Chronic thromboembolic pulmonary hypertension (CTEPH) is a rare but potentially life-threatening disease of the pulmonary circulation [1]. The pathogenesis of CTEPH is not entirely clear. The most accepted scenario is that of aborted recanalisation of pulmonary arteries after a thromboembolic episode. While some post-embolic residua may persist in up to 50% of survivors of acute pulmonary embolism (aPE), only 0.5% to 2% will progress to CTEPH [2, 3]. This is believed to occur in the presence of significant redistribution of flow to remaining unoccluded pulmonary bed with resulting elevation of intravascular pressure and shear stress. Remodelling of initially patent pulmonary arterioles leads to an increase in pulmonary vascular resistance similar to that observed in left-to-right shunting in congenital heart disease. Progressive uncoupling of pulmonary and right ventricular elastance results in a fall of pulmonary flow, left ventricular preload, systemic blood pressure, and right ventricular (RV) coronary perfusion leading to right heart failure with severe functional disability and eventually to death. Management of CTEPH requires precise differential diagnosis and qualification for surgical treatment by an experienced multidisciplinary team. Indeed, in operable patients pulmonary endarterectomy (PEA) is highly effective in restoring functional status and improving life expectancy. A surgical technique has been optimised and implemented worldwide by a group from San Diego – University of California [4]. Nevertheless, PEA performed in deep hypothermia and intermittent total cardiac arrest remains one of the most demanding cardiovascular interventions and is performed only in a limited number of highly dedicated centres. As an example, Papworth Hospital is the only centre performing PEA in the UK, while Marie-Lannelongue Hospital in Paris remains a referral centre for France for this type of surgery. Usually, individual cardiac surgeons are responsible for PEA in their centres, as the learning curve for this intervention has been well documented [5]. With growing experience of clinicians, radiologists, surgeons, and anaesthesiologists, an increasing proportion of patients with CTEPH may benefit from PEA despite distal, less accessible intravascular residua and/or advanced age and comorbidities. This is of paramount importance since the outcome of non-operated patients is drastically worse (Figure 1), despite identical baseline haemodynamic characteristicsand significant perioperative mortality of 2–10% in patients submitted to PEA [6]. Nevertheless, even in the leading CTEPH referral centres almost 50% patients remain on medical treatment alone, with grim perspectives regarding life quality and expectancy. Based on a large randomised trial and promising long-term effects on exercise tolerance [7, 8] direct guanylyl cyclase stimulator (riociguat) has been approved for treatment of inoperable CTEPH. Riociguat may protect patent pulmonary arterioles from progressive remodelling [9] but is unlikely to affect the culprit post-embolic residua. Recently, balloon pulmonary angioplasty (BPA) has emerged as a promising new interventional option in non-operable CTEPH. In 2001, Feinstein et al. from Harvard Medical School described a group of 18 CTEPH patients treated with BPA [10]. Of these, 16 were excluded from PEA due to distal lesions, and two due to the presence of comorbidities increasing the risk associated with surgical treatment. In total, 47 procedures were performed, thus dilating or restoring the patency of 107 arteries. In the periprocedural period, 1 patient died of reperfusion pulmonary oedema and right ventricular failure. In total, reperfusion oedema occurred in 23% of cases, and its presence correlated with the value of pulmonary artery pressure (PAP) prior to the procedure. Long-term follow-up (mean, 34 months) showed an increase in physical capacity, manifesting itself as an improvement in NYHA class from a mean value of 3.3 prior to the procedure to a mean value of 1.8 following the procedure. Figure 1 Survival curves for patients with CTEPH treated with PEA (shadow line) and who were treated by pharmacotherapy only (solid line) – reprinted from Wieteska et al. [6] The succeeding years saw the development of the BPA technique mainly in Japanese centres. Japanese researchers have refined the BPA technique by reducing the number of segments treated during one session [11], by using smaller balloons [12], and by wider use of intravascular imaging [13, 14]. The experience of the Japanese centres shows that a series of BPA procedures performed in experienced centres has lead to regression of right ventricular dysfunction [15, 16] and are associated with an annual mortality below 5% – also in elderly patients [17]. However, it should be stressed that the population of Japanese patients with CTEPH differs from that observed in the European-American registry [18]. In a registry comprising 519 Japanese patients with CTEPH, lower median pretreatment mPAP (38 mm Hg vs. 47 mm Hg), more frequent use of PAH-like therapy (52% vs. 38%), and a significantly lower rate of cardiac surgical treatment used (14% vs. 57%) was observed [19]. The only larger group of patients in Europe who underwent BPA is that described by Andreassen et al. [20]. The Norwegian team treated 20 CTEPH patients, including 16 with distal lesions, 3 with proximal lesions who had refused PEA, and 1 patient with persistent pulmonary hypertension following surgical treatment. Prior to treatment, 85% of the patients presented with NYHA class III and IV symptoms. During recruitment to a percutaneous treatment program in the same centre, 50 PEAs were performed. In total, 73 BPA procedures were carried out (mean, 3.7 BPAs/patient; range: 2–9), thus performing angioplasty of 371 vessels – 118 segmental arteries and 253 subsegmental arteries. In the periprocedural period, two patients died, and treatment-requiring reperfusion oedema occurred in 7 cases. During 3-month follow-up, an improvement in the functional class (75% of patients in NYHA class I–II), in VO2max in cardiopulmonary exercise test (13.6 ±5.6 vs. 17.0 ±6.5, p < 0.001), in mean pulmonary artery pressure (45 ±11 mm Hg vs. 33 ±10 mm Hg, p < 0.001), in pulmonary vascular resistance (8.8 ±4.0 Wood Units vs. 5.9 ±3.6 Wood Units, p < 0.001), and in NT-pro-BNP levels (194 ±182 ng/ml vs. 90 ±119 ng/ml, p = 0.007) was achieved. Follow-up angiography revealed no restenosis. In Poland, the first BPA procedure was performed in 2013 [21]. Until now, the experience of our team includes 37 BPA procedures, which consisted of angioplasty of 105 vessels in 20 patients with CTEPH. Seventeen patients were excluded from surgical treatment by an experienced PEA cardiac surgery team, and in 3 patients persistent pulmonary hypertension persisted after PEA. Eighty-two percent of patients received PAH-like therapy – most frequently sildenafil. In the periprocedural period, two patients died of severe reperfusion oedema and severe hypoxaemia unresponsive to oxygen therapy (including mechanical ventilation). Those 2 patients were disqualified from PEA due to the presence of extensive lung cavities related to previous mycobacterial infection and due to significant comorbidities and advanced age, respectively – but not because of distal localisation of thrombi. All patients who underwent BPA because of distal lesion localisation survived. In technical terms, BPA does not significantly differ from balloon angioplasty performed in other vessels (Figure 2). Nevertheless, the complicated anatomy of the pulmonary tree, the necessity to advance the instruments through enlarged right heart chambers, and the fact that pulmonary vessels can be easily damaged with the guide wire or balloon catheter requires specific experience. It is not recommended that BPA procedures be performed by cardiologists or interventional radiologists who have experience in other vascular regions but no experience in interventions within the pulmonary circulation. During one procedure, no more than two segmental arteries or their subsegmental equivalents should be dilated due to the risk of reperfusion oedema. Reperfusion oedema results from redistribution of blood flow to areas supplied by dilated vessels, in which vascular resistance has abruptly decreased. This may cause blood cells to migrate into the alveoli, excluding them from gas exchange. One way to prevent reperfusion oedema is to undersize the balloon catheter being used, on the basis of angiography, or by means of intravascular ultrasound (IVUS) or optical coherence tomography (OCT). Also, pressure distal to a residual lesion and a gradient across the lesion can be measured by means of an fractional flow reserve (FFR) probe [22]. As there is no tendency towards restenosis, it is unnecessary to use stents. The results achieved in the group of patients who have completed a series of BPA procedures are very encouraging. A reduction in mean PAP from baseline 58 ±6 mm Hg to 41 ±9 mm Hg and in PVR from 11.7 ±4.3 Wood units to 6.6 ±2.2 Wood units was achieved in our series. The haemodynamic improvement corresponds with an improvement in exercise tolerance. Prior to BPA procedures, 95% of patients were in NYHA class III and IV, and the rate of patients in class III and IV decreased to 35% after treatment. A significant issue limiting growth in the number of such procedures performed in Poland is that BPA is not reimbursed by the National Health Fund. Figure 2 Balloon pulmonary angioplasty in a 67-year-old patient with persistent form of CTEPH. Left panel (A) presents the angiogram of occluded segmental pulmonary artery of left lower lobe. The BPA results in reperfusion of the vessel – right panel ( ...