Objective To detecting the genetic etiology of a family with idiopathic pulmonary arterial hypertension and make gene diagnosis for the patient, so as to guide the targeted treatment and early intervention for the patient and her families. Methods The phenotype information of the family members was reviewed and their peripheral blood was collected for genomic DNA extraction. Exome sequencing was used to screen the mutations and proving the selected mutations by PCR-Sanger sequencing method. The pathogenicity of candidate mutation sites were searched through PubMed and related databases, and analyzed by protein function software. The judgement of pathogenicity was considered by clinical presentations and sequencing results of the patients based on Standards and guidelines for the interpretation of sequence variants revised by ACMG. Results At present, there was only one patient with pulmonary hypertension in this family, and other family members had no clinical manifestations of pulmonary hypertension. The female patient had BMPR2 gene c.1748dupA(p.Asn583Lysfs*6) heterozygous mutant. Her father and second son had BMPR2 gene c.1748dupA(p.Asn583Lysfs*6) heterozygous mutant, but none of the other members of the family had the mutation. Conclusions The heterozygous mutation of c.1748dupA (p.Asn583Lysfs*6) of BMPR2 gene is the genetic cause of the idiopathic pulmonary arterial hypertension patient, and the clinical significance of c.1748dupA(p.Asn583Lysfs*6) is pathogenic. The patient can be further diagnosed as pulmonary hypertension, primary 1 (PPH1) by gene diagnosis, and the mutant is novel and pathogenic for PPH1.
Objective To investigate the effects of simvastatin on monocrotaline-induced pulmonary hypertension in rats, and explore the potential mechanism of simvastatin by blocking heme oxygenase-1( HO-1) expression. Methods 52 male Sprague-Dawley rats were randomly divided into five groups, ie. a control group, a simvastatin control group, a pulmonary hypertension model group, a simvastatin treatment group, a ZnPP ( chemical inhibitor of HO) group. Mean pulmonary arterial pressure ( mPAP) and right ventricular systolic pressure ( RVSP) were detected by right heart catheter at 5th week. Right ventricular hypertrophy index ( RVHI) was calculated as the right ventricle to the left ventricle plus septum weight. Histopathology changes of small intrapulmonary arteries were evaluated via image analysis system.Immunohistochemical analysis was used to investigate the expression and location of HO-1. HO-1 protein level in lung tissue were determined by western blot. Results Compared with the model group, simvastatin treatment decreased mPAP and RVHI significantly [ ( 35. 63 ±5. 10) mm Hg vs. ( 65. 78 ±15. 51) mm Hg,0. 33 ±0. 05 vs. 0. 53 ±0. 06, both P lt; 0. 05 ] . Moreover, simvastatin treatment partially reversed the increase of arterial wall area and arterial wall diameter [ ( 50. 78 ±9. 03 ) % vs. ( 65. 92 ±7. 19) % ,( 43. 75 ±4. 23) % vs. ( 52. 00 ±5. 35) % , both P lt; 0. 01) . In the model group, HO-1 staining was primarily detected in alveolar macrophages. Simvastatin treatment increased HO-1 protein expression significantly, especially in the thickened smooth muscle layer and alveolar macrophages. Inhibiting HO-1 expression using ZnPP resulted in a loss of the effects of simvastatin. mPAP in the ZnPP group was ( 52. 88±17. 45) mm Hg, while arterial wall area and arterial wall diameter were ( 50. 78 ±9. 03) % and ( 52. 00 ±5. 35) % , respectively. Conclusions Simvastatin attenuates established pulmonary arterial hypertension andpulmonary artery remodeling in monocrotaline-induced pulmonary hypertension rats. The effect of simvastatin is associated with HO-1.
Objective To investigate the effect of prostaglandin E1 (PGE1) on serum vascular endothelial growth factor(VEGF) in patient with pulmonary hypertension secondary to congenital heart disease and its relation to different pathologic gradings of pulmonary arterioles. Methods Fifty three patients suffering from pulmonary hypertension secondary to congenital heart disease were chosen at random to undergo active tissue test of lung, including 6 patients suffering from severe cyanosis. All of them were intravenously dripped with PGE 1 for 15 days at the speed of 10 15 ng /kg·min, 12 hours a day. Venous blood was taken for study in the morning on the day before infusion, on the 5th day, the 10th day, and the 15th day after infusion. Then the concentration of VEGF was measured by enzyme linked immunosorbent assay (ELISA). Lung biopsy was taken from each patient and pathologic grading performed according to Heath and Edwards pathologic grading. Results Fifty three patients were classified into Grade Ⅴ:9 of them belonged to Grade Ⅰ, 14 to Grade Ⅱ, 19 to Grade Ⅲ, 5 to Grade Ⅳ, the other 6 with severe cyanosis belonged to Grade Ⅴ or even severe than Grade Ⅴ. Before administration of PGE 1, serum VEGF reached the peak while the pathologic grading of pulmonary arteriole was Grade Ⅲ, VEGF level markedly decreased in Grade Ⅳ and Ⅴ. After administration of PGE 1 serum VEGF in Grade Ⅰ showed no difference with that before administration of PGE 1( P gt;0.05), VEGF decreased in GradeⅡ and Ⅲ ( P lt;0.01), slightly decreased in Grade Ⅳ ( P lt; 0.05), while patients greater or equivalent to Grade Ⅴ showed no VEGF change during the course of PGE 1 administration ( P gt;0.05). Conclusions PGE 1 can lower the VEGF level, but the extent closely relates to the degree of pathologic change in pulmonary arteriole. It might be a pre operative parameter for pathologic grading of pulmonary arteriole.
Pulmonary arterial hypertension(PAH) is a kind of pulmonary hypertension disease. Recently, the researches of its pathogenesis have reached more and more deeply. The treatment of pulmonary arterial hypertension is individual and systematic, not only relying on medicine treatment. The treatment of PAH is as follows: common treatment, non-specific medicine treatment, targeted medicine treatment, NO breath-in treatment, gene treatment, intervention and surgery treatment.The article reviews the main treatment of pulmanory arteral hypertesion to provide new thought and evidence in clinic.
ObjectiveTo investigate the expression of CD4+CD25highCD127lowTreg (Treg) and related cytokines in peripheral blood of COPD patients with pulmonary hypertension and explore its clinical significance. MethodsPeripheral blood lymphocytes and serum were collected from 65 COPD patients with chronic pulmonary hypertension (the CPH group) and 20 COPD patients with normal pulmonary artery pressure (the control group). Flow cytometry was used to detect the Treg/CD4+ T cells and calculate its ratio, enzyme-linked immunosorbent assay was used to detect the serum contents of interleukin (IL)-6,IL-10 and tumor necrosis factor α (TNF-α). ResultsTreg can be detected in the peripheral blood of patients of COPD with or without PH, however, the Treg ratio in the CPH group was significantly lower than that in the control group [(7.41±1.12)% vs. (9.04±2.11)%, P<0.05]. Compared with the control group, the IL-10 level was significantly lower [(4.47±0.88)pg/mL vs. (5.18±0.26)pg/mL], while IL-6and TNF-α contents were significantly higher in the CPH group [(7.49±0.95)pg/mL vs. (6.76±0.35)pg/mL, (28.61±9.16)pg/mL vs. (19.64±4.85)pg/mL, P<0.05]. There was a positive correlation between Treg ratio and serum IL-10 level (r=0.41, P<0.05), and negative correlation between Treg ratio and TNF-α or IL-6 contents (r=0.45 or 0.37,P<0.05). The Treg ratio of the patients with severe pulmonary hypertension was lower than that in the patients with mild pulmonary hypertension [(7.42±1.03)% vs. (10.47±2.55)%,P<0.05). ConclusionsContents of Treg and IL-10 decrease while IL-6 and TNF-α increase in peripheral blood of COPD patients with pulmonary hypertension. It suggests that Treg cells and related cytokines may involve in the pathogenesis and progression of CPH. Treg may becomea potential biological prognosis indicator and treatment target of CPH in the future.
Objective To investigative the effects of combination treatment with simvastatin and aspirin in a rat model of monocrotaline-induced pulmonary hypertension. Methods Sixty male Sprague-Dawley rats were randomly divided into a control group, a simvastatin group, an aspirin group, and a combination treatment group. The control group received monocrotaline injection subcutaneously to induce pulmonary hypertension. Simvastatin ( 2 mg/kg) , aspirin ( 1 mg/kg) , or simvastatin ( 2 mg/kg) + aspirin ( 1 mg/kg) was administered once daily to the rats of treatment groups respectively for 28 days after monocrotaline injection. Mean pulmonary arterial pressure ( mPAP) was detected by right heart catheter.Right ventricular hypertrophy index ( RVHI) was calculated as the right ventricle to the left ventricle plus septum weight. Histopathology changes of small intrapulmonary arteries were evaluated via image analysissystem. Interleukin-6 ( IL-6) level in lung tissue was determined by ELISA.Results Compared with the control group, simvastatin or aspirin decreased mPAP [ ( 34. 1 ±8. 4) mm Hg, ( 38. 3 ±7. 1) mmHg vs.( 48. 4 ±7. 8) mmHg] and increased arterial wall diameter significantly ( P lt; 0. 05) . The combination treatment group showed more significant improvement in mPAP, RVHI and pulmonary arterial remodeling compared with each monotherapy ( P lt;0. 05) . Moreover, the combination therapy had additive effects on the increases in lung IL-6 levels and the perivascular inflammation score. Conclusions Combination therapy with simvastatin and aspirin is superior in preventing the development of pulmonary hypertension. The additive effect of combination therapy is suggested to be ascribed to anti-inflammation effects.
Objective To analyze the relation between preoperative pulmonary artery pressure(PAP) and postoperative complications in heart transplant patients, and summarize the experience of perioperative management of pulmonary hypertension (PH), to facilitate the early period heart function recovery of postoperative heart transplant patients. Methods A total of 125 orthotopic heart transplant patients were divided into two groups according to preoperative pulmonary arterial systolic pressure(PASP) and pulmonary vascular resistance(PVR), pulmonary [CM(1583mm]hypertension group (n=56): preoperativePASPgt;50 mm Hg or PVRgt;5 Wood·U; control group (n=69): preoperative PASP≤50 mmHg and PVR≤5 Wood·U. Hemodynamics index including preoperative cardiac index (CI),preoperative and postoperative PVR and PAP were collected by SwanGanz catheter and compared. The extent of postoperative tricuspid regurgitation was evaluated by echocardiography. Postoperative pulmonary hypertension was treated by diuresis,nitrogen oxide inhaling,nitroglycerin and prostacyclin infusion, continuous renal replacement therapy(CRRT)and extracorporeal membrane oxygenation(ECMO). Results All patients survived except one patient in pulmonary hypertension group died of multiorgan failure and severe infection postoperatively in hospital. Acute right ventricular failure occurred postoperatively in 23 patients, 10 patients used ECMO support, 10 patients with acute renal insufficiency were treated with CRRT. 124 patients were followed up for 2.59 months,7 patients died of multiple organ failure, infection and acute rejection in follow-up period, the survivals in both groups have normal PAP, no significant tricuspid regurgitation. No significant difference in cold ischemia time of donor heart, cardiopulmonary bypass(CPB) and circulation support time between both groups; but the patients of pulmonary hypertension group had longer tracheal intubation time in comparison with the patients of control group (65±119 h vs. 32±38 h, t=2.17,P=0.028). Preoperative PASP,mean pulmonary artery pressure(MPAP) and PVR in pulmonary hypertension group were significantly higher than those in control group, CI was lower in pulmonary hypertension group [PASP 64.30±11.50 mm Hg vs. 35.60±10.20 mm Hg; MPAP 43.20±8.50 mm Hg vs. 24.20±7.20 mm Hg; PVR 4.72±2.26 Wood·U vs. 2.27±1.24 Wood·U; CI 1.93±0.62 L/(min·m2) vs. 2.33±0.56 L/(min·m2); Plt;0.05]. Postoperative early PASP, MPAP and PVR in pulmonary hypertension group were significantly higher than those in control group (PASP 35.40±5.60 mm Hg vs. 31.10±5.70 mm Hg, MPAP 23.10±3.60 mm Hg vs. 21.00±4.00 mm Hg, PVR 2.46±0.78 Wood·U vs. 1.79±0.62 Wood·U; Plt;0.05). Conclusion Postoperative right heart insuficiency is related to preoperative pulmonary hypertension in heart transplant patients. Donor heart can quickly rehabilitate postoperatively by effectively controlling perioperative pulmonary hypertension with good follow-up results.
In left heart disease, pulmonary artery pressure would increase due to the elevated left atrial pressure. This type of pulmonary hypertension (PH) is belonged to type Ⅱ as a passive PH (pPH) in its classification. The essential cause of pPH is excessive blood volume. Recently, we have identified another type of pPH, which is induced by vasopressors. Vasopressor-induced pPH shares similar pathophysiological manifestations with left heart disease-induced pPH. pPH would, therefore, be aggressive if vasopressors were applied in patients with left heart disease, which may be common after cardiac surgery, because heart undergoing surgical trauma may require support of vasopressors. Unfortunately, pPH after cardiac surgery is often ignored because of the difficulty in diagnosis. To improve the understanding of pPH and its effect on outcomes, here we highlight the mechanisms of interaction between vasopressor-induced and left heart failure-induced pPH, and provide insights into its therapeutic options.
Pulmonary hypertension (PH), characterized by diverse etiologies and intricate pathological mechanisms, is a complex cardiopulmonary vascular disorder featuring high morbidity and mortality. Percutaneous pulmonary artery denervation (PADN) represents an emerging interventional treatment method, which shows good prospects in the clinical practice of PH. The PADN has attained preliminary achievements in terms of safety and efficacy. Nevertheless, its long-term prognosis, the characteristics of the appropriate patient populations, and the optimization strategies combined with targeted pharmacotherapy remain to be further explored. This article reviews the current clinical applications of PADN as well as the challenges it confronts.
Objective To summarize the clinical features of motor neuron disease ( MND) with main presentation of pulmonary hypertension, so as to improve the diagnosis.Methods A patientwithMND whose main presentation was pulmonary hypertension was analyzed retrospectively. Meanwhile related literatures were reviewed. Clinical data including symptoms, early signs, misdiagnosis causes, and necessary functional examination of respiratory muscle were collected. Results The symptoms of MND was slow-onset and insidious with gradual progression over time. History inquiring found that the symptoms of muscle wasting and physical debilitation emerged long time before the respiratory symptoms. Physical examination also revealed obvious sign of muscle atrophy. Conclusions MND with main presentation of pulmonary hypertension has been recognized insufficiently and often misdiagnosed as other pulmonary diseases. Detailed history taking, systematic physical examination, and convenient functional examination of respiratory muscle,can not only reduce misdiagnosis, but also avoid some expensive and traumatic process.