Mimickers of chronic thromboembolic pulmonary hypertension on imaging tests: a review

Introduction

Chronic thromboembolic pulmonary hypertension (CTEPH) is caused by mechanical obstruction of major pulmonary arteries due to one or recurrent pulmonary thromboemboli, which is followed by organization of the thrombus and small vessel arteriopathy.^1,2 It is an important reversible cause of pulmonary hypertension (PH), which is frequently underdiagnosed. ¹ CTEPH is classified as group 4 PH by the World Symposium of PH. ³ It is the only form of PH that is potentially curable. Early and accurate recognition is therefore vital to prevent progression and complications like progressive PH, right heart failure and death. ¹ Delayed diagnosis may be associated with a worse prognosis, higher perioperative mortality, and inoperable disease stages. ⁴

The clinical features of CTEPH are non specific and similar to those seen in other forms of PH. Ventilation perfusion (VQ) scanning is the initial screening test of choice to detect CTEPH. Some of the key advantages include, ease of availability and simplicity of interpretation.^5,6 A normal V/Q scan virtually excludes CTEPH. At least one, and more commonly multiple mismatched perfusion defects are seen in patients with CTEPH.^5,7 An abnormal VQ scan should be followed with pulmonary angiography (via computed tomography, magnetic resonance imaging and/or conventional digital subtraction angiography) to confirm the presence of CTEPH. Altered resolution of thrombus in the pulmonary arteries appears as webs, bands, partial recanalization, stenosis, pouch defects and retraction of the vessel with partial or total occlusion. ⁸ However, one need to be cognizant of other causes of PH that can mimic CTEPH due to similarities on imaging tests. ⁵

In this article, we highlight some important clinical as well as radiologic characteristics that can help distinguish CTEPH from other processes that can act as mimickers of this disease (Table 1).

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Table 1.

Salient features of conditions mimicking CTEPH.

	CTEPH Mimic	Similarities on imaging tests	Dissimilarities on imaging tests	Conditions in which the mimic should certainly be considered
1	In situ thrombosis in congenital heart disease	Mosaic attenuation seen but less pronounced Bronchial collaterals seen but less common Central pulmonary artery thrombus	Gross disproportionate enlargement of the central pulmonary arteries Absence of other vascular signs, such as vascular webs, vessel beading or paucity of peripheral arteries, beyond the central pulmonary arteries VQ scan normal or mottled appearance	Patients with congenital heart disease Eisenmenger's physiology
2	Pulmonary artery sarcoma	Perfusion defects on VQ scan Pulmonary arterial intraluminal filling defect	Complete vessel occlusion Expansile mass Extraluminal extension Involvement of pulmonary valve and RVOT Heterogenous attenuation PET avidity Delayed enhancement on CTA and MRI	Increase in thrombus size despite anticoagulation Pulmonary nodules Movement with cardiac cycle
3	Pulmonary vein involvement: a) Fibrosing mediastinitis b) Pulmonary vein stenosis secondary to ablation for atrial fibrillation	a) Mismatched perfusion defects on VQ scan b) Mismatched perfusion defects on VQ scan	a) Mediastinal and hilar soft tissue masses Mediastinal calcification Central pulmonary artery stenosis Pulmonary venous stenosis Airway narrowing Mediastinal lymphadenopathy b) Filling defects in the pulmonary veins Interlobulat septal thickening, pleural effusions, Kerley B lines on CXR	a) Prior history of histoplasmosis History of recurrent pulmonary infections b) Prior history of ablation for atrial fibrillation
4	PVOD	Mosaic attenuation pattern in lung fields	VQ scan normal in most cases Smooth interlobular septal thickening Ground glass opacities Mediastinal lymphadenopathy	Development of pulmonary edema following pulmonary vasodilator therapy
5	Large vessel vasculitis	Collateralization of vessels	Abnormal aortic contour and mural thickening Pulmonary aneurysms Transmural arterial calcification Absent intraluminal thrombus PET avidity	Asian women (Takayasu's arteritis) Visual defects, limb claudication, fever Concomitant presence of stroke, myocardial ischemia
6	Sarcoidosis	Mismatched perfusion defects on a VQ scan Arterial webbing Intimal irregularities Vascular narrowing with post stenotic dilatation	Absence of filling defects in the pulmonary arteries Parenchymal involvement Upper lobe predominance Mediastinal lymphadenopathy causing extrinsic compression	Evidence of sarcoidosis in extra pulmonary organs
7	Malignancy	VQ scan with multiple mismatched perfusion defects	Lymphangitic carcinomatosis PET avidity in some cancers	Significant unintentional weight loss Current or prior malignancy Evidence of metastatic disease Mediastinal lymphadenopathy
8	Congenital anomalies of the pulmonary artery: a) Congenital proximal interruption of the pulmonary artery b) Peripheral pulmonary artery stenosis	a) Unilateral lung volume loss Mismatched perfusion defect on VQ scan b) Mismatched perfusion defects	a) Smooth abrupt cut off of the pulmonary artery within 1 cm of the hilum on CTA Unilateral perfusion defect on VQ scan Absence of findings of pulmonary hypertension b) Congenital anomaly Can be seen in Noonan's, Alagille's or William's syndromes	Presence of other cardiac anomalies

CTEPH: chronic thromboembolic pulmonary hypertension, VQ: ventilation perfusion, RVOT: right ventricular outflow tract, PET: positron emission tomography, CTA: computed tomographic angiography, MRI: magnetic resonance imaging, CXR: chest xray, PVOD: pulmonary veno-occlusive disease

In situ thrombosis

In situ thrombosis of pulmonary arteries resembling chronic thromboembolism on CT scan can occur in patients with congenital heart disease with a left to right shunt (atrial septal defect, ventricular septal defect, patent ductus arteriosus and anomalous pulmonary venous drainage) and severe idiopathic PH.^9,10 Anecdotally, we have also observed in situ thrombosis in patients with advanced pulmonary parenchymal or airway disease and secondary PH with dilated pulmonary arteries. In situ thrombosis is perhaps the most frequent CTEPH mimicker encountered by expert CTEPH centers.

The exact mechanism behind thrombus formation is poorly understood, but it has been hypothesized that multiple factors may play a role. These include shear stress on the vessel wall, chronic stasis in the aneurysmal pulmonary dilations, increase in blood viscosity, chronic hypoxemia and endothelial damage.^9,11,12 In congenital heart diseases, due to progressive right-sided pressure and volume overload from the shunting, there is increase in shear stress which leads to endothelial dysfunction and progressive vascular remodeling; shunt reversal develops over time leading to Eisenmenger's physiology. There is a high risk (21 to 29%) of thrombus formation in this condition.^11,12

Clinically, it is difficult to diagnose in situ thrombosis as patients present with non-specific complaints. Chest radiography may show signs of PH like aneurysmal enlargement of the pulmonary arteries, pulmonary plethora and even pulmonary arterial calcifications (Fig. 1) in long standing cases. ¹² Echocardiography can detect intracardiac shunts, but shunts like sinus venosus defects, patent ductus arteriosus and anomalous venous return may be missed. ¹³ A characteristic feature on CTA is neovascularization or the formation of small intrapulmonary vessels in the subpleural region near the centrilobular arterioles. ¹¹ This will manifest as diffuse ground glass opacities, patchy pulmonary opacities, and atelectasis. ¹⁴ Thrombus can form in the central or distal pulmonary arteries and typically appears as a smooth lining thrombus attached to the artery wall in a vessel that is dilated (Fig. 2). ¹⁵ This appearance of the thrombus can cause difficulty in distinguishing in situ thrombosis from CTEPH. Some features that can point to a diagnosis of CTEPH in these situations is the presence of mosaic attenuation in the lungs, peripheral parenchymal infarcts, and irregular vessel size. ¹⁶ In situ thrombosis is non obstructive, which explains why VQ scans typically do not show perfusion defects (Fig. 2), a big clue to identify this as a non-CTEPH lesion.^15,17 VQ scans will either be normal or show a mottled appearance in patients with PH with in situ thrombosis, whereas in CTEPH it will show segmental or lobar defects. ¹⁰ OPEN IN VIEWER

Fig. 1.

Eisenmenger's syndrome with eccentric mural pulmonary artery calcification.

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Fig. 2.

Panel A and B: Contrast enhanced CT images in a 50-year-old patient with in situ thrombosis in Eisenmenger's syndrome with an unrepaired atrial septal defect demonstrating multiple eccentric filling defects. Unlike typical webs of CTEPH, these are fairly smooth in appearance and the vessel appears normal in caliber. Panel C: Planar ventilation and perfusion images in multiple projections in the same patient. The perfusion images are more homogenous than the ventilation images in general. Multiple matched defects are noted in both lungs such as in the anterior segment of the RUL, RML, Superior segment of the RLL, Anterior segment of LUL, superior segment of the LLLL, and the posteromedial segment of LLL, No segmental mismatched defects are seen in either lungs to suggest CTEPH.

The distinction between CTEPH and in situ thrombosis is critical, as pulmonary endarterectomy would not benefit these patients; it would not lead to any hemodynamic improvement, and will impose considerable surgical risk on these patients. Treatment of in situ thrombosis includes therapy with oxygen, PH-targeted therapies, and anticoagulation.^10,18 Treatment of in situ thrombosis in patients with Eisenmenger's physiology is difficult because these patients have bleeding tendencies due to various reasons like clotting factor deficiencies, abnormal platelet function, and thrombocytopenia. ¹² Anticoagulation can provoke severe hemoptysis in these patients and some experts recommend against its use. ¹²

Pulmonary vein stenosis secondary to ablation for atrial fibrillation

Pulmonary vein stenosis (PVS) is a rare condition that is becoming more common with the advent of radiofrequency ablation as a treatment for atrial fibrillation.^39,40 Other causes include congenital heart disease and mediastinal tumors.^39,40 It is characterized by progressive luminal narrowing of the pulmonary veins. ⁴⁰ PVS can occur days to months following the ablation procedure but the mean has been reported to be somewhere between two and seven months. ⁴¹ Clinically, it can present as shortness of breath, cough, chest pain or hemoptysis in patients with more severe (>50%) stenosis.^40,42 A prior history of ablation should prompt a consideration of pulmonary venous stenosis as a cause of symptoms.

Up to 80% of patients with pulmonary venous stenosis can present with multiple mismatched perfusion defects on a VQ scan due to obstruction to blood flow and mimic pulmonary thromboembolism.^40,43 Due to increased pressures in the pulmonary veins, there is longer blood/contrast transit time in the lung that is drained by the stenosed vein causing decreased perfusion to that part of the lung. ⁴⁴ It can also cause non-opacification of segmental and subsegmental veins of the lung (Fig. 5), which, if mistaken for the pulmonary arteries, can mimic pulmonary thromboembolic disease. ⁴⁴ PVS can present with findings of venous congestion on chest radiography, and demonstrate the presence of Kerley B lines, diffuse interlobular septal thickening, and pleural effusions. ⁴³ These findings are not present in CTEPH. CT-PV protocol with enhancement timed to left atrium is currently the imaging modality of choice for diagnosis of PVS due to its high spatial resolution and multiplanar views that can be obtained in a short scanning time.^39,40 It can be used to distinguish between PVS and CTEPH. MRI can also be used to reliably detect the venous stenotic lesions but is limited by the longer scanning time and lower spatial resolution compared to a CTA.^39,40,44 Transthoracic echocardiography can be used for diagnosing PVS but is not as sensitive as a CTA in adults. ⁴⁴ OPEN IN VIEWER

Management of PVS includes balloon angioplasty with or without stenting in symptomatic cases with severe stenosis.^40,45,46 There are no definite guidelines on the management of asymptomatic patients with severe stenosis; however, a study by Di Biase suggested that an early intervention in these patients is more likely to prevent progression to permanent total venous occlusion and development of severe PH. ⁴⁶ Prognosis of PVS is not favorable and restenosis rates of 25% and 49% have been reported after stenting and balloon angioplasty respectively. ⁴²

Pulmonary veno-occlusive disease/pulmonary capillary hemangiomatosis

Pulmonary veno-occlusive disease and pulmonary capillary hemangiomatosis are rare diseases that occur due to obstruction of the pulmonary veins, venules, or capillaries. ⁴⁷ They are increasingly recognized causes of PH. Both conditions affect young adults with a slight male preponderance for PVOD.^47,48 Clinical presentation mimics most other causes of PH and includes gradually progressive dyspnea, exercise intolerance, and leg edema. Right heart catheterization characteristically shows increase in the pulmonary arterial pressures with a normal or a low wedge pressure. ⁴⁹ Use of a pulmonary vasodilator may lead to acute pulmonary edema due to an increase in the transcapillary pressure gradient secondary to pulmonary arterial vasodilation without concomitant pulmonary venodilation.^47,49

The VQ scan in both these conditions is often normal but there have been reports of a mottled pattern mimicking pulmonary arterial hypertension, multiple mismatched segmental perfusion defects mimicking CTEPH as well as a unilateral large perfusion defect due to asymmetric involvement of the pulmonary veins.^48,50 For example, Bailey et al. ⁴⁸ reported a case series of three patients with high probability VQ scans in patients with PVOD. Seferian et al. ⁵⁰ reported mismatched perfusion defects in 4 out of 56 (7.1%) patients with PVOD. CT findings of PVOD/PCH are fairly useful in differentiating it from CTEPH, and common features include widespread smooth interlobular septal thickening, ground glass centrilobular opacities, and mediastinal adenopathy.^47,51 Pleural effusions and general signs of PH can also be present. ⁴⁸ Pulmonary angiography usually shows dilated pulmonary arteries, normal left atrium, and normal pulmonary veins. ⁴⁸ Compared to other forms of PH, PVOD/PCH presents with a lower DLCO and more severe hypoxemia. ⁵¹

A highly probable diagnosis of PVDO/PCH can be made with right heart catheterization and the classic imaging findings on CT scan along with the typical sings of decreased DLCO and hypoxemia. A definitive diagnosis requires a biopsy, which often is too risky to perform. ⁴⁹ Diagnosis is often made post mortem. The only cure for this condition is lung transplantation. PH-targeted therapies, anticoagulation and diuretics can be used for palliative purposes. ⁴⁹

Large vessel vasculitis

Large vessel vasculitis involving the pulmonary arteries can be seen in Takayasu's arteritis, giant cell arteritis, and Behcet's disease. Pulmonary arterial vasculitis can mimic CTEPH as it can cause extrinsic compression as well as endoluminal obstruction of the pulmonary artery.^52,53

Takayasu's arteritis (TA), also know as the ‘pulseless disease’, is a rare chronic vasculitis of unknown etiology that mainly affects the aorta and its branches but it can also involve the pulmonary arteries.^54,55 Although symptomatic pulmonary involvement is relatively uncommon in TA, studies have shown involvement of the large and medium pulmonary arteries in roughly 50% of patients with this condition. ⁵⁴ Isolated involvement of the pulmonary arteries is rare. ⁵⁶ It is predominantly seen in young women under the age of 40 years of East Asian ancestry.^56,57

Clinically, presentation is nonspecific, often insidious and depends on the site, extent, and duration of vascular involvement.^56,58 Patients can present with generalized symptoms of fever, night sweats, malaise, weight loss, arthralgias, and myalgias. ⁵⁶ They can also present with signs of organ ischemia like myocardial ischemia or infarction, stroke, uncontrolled hypertension, and visual disturbances due to involvement of the myocardial, cranial, renal, or retinal vessels respectively.^56,59 Limb claudication, diminished, or absent pulses and vascular bruits may also be present due to peripheral arteriopathy.^56,59 Pulmonary bruits over the lung fields have been described in patients with CTEPH but these patients do not have bruits over other systemic arteries. ⁵⁹ Patients may also present with respiratory symptoms like shortness of breath, cough, chest pain, and hemoptysis.^56,57,60 The development of PH can occur in TA but its incidence is about 12-13%. ⁵⁸ Variable disease progression and nonspecific signs and symptoms often lead to a delayed diagnosis. ⁵⁶ Increase in laboratory markers of inflammation like erythrocyte sedimentation rate and C- reactive protein can be seen although a negative value does not rule out vasculitis. ⁵⁶ Anemia is also often seen in patients with TA where in CTEPH, the hematocrit is often normal to elevated. ⁵⁹

Diagnosis is based on clinical presentation and various imaging modalities. ⁵⁶ Computed tomographic angiography and MRI are considered the tests of choice for TA as they help assess not only the arterial lumen but also the arterial wall changes. ⁶¹ On CTA, pulmonary vasculitis typically presents with concentric circumferential arterial mural thickening with high attenuation on pre contrast and double ring enhancement pattern on post contrast imaging.^56,62 Other features include transmural calcium deposition, luminal stenosis (Fig. 6) and/or dilation and less commonly occlusion, ectasias, and aneurysms of involved arteries.^56,62 The pulmonary arterial pseudoaneurysms may be associated with in situ thrombus formation that may mimic CTEPH. OPEN IN VIEWER

On pulmonary angiography, different findings like stenosis, dilation, occlusion and luminal irregularities can be seen in large vessel vasculitis as well as CTEPH. ⁵⁹ A study of 48 patients with TA and PH showed that the main pulmonary artery was more often involved compared to the distal pulmonary arteries in TA, whereas another study of 98 patients showed more frequent involvement of the segmental and subsegmental branches.^54,60 Right-sided involvement and involvement of the upper lobe branches of the pulmonary arteries are also more common than left sided or lower branch involvement.^54,60 A thin, beaded appearance of the pulmonary arteries can suggest TA over CTEPH. Although angiography is a useful evaluation tool, assessment of the vessel wall with this modality is suboptimal. ⁶¹ Angioscopy can help differentiate between TA and CTEPH, though it is rarely done. In CTEPH, the intima looks irregular and pitted while in arteritis, its appearance is smooth and uniform. ⁵⁹ Formation of systemic to pulmonary shunts distal to occluded pulmonary arteries has also been described in TA and their formation suggest extensive involvement of the pulmonary arteries.^54,56 This feature though, is also seen in CTEPH and is not helpful in differentiation. ⁵⁹ A PET scan also plays a valuable role in diagnosis of TA as pulmonary vasculitic lesions will demonstrate increase in FDG uptake compared to non-inflamed vessels.^61,63

Imaging of the aorta and its branches, via MRI or conventional angiography, is critical to the diagnosis of TA. On aortography, aortic stenosis, dilation, aneurysms, and occlusion may be seen.^42,54 Some vessels may have a beaded appearance and others may show abrupt tapering with pre-stenotic dilation. ⁵⁹

The main distinguishing features of TA from CTEPH are the presence of systemic symptoms and signs, particularly arterial symptoms such as limb claudication, neurologic deficits, and diminished systemic pulses, and imaging evidence of aortic involvement. Both aortography and pulmonary arteriography are necessary to establish a confident diagnosis and evaluate the extent of the disease.

Patients who develop PH secondary to pulmonary arteritis in TA have a very poor prognosis. ⁵⁶ The mainstay of treatment for TA is high dose glucocorticoids. ⁵⁷ Methotrexate, azathioprine and in severe cases, cyclophosphamide and infliximab have been used. ⁵⁶ Percutaneous transluminal angioplasty, stenting or bypass surgery may also be considered for critical vessel stenosis.^56,62

Sarcoidosis

Sarcoidosis is an idiopathic chronic inflammatory condition that can affect multiple organs but the most commonly involved organ is the lung. ⁶⁴ PH is highly prevalent in sarcoidosis and can be present in up to 28% of cases. ⁶⁵ Sarcoidosis can cause PH through multiple mechanisms, the most common cause being pulmonary parenchymal fibrosis. Other mechanisms include direct involvement of the vessel wall with granulomas, granulomatous FM (as described in detail above), and extrinsic compression of pulmonary vessels from mediastinal lymphadenopathy. ⁶⁶ A small case series by Tandon et al. ⁶⁷ raised the hypothesis that sarcoidosis may also be associated with CTEPH due to the increased risk of venous thromboembolism, and may be another mechanism of developing PH in these patients.

Sarcoidosis is often termed ‘the great mimicker’ as the clinical presentation and imaging findings may be non-specific or atypical. A VQ scan may show mismatched perfusion defects suggesting CTEPH. ³⁹ Also, certain features seen on CTA in CTEPH like arterial webbing, intimal irregularities, and abrupt vascular narrowing with post stenotic dilation may also be seen in sarcoidosis-associated PH due to granulomatous involvement of the vessels. ⁶⁷ Hence, one must be aware of other characteristic features that can help differentiate the two disease conditions. ⁶⁷

The appearance of pulmonary sarcoidosis on imaging depends on the stage of presentation. Stage I disease presents with mediastinal lymphadenopathy commonly involving the hilar and paratracheal nodes. ⁶⁴ The lymphadenopathy is usually bilateral symmetrical and non-necrotic. ⁶⁴ Other locations for nodal involvement include sub aortic, AP window nodes, and subcarinal nodes. In long standing disease, nodal calcification is commonly seen. Stage II disease involves the pulmonary parenchyma along with mediastinal lymphadenopathy. Stage III involves the lung parenchyma without any lymphadenopathy. The hallmark of pulmonary sarcoidosis is the presence of lung nodules in a peribronchovascular and perilymphatic (subpleural area and along the interstitium) distribution. The upper lobes of the lungs are the most frequently involved. ⁶⁴ Sometimes the nodules can coalesce and form larger nodules or less commonly, large mass-like areas. Stage IV disease is end stage fibrotic lung disease with fibrosis, traction bronchiectasis, and subpleural honeycombing predominantly involving the bilateral upper and mid lung zones. Although PH is more commonly associated with advanced stages of sarcoidosis, it can be seen in patients with Stage 1 disease as well. ⁶⁸ Alveolar sarcoidosis is a rarer form that can present with consolidative opacities on the Chest CT. ⁶⁴ Another uncommon form of sarcoidosis called miliary sarcoidosis presents with diffuse multiple tiny miliary nodules. Mediastinal lymphadenopathy and parenchymal involvement are helpful features in differentiating sarcoidosis from CTEPH.

Of note, as mentioned above, sarcoidosis and CTEPH can co-exist in the same patient (Fig. 7 to 10). It is crucial to rule out CTEPH in any patient with sarcoidosis-associated PH because, if present, PEA can be used to treat these patients. ⁶⁷ CTA will show absence of filling defects in the pulmonary arteries if PH is caused due to extrinsic compression of the vessel as opposed to CTEPH. OPEN IN VIEWER

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Fig. 7.

Panel A: Digital subtraction image from a right pulmonary angiogram in LAO 42 ° projection – There is stenosis of anterior segmental branch of RUL with post-stenotic dilation. Also noted is atrophic basilar segmental branch of the RLL. The perfusion in the periphery of the RUL (anterior segment) is diminished. Panel B: Digital subtraction image from a left pulmonary angiogram in RAO 37 ° Caudal 1 projection – There are atrophic/occluded lingular segmental branches. The basilar segmental branch of the LLL demonstrates luminal irregularities without significant luminal narrowing. There is associated decreased perfusion of the lingula.

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Fig. 8.

Surgical specimens of the right and left pulmonary arterial chronic clots, with the largest burden in the RUL.

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Fig. 9.

Axial CT images in the mediastinal window settings demonstrate calcified confluent mediastinal and right hilar lymphadenopathy in a patient with combined CTEPH and sarcoidosis. Also noted is lobular filling defects in the right main and interlobular pulmonary artery, consistent with CTED; there is mass effect on the right interlobar PA secondary to the calcified lymphadenopathy.

Sarcoidosis, in general, carries a favorable prognosis but when associated with PH, prognosis is poor and carries a significant morbidity and mortality. ⁶⁸ Treatment of sarcoidosis associated PH is not well established and includes anti-inflammatory therapies, pulmonary vasodilators, anticoagulation, and oxygen.^68,69

Malignancy

Pulmonary tumor thrombotic microangiopathy (PTTM) is a condition in which tumor cells embolize to the pulmonary circulation leading to activation of the coagulation cascade, thrombus formation, intimal proliferation, obstruction and subsequently PH. ⁷⁰ Tumors commonly associated with tumor embolization include renal cell cancer (Fig. 11), soft tissue sarcomas, and atrial myxomas, but it has also been reported in multiple other tumor types like breast cancer, gastric cancer, liver cancer, thyroid cancer, testicular cancer, and uterine cancer. ⁹ In an autopsy study by Winterbauer et al., ⁷¹ tumor embolization was found in 26% of patients with cancer and in about 8% of the cases, it was a significant cause of death of the patient. ⁷¹ We reported a case of right atrial myxoma metastases to the pulmonary arteries giving the appearance of chronic thromboembolic lesions. ⁷² PTTM can also occur due to direct tumor extension to the pulmonary arteries through the right heart chamber or the vena cavae. ⁷⁰ A frequent cause of complete lack of perfusion of one lung on VQ scan is lung cancer. ⁷³ OPEN IN VIEWER

Patients can present insidiously with symptoms of dyspnea on exertion, cough, chest pain, hemoptysis as well as general symptoms like fatigue, malaise, night sweats, and weight loss. Most of these patients are also hypoxic.^70,74 Although cough may be present in CTEPH, it is not a common symptom like in PTTM. ⁷⁰ In more advanced cases, patients can present with decompensated heart failure. ⁷⁰ On laboratory analysis, signs of microangiopathic hemolytic anemia like thrombocytopenia, anemia, elevated D-dimer, and elevated LDH may be seen. ⁷⁰

The VQ scans of these patients typically show multiple symmetric peripheral subsegmental mismatched perfusion defects that are distributed evenly throughout the lungs.^75,76 This VQ scan pattern can also be seen in idiopathic PH, septic emboli, fat emboli, and talc granulomatosis in IV drug abusers. ⁷⁵ This is different from the larger mismatched perfusion defects seen in the larger pulmonary arteries in CTEPH although features overlap and diagnosis is not conclusive. ⁷⁷ In PTTM, there are no specific diagnostic signs on a Chest CT but there may be ancillary findings related to the tumor that may prove helpful in pinpointing the diagnosis. ⁷⁶ A Chest CT scan may show asymmetric intra and interlobular septal thickening that may be nodular in appearance secondary to lymphangitic infiltration by tumor cells or tumoral edema.^70,76 There may also be mediastinal or hilar lymphadenopathy or lung nodules, which may represent metastatic disease. A case series reported four patients with a ‘dilated and beaded’ appearance of the peripheral pulmonary arteries due to tumor emboli. ⁷⁶ Other features include ground glass opacities and centrilobular tree in bud opacities. ⁷⁰ Features of PH including right-sided heart enlargement and enlargement of the pulmonary artery may be seen. ⁷⁰ PET avidity has been reported in some cases of PTTM depending on the lesion size and histological type of cancer. Thrombus in CTEPH is not PET avid and this may be a useful test to distinguish between the two entities if positive in PTTM. ⁷⁴ Pulmonary angiography is not an ideal modality for the evaluation of tumor emboli and has a very low sensitivity and specificity for diagnosis. ⁷⁶ A definite diagnosis may be difficult and requires tissue sampling and cytological analysis. ⁷⁴ A prior history of malignancy or current malignancy should prompt physicians to consider this diagnosis and investigate it with further work up. Finally, it is important to note that malignancy too, like sarcoidosis independently increases the risk of venous thromboembolism and can promote the development of CTEPH.^78,79

The prognosis of patients with PTTM is extremely poor with death occurring within a few days to weeks due to right heart failure. ⁷⁰ If diagnosed early, treatment should be directed at the underlying malignancy. Pulmonary vasodilators, anti inflammatory agents like steroids and anti-proliferative agents targeting growth factors have been used but evidence is limited and is based on case reports. ⁷⁸

Congenital anomalies of the pulmonary arteries

Unilateral proximal interruption of the pulmonary artery

Unilateral proximal interruption of the pulmonary artery (UPPA) is characterized by abrupt termination of the pulmonary artery at the level of the hilum. ⁸⁰ This is a rare congenital anomaly with an incidence of 1 in 200,000 persons.^80,81 The right side is more commonly affected than the left side. Left-sided interruption of the pulmonary artery is often associated with concurrent congenital cardiac anomalies like tetralogy of Fallot, right aortic arch, aortic coarctation, patent ductus arteriosus, septal defects, and transposition of great arteries.^81–83 Right-sided defects are usually present in isolation. ¹⁸ The affected lung is supplied by systemic collateral vessels formed mainly by branches of the bronchial arteries but also by collaterals from the intercostal, internal mammary, subclavian, subdiaphragmatic, or innominate arteries.^80,81,83

This condition is typically diagnosed at a younger age (median age of 14 years). ⁸³ The most common symptoms include recurrent infections, dyspnea, exercise intolerance, and hemoptysis.^80,83 In a significant proportion of adult patients, this condition can be asymptomatic.^84,85 Rupture of the collateral vessels may occur as a complication in about 10 to 20% of patients causing pulmonary hemorrhage which can vary from self-limited to massive life-threatening hemorrhage.^80,81,83 On physical exam, the presence of flow murmurs has been described limited to the affected side secondary to turbulent vessel flow. Flow murmurs over the lung fields can also be heard in patients with CTEPH. ⁸⁴ The incidence of PH in this condition is variable and reportedly varies from 19 to 44%.^81,83

UPPA is often suspected after a chest radiograph is obtained for other purposes and shows abnormalities suspicious of this condition. On a plain chest radiograph, the mediastinum is shifted to the affected side, the ipsilateral hemidiaphragm may be elevated and there is compensatory hyperinflation of the lungs on the unaffected side.^80,83,84 The hilar shadow is absent. ⁸⁶ Other signs may be seen due to the collateralization of vessels on the affected side such as subpleural reticular opacities, rib notching due to intercostal arteries, and pleural thickening or parenchymal bands due to transpleural collaterals.^80,83 However, not all patients present with these classic chest X-ray findings. Sometimes, normal or increased vascularity of the affected lung may be seen due to compensatory increase in bronchial collaterals or back perfusion of pulmonary arteries by these collaterals. ⁸⁴ Chest radiography in CTEPH may show similar findings of hypovascularity and unilateral lung volume loss due to prior pulmonary infarctions and can be confused with UPPA. A CT angiography is the preferred diagnostic modality as it can delineate the vascular anatomy more accurately.^80,83 Abrupt termination of the pulmonary artery is seen at or within 1 cm of the hilum (Figs. 12 and 13). The CTA will also show the collateral vessels on the affected side of the lung and ipsilateral volume loss. ⁸³ If a main pulmonary artery is blocked by a thrombus in CTEPH, it may mimic UPPA on a CTA and be difficult to distinguish from this condition. A VQ scan may not be reliable in distinguishing UPPA and CTEPH as both conditions will show mismatched perfusion defects. ⁸⁷ However, in UPPA, the perfusion defect will only be seen on one side. ⁸³ Cardiac MRI may be useful in identifying other congenital anomalies of the cardiac structures that may be present concomitantly. ⁸⁰ A history of deep vein thrombosis may provide a clue to the presence of CTEPH. On physical examination, patients with CTEPH may demonstrate signs of PH and right ventricular failure which is not seen in patients with UPPA. ⁸⁴ OPEN IN VIEWER

Fig. 12.

Panel A: CXR showing mediastinal shift to the left with volume loss in a patient with congenital interruption of the left pulmonary artery. Also noted is shallow appearance of the left hilum. Panel B and C: Axial CT images in mediastinal window settings demonstrate complete absence of the left PA. Few bronchial artery collaterals are noted in the left hilar region. Panel D: Corresponding lung window image shows volume loss of the left lung with few peripheral reticulations (which reflect nonspecific fibrosis).

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Fig. 13.

Perfused blood volume images from Dual energy CT data demonstrate near complete absence of the perfusion to the left lung.

Traditionally, a pneumonectomy is considered to be the defnitive treatment although it carries a high risk of morbidity and mortality. ⁸¹ Embolization of collateral arteries in cases of hemoptysis has shown to be successful in 73–99% of patients according to a study with recurrence also relatively common occurring in up to half of the patients. ⁸⁸

Summary

The diagnosis of CTEPH is challenging and critical at the same time, as dramatically effective procedures are available to the correctly diagnosed patient. The VQ scan remains the initial screening test of choice given its binary simple interpretation and high sensitivity for the detection of CTEPH. However, an abnormal VQ scan showing mismatched perfusion defects does not always equate to CTEPH. Furthermore, lining thrombus on CTA, typically reported as chronic pulmonary embolism, does not equate with CTEPH either. A multidisciplinary team with experience and expertise in CTEPH, pulmonary vascular disease, and diagnostic radiology is needed to arrive at the correct diagnosis and treatment plan.