Risk factors and basic mechanisms of chronic thromboembolic pulmonary hypertension: a current understanding

DEFINITION

CTEPH is defined by the following observations after ≥3 months of effective anticoagulation [13]: 1) mean pulmonary arterial pressure >25 mmHg with a pulmonary capillary wedge pressure ≤15 mmHg; and 2) at least one (segmental) perfusion defect detected by lung scanning, multi-detector computed tomographic angiography or pulmonary angiography.

THE THROMBOEMBOLIC CONCEPT

Although CTEPH is considered a venous thromboembolic disorder, classic thromboembolic plasmatic risk factors are lacking. Over the past few years, several important observations and clarifications have been made with regard to a better understanding of the disease [1]. In previous pathology series, <50% of patients had an identifiable coagulation, autoimmune or haematological abnormality [14, 15]. However, the European CTEPH Registry has recently revealed that previous PE is detected in 74.8% of all CTEPH patients while previous deep venous thrombosis (DVT) is documented in 56.1% of patients [16]. Based on these data, it appears adequate to view CTEPH as a sequela of classical thromboembolism that is modified by misguided thrombus resolution leading to occlusive vascular remodelling (fig. 1) in proximal and distal vessels. Moreover, some, but not all, risk factors of recurrent VTE are present, such as elevated factor VIII (FVIII) [17] and lupus anticoagulant (LAC)/antiphospholipid antibodies (APAs) [18]. In contrast to pulmonary arterial hypertension (PAH) involving vessels <300 μm in diameter, CTEPH typically affects major vessels [13] and is therefore amenable to surgical removal of the obstructions [19], i.e. pulmonary endarterectomy (PEA). Figure 2 shows a typical specimen surgically removed from a CTEPH patient, representing a cast of the pulmonary vascular bed, consisting of endothelial cells, smooth muscle cells, fibroblasts and fresh thrombus by histological examination [1]. While the concept of major-vessel disease (i.e. CTEPH) and small-vessel disease (i.e. PAH) sounds intriguing, there are cases of CTEPH overlapping with PAH, in that they are characterised by distal thromboembolic lesions and a typical pulmonary arteriopathy. Depending on the assessment of the surgical team, those cases are classified as inoperable CTEPH.

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Figure 1–

Scheme of the pathophysiological concept of chronic thromboembolic pulmonary hypertention. VTE: venous thromboembolism; PE: pulmonary embolism.

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Figure 2–

Major vessel obstructions (“acute and chronic clot”) removed by pulmonary endarterectomy from the right and left pulmonary artery. Scale bar=1 cm.

COAGULATION AND FIBRINOLYSIS

A low incidence of CTEPH after PE, a lack of symptomatic PE in ≥25% of patients with CTEPH and the absence of classical thromboembolic risk factors challenges the link between PE and CTEPH [1, 20, 21]. For example, a deficiency of antithrombin, protein C and protein S, the G20210A mutation of prothrombin and hyperhomocysteinaemia are not associated with CTEPH. The factor V R506Q mutation (factor V Leiden) is not more common in CTEPH [18]. However, in a recent retrospective study, factor V Leiden was more frequent in CTEPH than in other PH (29% versus 7.8%; p=0.001), and the prothrombin mutation was more frequent in CTEPH, albeit not significantly [22]. Factor V mutation prevalence is dependent on the populations that are studied. The association between combined defects and CTEPH is anecdotal [23]. LACs/APAs and the coagulation factor FVIII have been found associated with VTE and CTEPH [13, 18, 21, 22, 24, 25].

APAs have been detected in patients with various forms of PH, but usually in low titres. High APA titres were found in CTEPH patients, and high titres were associated with LAC [18]. In patients with CTEPH, the detection of LAC suggests a prothrombotic state; this may not be true in patients with nonthromboembolic PH in whom other immunological and inflammatory mechanisms may be involved [26, 27]. The finding of multiple positive tests in CTEPH patients is of interest because of a recent publication illustrating a higher risk of VTE recurrence in triple-positive tests [28, 29].

Plasma concentrations of FVIII and von Willebrand factor antigen (VWF:Ag) were measured in 122 consecutive patients with CTEPH, in 88 patients with nonthromboembolic PAH, and in 82 age- and sex-matched healthy controls [17]. Elevated VWF:Ag and FVIII (>230 IU·dL⁻¹) were more common in patients with CTEPH than in both PAH patients and controls (41% versus 5% and 22%, respectively). After successful PEA, no decrease in FVIII plasma concentrations occurred; in contrast, plasma FVIII decreases after alleviation of PH by prostanoid treatment [30]. These data suggest that elevated values of FVIII in patients with CTEPH might be causal to the disease process.

Acute episodes of VTE may be associated with the risk of developing CTEPH. In a prospective cohort study, 305 patients with symptomatic VTE were recruited, 223 with a first episode of PE, 58 with previous DVT and 24 with previous PE [8]. The incidence of CTEPH in the first group was 3.8% within the first 2 yrs of follow-up. In the other two groups, cumulative incidences of CTEPH were 5.2% and 33.3%, respectively. In the multivariate logistic regression model, younger age (OR 1.79, 95% CI 1.23–2.56), previous PE (OR 19, 95% CI 4.5–79.8), an idiopathic clinical presentation of PE (OR 5.70, 95% CI 1.41–22 .97) and larger perfusion defects at the time of PE diagnosis (OR 2.22, 95% CI 1.49–3.31) were associated with an increased risk of CTEPH [8]. In a recent smaller prospective cohort study on 110 patients with acute PE, CTEPH incidence was 9.1% within 2 yrs; six (5.4%) cases were diagnosed during variable clinical follow-up and the remaining cases were diagnosed on the basis of echocardiographic and clinical findings at 2 yrs from the index event [11]. In the multivariate regression model older age (relative risk (RR) 1.2 per year, 95% CI 1.0–1.3) and a combination of previous and recurrent PE were found to be associated with CTEPH (RR 5.7, 95% CI 1.5–22.0). In a large retrospective cohort study, 687 consecutive patients with PH were enrolled in four large European databases [25]. 433 of these patients were diagnosed with CTEPH and 254 with nonthromboembolic PH. A logistic regression analysis was performed in 585 patients showing that both previous and recurrent VTE were significantly associated with an increased risk of CTEPH (OR 4.52, 95% CI 2.35–9.12 and OR 14.49, 95% CI 5.40–43.08, respectively). Even chronic venous ulcers, which can be viewed as the late sequelae of DVT, were more common in CTEPH patients (OR 2.84, 95% CI 0.99–9.00).

In a prospective cohort study on 254 subjects observed for a median 3.8 yrs after a first episode of acute PE, 0.8% developed CTEPH [3]. Interestingly, this incidence increased to 1.5% if only patients with an idiopathic clinical presentation of PE were considered, which is similar to that observed by Pengo et al. [8], although no VTE recurrences were observed in patients diagnosed with CTEPH. However, the exclusion of both cancer patients and those with major thrombophilic disorders, the relatively low severity of acute PE episodes and the very careful management of anticoagulant therapy may have influenced the true incidence of CTEPH. In another prospective cohort study of 834 subjects with suspected PE, 320 patients with an objectively confirmed diagnosis were followed-up for a median 2.1 yrs [6]. This study was unique in that it performed serial lung scans in all patients. The incidence of CTEPH was 1.3%; the median extent of pulmonary vascular obstruction was almost 60% in patients diagnosed with CTEPH. There was no evidence of recurrent PE in serial lung scans. However, an association between recurrent PE and CTEPH could have been underestimated: 1-yr mortality was high, and three out of four CTEPH patients had had documented episodes of DVT without any objective imaging tests for PE before entering the study. Poli et al. [31] prospectively observed a cohort of 239 patients with a first episode of PE and found a 0.4% CTEPH incidence after a median follow-up of 3 yrs. VTE recurrences and high levels of D-dimer after withdrawal of anticoagulant therapy were not associated with an increased risk of CTEPH. Notably, none of the patients with VTE recurrences had high systolic pulmonary arterial pressure. However, the lack of data about the severity of the index event and the exclusion of patients with cancer introduced a selection bias. In up to 14% of subjects a treatment strategy based on D-dimer testing was adopted in order to reduce VTE recurrences, and this may have affected CTEPH incidence. Klok et al. [5] investigated the occurrence of CTEPH in 866 unselected consecutive patients diagnosed with PE. Provided that a diagnosis of CTEPH was not made, the 588 survivors underwent an echocardiographic study after a median time of 3.7 yrs after the index event; in case of suspected CTEPH a diagnostic procedure was performed for confirmation purposes. The cumulative incidence of CTEPH was 0.57% in the overall population and 1.5% in patients with unprovoked PE. Recurrent PE was not associated with a higher risk of developing CTEPH. However, a lack of data related to the acute index event, variable duration of follow-up and the exclusion of ∼30% of eligible subjects significantly limited the power of detecting CTEPH.

Riedel et al. [20] assessed haemodynamics at ≥2 months after acute PE in 76 patients. A haemodynamic investigation was subsequently performed in subjects surviving 1–15 yrs after the first examination [32]. The detection of a mean pulmonary artery pressure >30 mmHg at baseline was associated with a further increase during follow-up (from 47.1±14.6 to 55.3±10.1 mmHg, p<0.05), while normal mean pulmonary artery pressures showed no late increase.

In a small prospective cohort study Ribeiro et al. [7] performed serial echocardiographic examinations within 1 yr of the acute event in 78 patients who were subsequently followed over 5 yrs. The detection of systolic pulmonary artery pressures >50 mmHg at the time of the initial diagnosis of PE was associated with a three-fold increase in the risk of PH at 1 yr [7]. Notably, three out of four patients with persistent PH underwent PEA. The detection of right ventricular dysfunction during the acute phase of PE in a cohort of 301 patients with a first acute episode of PE was associated with an almost four-fold risk of VTE recurrences after a 3-yr follow-up (hazard ratio 3.79, 95% CI 1.8–7.8) [33]. However, the question remains whether early detection of significantly elevated pulmonary arterial pressures is related to true acute PE with right ventricular strain, or to an early manifestation of CTEPH.

Taken together, currently available evidence confirms that at least some prothrombotic risk factors of acute and recurrent VTE are prevalent in CTEPH patients, while fibrinolytic factors have been shown to be bystanders rather than mediators of the disease [34]. In general, the clinical presentation of the acute PE episode, and possibly VTE recurrences, increase the risk of developing CTEPH. Recent studies have demonstrated that persistent residual thrombotic material in the deep venous system is associated with a higher risk of VTE recurrences and identify a subgroup of patients in whom prolonging anticoagulant therapy is beneficial [35].

Current evidence suffers from several limitations: patient cohorts are heterogeneous and their mortality rates variable; studies are often retrospective and not adequately controlled; the severity of the initial embolic episode is often unknown; and it is very hard to exclude pre-existing PH. However, the recent description of the European patient cohort indicating that previous PE was confirmed in three-quarters of patients and previous VTE was observed in half of them provides firm evidence for the thromboembolic nature of the disease, despite continued controversy over this issue [36].

OTHER RISK FACTORS

Nonplasmatic risk factors such as splenectomy, ventriculo–atrial (VA) shunt for hydrocephalus therapy, inflammatory bowel disease and chronic osteomyelitis are associated with a higher incidence and a worse prognosis of CTEPH [21, 25, 37]. In a recent retrospective database involving three European PEA centres, data from 687 CTEPH patients were compared with nonthromboembolic precapillary PAH cohorts at the participating institutions. VA shunts and infected pacemakers (OR 76.40, 95% CI 7.67–10351; p<0.001), splenectomy (OR 17.87, 95% CI 1.56–2438; p=0.017), and non-O blood groups (OR 2.09, 95% CI 1.12–3.94; p=0.019) were more often associated with CTEPH. Thyroid replacement therapy (OR 6.10, 95% CI 2.73–15.05; p<0.001) and a history of malignancy (OR 3.76, 95% CI 1.47–10.43; p=0.005) emerged as novel CTEPH risk factors. Recent data from the French PH programme reporting on 17 cases of Port-A-Cath® (Smiths Medical, Grasbrunn, Germany) central venous access systems entailing CTEPH [38] with 30% culture-positive for Staphylococcus epidermidis lends support to the concept of infected intravenous lines as a pathological trigger for CTEPH.

PATHOPHYSIOLOGICAL CONCEPTS AND ANIMAL MODELS

VASCULAR PATHOBIOLOGY

According to current knowledge, CTEPH emerges as a “dual” pulmonary vascular disorder with thrombosis inducing major vessel vascular remodelling, combined with a small pulmonary vessel disease (pulmonary arteriopathy) [1, 58]. Vascular lesions comprise distal extension of muscularisation, concentric laminar intimal fibroelastosis and eccentric intimal fibrosis, medial hypertrophy and occasional plexiform lesions. The latter appear to predominate in areas with patent feeding vessels (fig. 3a), while in areas distal to stenotic or occluded vessels a paucity of vessels is observed (fig. 3b). Pulmonary arteriopathy in CTEPH patients is currently interpreted as the sequela of combined endothelial dysfunction with abnormal accumulation of asymmetric dimethylarginine [59], abnormal proliferation of smooth muscle and endothelial cells, fibroblast and smooth muscle cell migration, inhibited apoptosis in vascular smooth muscle cells and in situ thrombosis [60, 61]. Key players in this disturbance are prostacyclin and prostacyclin synthase, which have been found deficient in PAH, and physiologically counteract the effects of RhoA/Rho-kinases, small intracellular guanosine triphosphatases having important signalling functions on tissue factor expression, nuclear factor-κB induction and cyclin D transcription. It is not known whether the degree of small-vessel disease may be related to the length of time a patient has PH before diagnosis of CTEPH [62]. Recent data suggest that the incidence of small-vessel disease may be greater in patients with associated medical conditions [37], e.g. VA shunts for the treatment of hydrocephalus, splenectomy, inflammatory bowel disease, low-grade malignancy and thyroid replacement therapy. In addition, pulmonary vascular reactivity, which is thought to reflect the functional responsiveness of resistance vessels, parallels prognosis [63]. In greater detail, a decrease in mean pulmonary artery pressure of ≥10% after administration of inhaled nitric oxide at diagnostic right heart catheterisation is a predictor of better prognosis. Recently, the observation of infection with staphylococcal species has been demonstrated both in vivo [38, 57] and in a detailed analysis involving a mouse model of stagnant-flow venous thrombosis [57]. Staphylococcus aureus or Staphylococcus epidermidis is responsible for up to half of device infections, and bacterial pathogens promote fibrotic wound healing [64]. In the mouse model, staphylococcal infection delayed thrombus resolution in parallel with upregulation of TGF-β and connective tissue growth factor, laying grounds for the assumption that thrombus infection may be associated with thrombus nonresolution. Based on these data, one may speculate that timely antibiotic treatment of major VTE may prevent the development of CTEPH.

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Figure 3–

“Secondary vascular disease” of chronic thromboembolic pulmonary hypertension observed in lung biopsies obtained during pulmonary endardectomy in the course of a clinical study. a) Trichrome stain of small pulmonary arteries <200 μm in diameter with intimal fibrosis and smooth muscle hypertrophy; b) lung specimen from a lobe dependent upon a completely occluded main pulmonary artery. Note a paucity of vessels. Existing vessels do not display smooth muscle cell hypertrophy and intimal lesions. Both lung specimens are from the same patient (different from that shown in fig. 2). Scale bars=200 μm.

Pulmonary vascular wall thickening in CTEPH patients may be due to proliferation of adventitial fibroblasts, circulating progenitor/precursor cells and/or myofibroblasts, creating fibrous plaques with angioneogenesis and cholesterol-containing atherosclerotic plaques [65]. In a large series of thromboembolic obstructions analysed at the University of California at San Diego (San Diego, CA, USA), remodelling of thrombi at various stages, granulomas associated with sarcoidosis, and a rare case showing features of inflammatory myofibroblastic tumour, primary or metastatic malignancies, and isolated pulmonary arteritis were observed [58]. In 15% of cases significant inflammation was noted [14]. The role of inflammation in CTEPH pathogenesis has been emphasised by studies illustrating the expression of the CRP receptor LOX-1 on cells isolated from the major pulmonary vessels in CTEPH [27]. The cells isolated from endarterectomised tissue from CTEPH patients displayed diverse morphological phenotypes. Immunofluorescent staining using the smooth muscle cell (SMC) marker smooth muscle α-actin was detected in most of the cells; however, some cells showed defined actin filament structures, some a more general cytoplasmic staining and others very weak staining. Cells stained very strongly with the fibroblast marker vimentin in addition to markers typical of more primitive mesenchymal precursor/progenitor cells, some of them with hyperproliferative, anchorage-independent, invasive and serum-independent features [66]. Furthermore, RT-PCR confirmed the presence of mRNA transcripts indicating primitive cell types. In vitro, it was demonstrated that myofibroblast-like cells harvested from PEA specimens induced endothelial-to-mesenchymal transition that was effectively inhibited by rapamycin [44]. Similar proliferative features were observed in cells isolated and cultured from the proximal pulmonary arteries during PEA [67]. The data suggest that enhanced or deregulated differentiation of progenitor cells into SMC types may occur in occluded vessels, in addition to transmigration or transdifferentiation of adventitial fibroblasts. These mechanisms characterise both vascular remodelling processes observed in CTEPH [43, 68].

CONCLUSION AND OUTLOOK

CTEPH is a unique subset of PH because of the asset of curability. It may therefore also serve as an elegant model for studies of right ventricular function and pulmonary vascular tissues. In Europe, the Association for Research in CTEPH has established a unique database and platform to drive research and education in this important subsection of pulmonary vascular medicine.