Objective To explore and compare the diagnostic value of blood pressure, brain natriuretic peptide (BNP), pulmonary artery systolic pressure (PASP) in evaluating right ventricular dysfunction (RVD) in patients with acute pulmonary embolism (APE). Methods A retrospective study was conducted on 84 APE patients who were diagnosed by computed tomographic pulmonary angiography. The patients were divided into a RVD group and a non-RVD group by echocardiography. Eighteen clinical and auxiliary examination variables were used as the research factors and RVD as the related factor. The relationship between these research factors and RVD were evaluated by logistic regression model, the diagnostic value of BNP and PASP to predict RVD was analyzed by receiver-operating characteristic (ROC) curve analysis. Results The patients with RVD had more rapid heart rate, higher diastolic blood pressure, higher mean arterial pressure, higher incidence of BNP>100 pg/ml and higher incidence of PASP>40 mm Hg (allP<0 05="" upon="" logistic="" regression="" model="" bnp="">100 pg/ml (OR=4.904, 95%CI 1.431–16.806, P=0.011) and PASP>40 mm Hg (OR=6.415, 95%CI 1.509–27.261, P=0.012) were independent predictors of RVD. The areas under the ROC curve to predict RVD were 0.823 (95%CI 0.729–0.917) for BNP, and 0.798 (95%CI 0.700–0.896) for PASP. Conclusions Blood pressure related parameters can not serve as a predictor of RVD. Combined monitoring of BNP level and PASP is helpful for accurate prediction of RVD in patients with APE.
Abstract: Right ventricular dysfunction or right heart failure is a complex clinical syndrome and often leads to a poor prognosis and high mortality. In order to detect right ventricular dysfunction at an early stage, provide a therapy guidance and evaluate treatment outcomes, right ventricular function evaluation has aroused more and more concern in clinical physicians. With the advantages of being non-invasive, accuracy and repetitiveness, echocardiography is used extensively in the assessment of heart function. In this review, we focus on how to use echocardiography to evaluate right ventricular function easily, efficiently, accurately and sensitively, and provide a good foundation for its further clinical application.
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.
Objective To investigate the changes of pulmonary circulation and right ventricular function after lung volume reduction surgery. Methods We retrospectively analyzed the clinical data of 34 patients of severe chronic obstructive pulmonary disease with single or double lung volume reduction surgery through thoracoscope in our hospital from 2013 through 2014. Ultrasonic testing was conducted peroperatively, on postoperative day 3–5, at 1 month and 3 months after surgery. Results Right ventricular stroke volume (61.00±10.54 ml vs. 38.34±10.04 ml) and right ventricular ejection fraction decreased (58.00%±9.00% vs. 49.00%±10.00%), mean pulmonary arterial pressure (23.35±5.07 mm Hg vs. 29.57±6.32 mm Hg) and total pulmonary vascular resistance (9.28±2.14 mm Hg vs. 12.05±4.36 mm Hg) increased with statistical differences (P<0.05) on postoperative day 3–5. Right heart ejection fraction was 51%±11% with a statistical increase (P<0.05) at 1 month after surgery. There was no statistical difference in indicators above between 3 months after surgery and before surgery. Conclusion Changes of pulmonary circulation and right ventricular function may be temporary. Right ventricular dysfunction decreases, pulmonary arterial pressure, and total pulmonary vascular resistance increases on postoperative day 3–5 d. But the changes gradually recover in 1–3 months after surgery, and could be gradually restored to preoperative level.
Objective To analyze and summarize the early and medium-term outcomes of self-expanding interventional pulmonary valve stent (SalusTM) for right ventricular outflow tract dysfunction with severe pulmonary valve regurgitation. Methods We established strict enrollment and follow-up criteria. Patients who received interventional pulmonary valve in transthoracic implantation in Guangdong Provincial People’s Hospital from September 2, 2021 to July 18, 2023 were prospectively included, and all clinical data of patients were collected and analyzed. ResultsA total of 38 patients with severe pulmonary regurgitation were included, with 23 (60.5%) males and 15 (39.5%) females. The mean age was 24.08±8.12 years, and the mean weight was 57.66±13.54 kg. The preoperative mean right ventricular end-diastolic volume index (RVEDVI) and right ventricular end-systolic volume index (RVESVI) were 151.83±42.84 mL/m2 and 83.34±33.05 mL/m2, respectively. All patients successfully underwent transcatheter self-expandable pulmonary valve implantation, with 3 (7.9%) patients experiencing valve stent displacement during the procedure. Perioperative complications included 1 (2.6%) patient of postoperative inferior wall myocardial infarction and 1 (2.6%) patient of poor wound healing. The median follow-up time was 12.00 (6.00, 17.50) months. During the follow-up period, there were no deaths or reinterventions, and no patients had recurrent severe pulmonary regurgitation. Three (7.9%) patients experienced chest tightness and chest pain, and 1 (2.6%) patient developed frequent ventricular premature beats. Compared with preoperative values, the right atrial diameter, right ventricular diameter, and tricuspid annular plane systolic excursion were significantly reduced at 6 months and 1 year postoperatively, with improvement in the degree of pulmonary regurgitation (P<0.01). Compared with preoperative values, RVEDVI and RVESVI decreased to 109.51±17.13 mL/m2 and 55.88±15.66 mL/m2, respectively, at 1 year postoperatively (P<0.01). Conclusion Self-expanding interventional pulmonary valve in transthoracic implantation is safe and effective for severe pulmonary valve regurgitation and shows good clinical and hemodynamic results in one-year outcome.
Objective To analyze the clinical features of patients with acute pulmonary embolism ( APE) with normal blood pressure and right ventricular dysfunction. Methods 130 hospitalized patients with normotensive APE between January 2009 and January 2012 were retrospectively analyzed. The patients underwent transthoracic echocardiography to determine if they were complicated with RVD. The clinical features, risk factors, diagnosis, and treatment were analyzed and compared between the normotensive APE patients with or without RVD. Results 41 normotensive APE patients with RVD were as RVD group, and other 89 patients without RVD were as non-RVD group. The incidences of syncope ( 34.1% vs. 7.8% ) , tachycardia( 41.4% vs. 21.3% ) , P2 hyperthyroidism( 46.3% vs. 25.8% ) , jugular vein filling ( 12.1% vs. 1.1% ) , and cyanosis ( 26.8% vs. 8.9% ) were all significantly higher in the RVD group than those in the non-RVD group ( P lt; 0.05) . Computed tomography pulmonary angiography ( CTPA) revealed that the incidences of thromboembolism involving proximal pulmonary artery ( 58. 3% vs. 8. 3% ) and thromboembolism involving lobar pulmonary ( 77.8% vs.51.2% ) were also higher in the RVD group ( P lt; 0.001, P = 0.025 ) . In the RVD group, the patients were assigned to received thrombolysis plus anticoagulation therapy, or anticoagulation therapy alone. The clinical indicators ( heart rate, PaCO2 , AaDO2 , SPAP, TRPG) were all statistically improved after thrombolysis or anticoagulation treatment ( P lt;0.001) . But compared with the patients who underwent anticoagulation therapy alone, the cost of treatment and the incidence of minor bleeding were significantly higher, and the levels of AaDO2 , SPAP and TRPG were statistically lower in the patients with thrombolysis plus anticoagulation therapy. Conclusions For APE patients with central pulmonary embolism demonstrated by CTPA, syncope, and tachycardia, transthoracic echocardiograph should be performed as early as possible to confirm RVD diagnosis. For normotensive APE patients with RVD, anticoagulant treatment can achieve higher efficacy of costeffectiveness ratio.
ObjectiveTo investigate pulmonary artery growth, valvular regurgitation and right heart function after right ventricle-pulmonary artery (RV-PA) anastomosis for right ventricle outflow (RVOT) reconstruction in patients with different types of pulmonary atresia and ventricle septal defect (PA/VSD). MethodsClinical data of 31 PA/VSD patients who underwent right ventricle-pulmonary anastomosis for RVOT reconstruction from November 2002 to September 2012 in Guangdong General Hospital were retrospectively analyzed. There were 20 male and 11 female patients with their age ranging from 14 days to 14.50 years (47.90±53.84 months). Patients were followed up after discharge to evaluate the anastomasis, pulmonary artery growth, pulmonary artery and tricuspid regurgitation and their relationship with follow-up duration. Right ventricular strain and other echocardiography indexes were used to evaluate right heart function. ResultsThree patients died postoperatively. Twenty-seven patients (27/31, 87.1%)were followed up for 4-129 (35.97±28.24)months. There was no late death during follow-up. There was no anastomotic restenosis in patients who received radical surgery. Four patients who received palliative surgery had comparative anastomotic restenosis. The diameters of RV-PA anastomasis, left and right branches of the pulmonary artery during follow-up were significantly larger than early postoperative diameters (P < 0.05). Echocardiography showed that pulmonary artery and tricuspid regurgitation were aggravated, which was not correlated to follow-up duration. Overall right heart function was good during follow-up. ConclusionsClinical outcomes of RV-PA anastomosis for RVOT reconstruction in patients with PA/VSD are satisfactory. RV-PA anastomasis, left and right branches of the pulmonary artery can keep their growth and development. Mid-term and long-term right heart function is good.
Objective To compare the clinical efficacy and safety of thrombolysis with anticoagulation therapy for patients with acute sub-massive pulmonary thromboembolism. Methods The clinical data of 84 patients with acute sub-massive pulmonary thromboembolism were analyzed retrospectively, mainly focusing on the in-hospital efficacy and safety of thrombolysis and/ or anticoagulation. The efficacy was evaluated based on 6 grades: cured, markedly improved, improved, not changed, deteriorated and died. Results Among the 84 patients,49 patients received thrombolysis and sequential anticoagulation therapy( thrombolysis group) , 35 patients received anticoagulation therapy alone( anticoagulation group) . As compared with the anticoagulation group, the thrombolysis group had higher effective rate( defined as patients who were cured, markedly improved or improved, 81. 6% versus 54. 3%, P = 0. 007) , lower critical event occurrence ( defined as clinical condition deteriorated or died, 2. 0% versus 14. 3% , P = 0. 032) . There was no significant difference in bleeding rates between the two groups ( thrombolysis group 20. 4% versus anticoagulation group 14. 3% , P gt; 0. 05) . No major bleeding or intracranial hemorrhage occurred in any of the patients. Conclusions Thrombolysis therapy may be more effective than anticoagulation therapy alone in patients with acute sub-massive pulmonary thromboembolism, and thus warrants further prospective randomized control study in large population.