Pulmonary arterial hypertension (PAH) is a rare disorder with a poor prognosis. Deleterious variation within components of the transforming growth factor-β pathway, particularly the bone morphogenetic protein type 2 receptor (BMPR2), underlies most heritable forms of PAH. To identify the missing heritability we perform whole-genome sequencing in 1038 PAH index cases and 6385 PAH-negative control subjects. Case-control analyses reveal significant overrepresentation of rare variants in ATP13A3, AQP1 and SOX17, and provide independent validation of a critical role for GDF2 in PAH. We demonstrate familial segregation of mutations in SOX17 and AQP1 with PAH. Mutations in GDF2, encoding a BMPR2 ligand, lead to reduced secretion from transfected cells. In addition, we identify pathogenic mutations in the majority of previously reported PAH genes, and provide evidence for further putative genes. Taken together these findings contribute new insights into the molecular basis of PAH and indicate unexplored pathways for therapeutic intervention.
Rationale: Clinical and epidemiologic data in coronavirus disease (COVID-19) have accrued rapidly since the outbreak, but few address the underlying pathophysiology. Objectives: To ascertain the physiologic, hematologic, and imaging basis of lung injury in severe COVID-19 pneumonia. Methods: Clinical, physiologic, and laboratory data were collated. Radiologic (computed tomography (CT) pulmonary angiography [n = 39] and dual-energy CT [DECT, n = 20]) studies were evaluated: observers quantified CT patterns (including the extent of abnormal lung and the presence and extent of dilated peripheral vessels) and perfusion defects on DECT. Coagulation status was assessed using thromboelastography. Measurements and Results: In 39 consecutive patients (male: female, 32:7; mean age, 53 6 10 yr [range, 29-79 yr]; Black and minority ethnic, n = 25 [64%]), there was a significant vascular perfusion abnormality and increased physiologic dead space (dynamic compliance, 33.7 6 14.7 ml/cm H 2 O; Murray lung injury score, 3.14 6 0.53; mean ventilatory ratios, 2.6 6 0.8) with evidence of hypercoagulability and fibrinolytic "shutdown". The mean CT extent (6SD) of normally aerated lung, ground-glass opacification, and dense parenchymal opacification were 23.5 6 16.7%, 36.3 6 24.7%, and 42.7 6 27.1%, respectively. Dilated peripheral vessels were present in 21/33 (63.6%) patients with at least two assessable lobes (including 10/21 [47.6%] with no evidence of acute pulmonary emboli). Perfusion defects on DECT (assessable in 18/20 [90%]) were present in all patients (wedge-shaped, n = 3; mottled, n = 9; mixed pattern, n = 6). Conclusions: Physiologic, hematologic, and imaging data show not only the presence of a hypercoagulable phenotype in severe COVID-19 pneumonia but also markedly impaired pulmonary perfusion likely caused by pulmonary angiopathy and thrombosis.
C hronic thromboembolic pulmonary hypertension (CTEPH) is a complication of acute pulmonary emboli with uncertain prevalence, ranging from 0.57% to 9.1%. 1The diagnosis is strongly associated with a history of acute venous thromboembolism.2 CTEPH results from incomplete Editorial, see p 1731 Clinical Perspective on p 1771resolution of pulmonary emboli that become organized into vessel walls and cause different degrees of obstruction to Background-Chronic thromboembolic pulmonary hypertension results from incomplete resolution of pulmonary emboli.Pulmonary endarterectomy (PEA) is potentially curative, but residual pulmonary hypertension following surgery is common and its impact on long-term outcome is poorly understood. We wanted to identify factors correlated with poor long-term outcome after surgery and specifically define clinically relevant residual pulmonary hypertension post-PEA. Methods and Results-Eight hundred eighty consecutive patients (mean age, 57 years) underwent PEA for chronic thromboembolic pulmonary hypertension. Patients routinely underwent detailed reassessment with right heart catheterization and noninvasive testing at 3 to 6 months and annually thereafter with discharge if they were clinically stable at 3 to 5 years and did not require pulmonary vasodilator therapy. Cox regressions were used for survival (time-toevent) analyses. Overall survival was 86%, 84%, 79%, and 72% at 1, 3, 5, and 10 years for the whole cohort and 91% and 90% at 1 and 3 years for the recent half of the cohort. The majority of patient deaths after the perioperative period were not attributable to right ventricular failure (chronic thromboembolic pulmonary hypertension). At reassessment, a mean pulmonary artery pressure of ≥30 mm Hg correlated with the initiation of pulmonary vasodilator therapy post-PEA. A mean pulmonary artery pressure of ≥38 mm Hg and pulmonary vascular resistance ≥425 dynes·s -1 ·cm -5 at reassessment correlated with worse long-term survival. Conclusions-Our data confirm excellent long-term survival and maintenance of good functional status post-PEA.Hemodynamic assessment 3 to 6 months and 12 months post-PEA allows stratification of patients at higher risk of dying of chronic thromboembolic pulmonary hypertension and identifies a level of residual pulmonary hypertension that may guide the long-term management of patients postsurgery. 4 It is recognized that there is a steep surgical and institutional learning curve at the start of a PEA program, but, in experienced centers, the operative mortality rate is <5%.5-7 A number of reports have confirmed improved short-term outcome in terms of hemodynamics, right ventricular function, quality of life, functional status, and exercise capacity after surgery. [7][8][9][10][11][12][13][14][15][16][17][18] Fewer reports describe long-term outcome post-PEA, and those that have been published are mainly retrospective and either only had small numbers of patients [19][20][21][22][23][24][25][26] or limited information of factors correlated with long-term outco...
Inflammation in pulmonary arterial hypertension. P. Dorfmüller, F. Perros, K. Balabanian, M. Humbert. #ERS Journals Ltd 2003. ABSTRACT: Inflammatory mechanisms appear to play a significant role in some types of pulmonary hypertension (PH), including monocrotaline-induced PH in rats and pulmonary arterial hypertension of various origins in humans, such as connective tissue diseases (scleroderma, systemic lupus erythematosus, mixed connective disease), human immunodeficiency virus infection, or plasma cell dyscrasia with polyneuropathy, organomegaly, endocrinopathy, monoclonal (M) protein and skin changes (POEMS) syndrome.Interestingly, some patients with severe pulmonary arterial hypertension associated with systemic lupus erythematosus have experienced significant improvements with immunosuppressive therapy, emphasising the relevance of inflammation in a subset of patients presenting with PH. Patients with primary PH (PPH) also have some immunological disturbances, suggesting a possible role for inflammation in the pathophysiology of this disease. A subset of PPH patients have been shown to have circulating autoantibodies, including antinuclear antibodies, as well as elevated circulating levels of the pro-infammatory cytokines, interleukins -1 and -6. Lung histology has also revealed inflammatory infiltrates in the range of plexiform lesions in patients displaying severe PPH, as well as an increased expression of the chemokines regulated upon activation, normal T-cell expressed and secreted (RANTES) and fractalkine.Further analysis of the role of inflammatory mechanisms is necessary to understand whether this component of the disease is relevant to its pathophysiology. Pulmonary arterial hypertension (PAH) is characterised by an elevated mean pulmonary artery pressure o25 mmHg at rest, with a normal pulmonary artery wedge pressure. This severe condition leads to progressive right heart failure and ultimately death [1]. The Evian Classification reflects recent advances in the understanding of pulmonary hypertensive diseases, and recognises the similarity between "unexplained" pulmonary hypertension (PH) (primary PH (PPH)) and PAH of certain known aetiologies, such as collagen vascular diseases, human immunodeficiency virus (HIV) infection, portal hypertension, congenital systemic-to-pulmonary shunts and anorexigen exposure [2].PAH results from chronic obstruction of small pulmonary arteries, which is due, at least in part, to endothelial and vascular smooth muscle cell dysfunction and proliferation [3]. The recent discovery that a significant proportion of patients with familial, as well as sporadic, PPH have germline mutations of genes encoding receptor members of the transforming growth factor (TGF)-b family (bone morphogenetic protein receptor-II and activin receptor-like kinase-1), suggests that dysfunctional TGF-b signalling could lead to an abnormal proliferation of pulmonary vascular cells [4,5]. Although these major advances have improved the understanding of PAH, more information is needed to evaluate th...
IntroductionPulmonary vascular dysfunction, pulmonary hypertension (PH), and resulting right ventricular (RV) failure occur in many critical illnesses and may be associated with a worse prognosis. PH and RV failure may be difficult to manage: principles include maintenance of appropriate RV preload, augmentation of RV function, and reduction of RV afterload by lowering pulmonary vascular resistance (PVR). We therefore provide a detailed update on the management of PH and RV failure in adult critical care.MethodsA systematic review was performed, based on a search of the literature from 1980 to 2010, by using prespecified search terms. Relevant studies were subjected to analysis based on the GRADE method.ResultsClinical studies of intensive care management of pulmonary vascular dysfunction were identified, describing volume therapy, vasopressors, sympathetic inotropes, inodilators, levosimendan, pulmonary vasodilators, and mechanical devices. The following GRADE recommendations (evidence level) are made in patients with pulmonary vascular dysfunction: 1) A weak recommendation (very-low-quality evidence) is made that close monitoring of the RV is advised as volume loading may worsen RV performance; 2) A weak recommendation (low-quality evidence) is made that low-dose norepinephrine is an effective pressor in these patients; and that 3) low-dose vasopressin may be useful to manage patients with resistant vasodilatory shock. 4) A weak recommendation (low-moderate quality evidence) is made that low-dose dobutamine improves RV function in pulmonary vascular dysfunction. 5) A strong recommendation (moderate-quality evidence) is made that phosphodiesterase type III inhibitors reduce PVR and improve RV function, although hypotension is frequent. 6) A weak recommendation (low-quality evidence) is made that levosimendan may be useful for short-term improvements in RV performance. 7) A strong recommendation (moderate-quality evidence) is made that pulmonary vasodilators reduce PVR and improve RV function, notably in pulmonary vascular dysfunction after cardiac surgery, and that the side-effect profile is reduced by using inhaled rather than systemic agents. 8) A weak recommendation (very-low-quality evidence) is made that mechanical therapies may be useful rescue therapies in some settings of pulmonary vascular dysfunction awaiting definitive therapy.ConclusionsThis systematic review highlights that although some recommendations can be made to guide the critical care management of pulmonary vascular and right ventricular dysfunction, within the limitations of this review and the GRADE methodology, the quality of the evidence base is generally low, and further high-quality research is needed.
in this population. [4][5][6] Because of ongoing improvement of care, survival prospects of adults with congenital heart disease are likely to have changed over recent decades. Khairy et al 7 demonstrated that mortality in patients with congenital heart disease has shifted away from infants and toward adults, with a steady increase in age at death. The current study was designed to evaluate a contemporary ACHD cohort from a single tertiary center and attempt comparison with data from Background-Adult congenital heart disease (ACHD) patients have ongoing morbidity and reduced long-term survival.Recently, the importance of specialized follow-up at tertiary ACHD centers has been highlighted. We aimed to assess survival prospects and clarify causes of death in a large cohort of patients at a single, tertiary center. Methods and Results-We included 6969 adult patients (age 29.9±15.4 years) under follow-up at our institution between 1991 and 2013. Causes of death were ascertained from official death certificates. Survival was compared with the expected survival in the general age-and sex-matched population, and standardized mortality rates were calculated. Over a median follow-up time of 9.1 years (interquartile range, 5.2-14.5), 524 patients died. Leading causes of death were chronic heart failure (42%), pneumonia (10%), sudden-cardiac death (7%), cancer (6%), and hemorrhage (5%), whereas perioperative mortality was comparatively low. Isolated simple defects exhibited mortality rates similar to those in the general population, whereas patients with Eisenmenger syndrome, complex congenital heart disease, and Fontan physiology had much poorer long-term survival (P<0.0001 for all). The probability of cardiac death decreased with increasing patient's age, whereas the proportion of patients dying from noncardiac causes, such as cancer, increased. Conclusions-ACHD patients continue to be afflicted by increased mortality in comparision with the general population as they grow older. Highest mortality rates were observed among patients with complex ACHD, Fontan physiology, and Eisenmenger syndrome. Our data provide an overview over causes of mortality and especially the spectrum of noncardiac causes of death in contemporary ACHD patients. Key words: heart defects, congenital ◼ heart failure ◼ mortality ◼ sudden cardiac death ◼ survival © 2015 American Heart Association, Inc.Circulation is available at http://circ.ahajournals.org DOI: 10.1161/CIRCULATIONAHA.115.017202Received April 23, 2015; accepted September 8, 2015. From Adult Congenital Heart Centre and National Centre for Pulmonary Hypertension, Royal Brompton Hospital, London, United Kingdom (G. previous studies. In addition, we provide herewith mortality data in relationship to the general population, adjusted for age and sex, and propose a novel approach for presenting these data to health professionals, health policy makers, and patients alike.- Patients and MethodsWe retrospectively reviewed data on all adult patients with congenital heart disease under active foll...
Background-Advanced therapy (AT) for pulmonary arterial hypertension in the context of congenital heart disease (Eisenmenger syndrome) improves pulmonary hemodynamics, functional class, and the 6-minute walk test. We examined the potential effect of AT on survival in this population. Methods and Results-Data on all Eisenmenger patients attending our center over the past decade were collected. Survival rates were compared between patients on and off AT with the use of a modified version of the Cox model, which treats AT as a time-varying covariate. Baseline differences were adjusted for the use of propensity scores. A total of 229 patients (aged 34.5Ϯ12.6 years; 35.4% male) were included. The majority had complex anatomy, and 53.7% were in New York Heart Association class ՆIII at baseline assessment. Mean resting saturations were 84.3%. Sixty-eight patients (29.7%) either were on AT or had AT initiated during follow-up. During a median follow-up of 4.0 years, 52 patients died, only 2 of them while on AT. Patients on AT were at a significantly lower risk of death, both unadjusted and after adjustment for baseline clinical differences by propensity score regression adjustment (C statisticϭ0.80; hazard ratio, 0.16; 95% confidence interval, 0.04 to 0.71; Pϭ0.015) and propensity score matching (hazard ratio, 0.10; 95% confidence interval, 0.01 to 0.78; Pϭ0.028). Conclusions-AT for pulmonary arterial hypertension in a contemporary cohort of adults with Eisenmenger syndrome was associated with a lower risk of death. Survival benefits should be considered together with improved hemodynamics and functional class when decisions are made about AT in this population. (Circulation. 2010;121:20-25.)
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