagnosis); (b) remission (clearing of radiographic abnormalities, a decline in total serum IgE, control of respiratory symptoms, and a discontinuation of steroid therapy over 6 months without exacerbation); (c) recurrent exacerbation (exacerbation of the acute stage, or a twofold rise in serum IgE in association with a new radiographic abnormality); (d) corticosteroid-dependent asthma with exacerbations of ABPA (patients require continuous steroids to control their asthma, and/or control of recurrent exacerbations of ABPA); and (e) fibrotic lung disease (extensive changes on the chest radiograph, which are irreversible). In the early stages of the disease (stages 1–3) the disease is still potentially reversible, but in the later stages (stages 4–5) irreversible parenchymal changes have occurred in the form of central bronchiectasis and fibrosis [75]. The terminology "ABPA-CB" is used when central bronchiectasis is present and "ABPA-Serologic" when it is not [71], but this presupposes that all patients with suspected ABPA undergo an HRCT examination.
Up to 10% of patients with cystic fibrosis have ABPA [67]. In these patients the diagnosis is made from clinical history, positive sputum cultures of Aspergillus, and immune criteria (specific serum positivity to Aspergillus fumigatus, Aspergillus-fumigatus-specific IgE and precipitating antibodies to Aspergillus fumigatus) [68].
The classical radiographic findings of ABPA comprise: fleeting air-space shadows (pathologically, these are probably areas of eosinophilic pneumonia, often with elements bronchocentric granulomatosis; Fig. 8a,b) [18, 76]; tubular—sometimes branching—densities, also known as "toothpaste" and "gloved-finger" shadows (representing mucoid impaction in bronchi; Fig. 8c); "pseudohilar adenopathy" caused by mucous plugging of central bronchi; tram-line shadows; parallel shadows and ring shadows of bronchiectasis [76, 77]. The development of atelectasis and cavitation was shown to occur in 46 and 20% of patients with ABPA, respectively, in one series [78]. Cavitation was observed to occur in patients with a chronic infiltrate, often in the absence of secondary bacterial infection, and was assumed to represent necrosis within the eosinophilic pneumonia [78]. The development of aspergillomas is uncommon but well described and reported in up to 7% of patients with ABPA. Usually, mycetoma occurs in patients with longstanding ABPA with extensive lung destruction [76, 79], although this is not always the case and rapid formation of mycetoma in early ABPA has been described [80].
Central bronchiectasis with normal tapering of distal bronchi was the hallmark in the era of bronchography [81].
High-resolution CT is well suited to showing the distribution, extent, and progression of bronchiectasis in ABPA [82, 83, 84]. In patients with an established clinical and radiological diagnosis of ABPA, HRCT most often demonstrates central bronchiectasis in 95% (central and upper lobe predominance; Fig. 9), although a mixture of central and peripheral is often seen, and occasionally a pattern of lower-lobe cylindrical bronchiectasis, similar to that seen in idiopathic bronchiectasis, is encountered [85]. Other findings on HRCT include centrilobular nodular opacities (tree-in-bud pattern), mucoid impaction, parenchymal consolidation, parenchymal scarring and pleural abnormalities (effusions and minor pleural thickening) [83, 84, 86]. High-attenuation mucous plugging on CT has been described in up to 30% of cases [87], but in practice this is not a conspicuous feature. The cause of high-attenuation mucoid impaction is thought to relate to calcium salts and metal ions within mucoid material, as has been shown in paranasal soft tissue masses related to aspergillosis [88]. In asthmatics a combination of three or more lobes affected with central bronchiectasis (especially the upper lobes), the presence of centrilobular nodules, and mucoid impaction is highly suggestive of ABPA [84].
In a large prospective study by Eaton et al. 20% of asthmatic patients had skin-prick testing positivity to Aspergillus fumigatus; of these, HRCT findings compatible with ABPA were found in 25% [89], emphasising the role of HRCT in the diagnostic work-up in asthmatic patients with possible ABPA.
Aspergillus hypersensitivity pneumonitis
Aspergillus can occasionally produce a hypersensitivity pneumonitis (extrinsic allergic alveolitis). This particular entity is often seen as a consequence of contaminated water sources (particularly hot tubs), but also can be the main antigen in some cases of farmer's lung. It presents in exactly the same manner as other cases of extrinsic allergic alveolitis, with fever, chills, acute shortness of breath, or with progressive shortness of breath in the sub-acute and chronic phases. The radiological picture is that of ground-glass opacity or diffuse small nodules on the chest radiograph, and on CT is that of centrilobular nodules with patchy areas of ground-glass attenuation, and focal patchy air trapping on expiration. Fibrosis is seen in the later phases [90].
Issues of classification and overlap
The degree of overlap between what are often regarded as discrete clinicopathological entities may appear, at first sight, surprising. Although aspergillomas are thought of as an indolent saprophytic growth, cases of subsequent invasive aspergillosis are well described [91, 92]. Another linkage is the development of ABPA following the formation of an aspergilloma [93].
ABPA is set apart from the Aspergillus infections by the observation that the fungal hyhae are confined to the bronchial lumen. In longstanding ABPA the bronchi show marked bronchiectatic change and aspergillomas may form within them. In one series of 111 patients with ABPA radiographic evidence of mycetomas was evident in 8 (probably an underestimate) [76], and 7 of these were located in the midzone of the lung (Fig. 10). The development of aspergillomas can also be seen early in the disease process of ABPA (before bronchiectasis) [80] implying that in some patients they form from direct parenchymal invasion in much the same way as mycetomas resulting from chronic airway invasive aspergillosis. The invasive propensity of Aspergillus, in the context of ABPA, has been carefully described by Riley et al. [94]: the chest radiograph of a patient with longstanding ABPA showed chronic fibrocystic changes in the right upper lobe; the lobe was resected and macroscopically the specimen showed pleural fibrosis, a contracted lobe with gross bronchiectasis and also numerous intrapulmonary nodules and several cavities. Histological examination showed granulomas throughout the lobe both close and distant to the major bronchi; of these, 10% had branching hyphae of Aspergillus within them [94]. This patient had a chronic airway invasive infection with Aspergillus co-existent with ABPA, and this has been described subsequently (Fig. 11) [14]. Not only can hypha invade the lung locally in ABPA, but blood-borne dissemination is also possible (Fig. 12) [95]. This complication has a very high mortality and identification at an early stage is therefore highly desirable. The propensity for Aspergillus to become invasive in ABPA presumably relates to the interplay between degree of pre-existing bronchial wall damage from longstanding ABPA, the amount of Aspergillus fungus in the bronchial tree, and systemic immune factors (including the use of high-dose steroids). Table 4 summarises the overlap between the different forms of Aspergillus infection.
Generally, invasive aspergillosis occurs in immunocompromised patients, as previously described; however, there have been several reports documented in patients with no known prior immunodeficiency, and in patients with only minor immunodeficiency [22, 23, 24, 25]. Lake et al. described a case of fatal disseminated aspergillosis in an asthmatic patient in whom the only immunosuppression was a short course of corticosteroids [96]. Chronic airway invasive aspergillosis starts as an infiltrate with local tissue invasion of Aspergillus which then cavitates, and subsequent aspergilloma formation within the cavity. This form is usually seen in frail patients with a debilitating illness (see Table 2) and is only made following the exclusion of other infections and positive cultures for Aspergillus. Recently, Hafeez et al. described four cases of non-tuberculous mycobacterium infection (three patients were infected with mycobacterium malmoense, and one with mycobacterium avium intracellulare) in whom chronic airway invasive aspergillosis was co-existent [64]. As the same patients' risk factors predispose to both atypical mycobacterial infection and chronic airway invasive aspergillosis, it is not surprising that the two can co-exist. Radiographically, the appearances are similar to chronic airway invasive aspergillosis alone showing consolidation and cavitation in the upper lobes (Fig. 13). Chronic airway invasive aspergillosis should therefore be considered in any patient with a non-tuberculous mycobacterial infection who fails to respond to appropriate therapy [64, 97]. It is interesting that three of the four patients improved on treatment with corticosteroids, and the authors postulate that a local type-III hypersensitivity reaction may contribute to the lung destruction in chronic airway invasive aspergillosis [64].
The form Aspergillus pulmonary infection takes is dependent on local and systemic host immunity, and the presence of underlying lung pathology, both of which can change in any given patient with time and so modify the manifestation of Aspergillus infection. Figure 14 summarises the possible combinations of Aspergillus involvement in the lung.
Conclusion
The spectrum of disease caused by Aspergillus in the lung is wide ranging from hypersensitivity in ABPA, to invasive aspergillosis in the immunocompromised patient, and it is clear that local and systemic host immune factors play an integral role. In practice, most patients can be categorised as having an aspergilloma, ABPA, or invasive aspergillosis. Nevertheless there is a tendency for patients with ABPA, in particular, to develop aspergillomas, and occasionally chronic airway invasive and angioinvasive aspergillosis (see Table 4).
Chronic airway invasive aspergillosis is the preferred term in our classification for the previously described entities of semi-invasive and chronic necrotising aspergillosis as it best fits the underlying pathological process (of local parenchymal invasion with Aspergillus, and hyphae found deep to the basement membrane).
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Buckingham, S.J., Hansell, D.M. Aspergillus in the lung: diverse and coincident forms. Eur Radiol 13, 1786–1800 (2003). https://doi.org/10.1007/s00330-002-1813-4
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DOI: https://doi.org/10.1007/s00330-002-1813-4