Transcatheter aortic valve replacement (TAVR) has emerged as the standard treatment for severe aortic stenosis, demonstrating comparable efficacy to traditional surgery in low and intermediate-risk patients. However, the bioprosthetic valves utilized in TAVR have a limited lifespan, and bioprosthetic valve failure, including calcification, rupture or infection may develop, leading to poor clinical outcomes. Elevated blood pressure has been identified as a key factor in aortic valve calcification, and its role in bioprosthetic valve failure is gaining increasing attention. Hypertension may accelerate the calcification process and exacerbate valve failure due to increased mechanical stress on the valve, activation of the renin-angiotensin system, and enhanced thrombus formation. Furthermore, elevated blood pressure interacts with prosthesis mismatch and paravalvular leak, jointly affecting valve durability. This review explores the impact of elevated blood pressure on bioprosthetic valve calcification and failure after TAVR, and emphasizes the importance of blood pressure control, optimized preoperative assessment, and appropriate valve selection in reducing valve failures.
Humans ; Transcatheter Aortic Valve Replacement/adverse effects* ; Calcinosis/etiology* ; Bioprosthesis ; Heart Valve Prosthesis/adverse effects* ; Prosthesis Failure ; Aortic Valve Stenosis/surgery* ; Aortic Valve/surgery* ; Hypertension/physiopathology*

Structural valve deterioration (SVD) refers to intrinsic and irreversible pathological changes in the components of prosthetic heart valves, manifesting as fibrosis, calcification, wear and tear, loosening, as well as strut fracture or deformation of the valve framework. These changes ultimately lead to valve stenosis and/or regurgitation.The mechanisms may be related to mechanical stress, immune response and abnormal calcium-phosphorus metabolism. Studies have shown that risk factors for SVD include patient factors (such as age, underlying cardiovascular disease and comorbidities), valve factors (such as material properties, processing techniques, and valve type), and surgical factors (such as valve injury, suboptimal stent expansion, and irregular stent release morphology). Clinical imaging assessment of SVD demonstrates complementary advantages among echocardiography, multi-detector spiral CT and cardiac magnetic resonance imaging, with distinct diagnostic objectives. The primary management strategies for SVD after trans-catheter aortic valve replacement (TAVR) include drug therapy, redo-TAVR, surgical aortic valve replacement (SAVR) and the novel SURPLUS technique. Among them, redo-TAVR has become a common method because of its minimally invasive nature, but it is still necessary to further clarify the patient indications and optimize the surgical strategy. SAVR is reserved for young, low-risk patients; SURPLUS combines the advantages of SAVR and TAVR, making it suitable for cases where redo-TAVR is unfeasible or contraindicated, while the risk of SAVR is excessively high. This article reviews the latest progress of SVD following TAVR treatment to provide reference for research into the durability of bioprosthetic valve and clinical intervention of SVD.
Humans ; Transcatheter Aortic Valve Replacement/adverse effects* ; Heart Valve Prosthesis/adverse effects* ; Prosthesis Failure ; Aortic Valve/pathology* ; Aortic Valve Stenosis/surgery*

OBJECTIVES: To evaluate the early clinical efficacy and safety of trans-catheter aortic valve replacement (TAVR) for patients with severe pure native aortic regurgitation (PNAR) who are not suitable for conventional surgical aortic valve replace-ment. METHODS: A retrospective analysis was conducted on 48 patients with PNAR who underwent TAVR at the Department of Cardiac Surgery, the First Affiliated Hospital of Sun Yat-sen University between March 2019 and February 2025. These included 25 cases with transfemoral approach (TF-TAVR group) and 23 cases with transapical approach (TA-TAVR group). Efficacy and safety were assessed by analyzing baseline characteristics, all-cause mortality, and procedure-related complications. RESULTS: Compared with the TA-TAVR group, the TF-TAVR group exhibited significantly smaller aortic annulus circumference and diameter, left ventricular outflow tract circumference and diameter, diameters of the left, right, and non-coronary sinuses, and sinotubular junction (STJ) diameter, along with a shorter distance from the STJ to the aortic annular plane ring plane, a smaller annulus angle (all P<0.05). Additionally, the TF-TAVR group showed a deeper prosthesis implantation depth relative to the aortic annular plane (P<0.01). The overall technical success rate was 91.67%, and the device success rate was 83.33%. Post-TAVR, both groups demonstrated significant improvement in left ventricular end-diastolic diameter (both P<0.05), while only the TA-TAVR group showed significant reduction in left ventricular end-systolic diameter (P<0.05). For primary outcomes, in-hospital mortality occurred in 2 patients (4.17%). No additional deaths were reported at 60 or 90 d after surgery. During 90-180 d after surgery, one patient in the TF-TAVR group died of sudden cardiac death, and one in the TA-TAVR group died of gastroin-testinal bleeding. During 180 d-1 year after surgery, one patient in the TF-TAVR group died of low cardiac output syndrome. No statistically significant differences were observed in 1-year Kaplan-Meier survival curves between the two groups (P>0.05). No conduction block events occurred in TA-TAVR group during hospitalization or 1-year follow-up, while high-grade atrioventricular block, left bundle branch block, permanent pacemaker implantation occurred in TF-TAVR group during hospitalization (12.00%, 4.00%, and 12.00%, respectively). CONCLUSIONS TAVR demonstrates high feasibility and acceptable safety for severe PNAR patients who are not suitable for conventional SAVR. Both TF-TAVR and TA-TAVR show comparable early postoperative efficacy and safety profiles.
Humans ; Transcatheter Aortic Valve Replacement/adverse effects* ; Aortic Valve Insufficiency/surgery* ; Retrospective Studies ; Male ; Female ; Aged ; Treatment Outcome ; Aortic Valve/surgery* ; Aged, 80 and over ; Heart Valve Prosthesis

Objectives: To evaluate the feasibility and preliminary clinical results of transcatheter pulmonary valve replacement (TPVR) with the domestically-produced balloon-expandable Prizvalve system. Methods: This is a prospective single-center observational study. Patients with postoperative right ventricular outflow tract (RVOT) dysfunction, who were admitted to West China Hospital of Sichuan University from September 2021 to March 2023 and deemed anatomically suitable for TPVR with balloon-expandable valve, were included. Clinical, imaging, procedural and follow-up data were analyzed. The immediate procedural results were evaluated by clinical implant success rate, which is defined as successful valve implantation with echocardiography-assessed pulmonary regurgitationResults: A total of 5 patients were included, with 4 males, aged 14 to 37 years. The initial diagnosis included Tetralogy of Fallot (2 cases), truncus arteriosus (1 case), pulmonary atresia (1 case) and subaortic stenosis (1 case, prior Ross procedure). Four patients underwent RVOT reconstruction with homograft or artificial conduit, and one patient was treated with trans-annular patch technique. The indications of TPVR included RVOT obstruction and regurgitation (3 cases), isolated obstruction (1 case), and isolated regurgitation (1 case). Of the 4 patients with varying severity of ROVT obstruction, the average preprocedural peak jet velocity of RVOT was 3.5 m/s, and the average peak pressure gradient was 50.0 mmHg. Except for one patient, who had previously been implanted with a covered Cheatham-Platinum (CP) stent due to severe stenosis of the main pulmonary artery, other patients underwent pre-stenting with a covered CP stent before TPVR. Clinical implant success was achieved in all of the 5 patients, and there was no serious periprocedural complications. The average trans-pulmonary peak jet velocity and peak pressure gradient derived from postprocedural echocardiography was 2.3 m/s and 21.2 mmHg, respectively. All patients experienced significant symptom relief after the procedure. All patients completed 3-month follow-up, and 4 completed 6-month follow-up. There was no case of infectious endocarditis during follow-up. All patients were graded as NYHA functional class one at the latest follow-up. Conclusions: TPVR using the domestically-produced balloon-expandable Prizvalve system is safe and feasible for the treatment of patients with post-surgical RVOT dysfunction and suitable landing-zone anatomy. The safety, effectiveness, and long-term valve durability of the Prizvalve system deserve further research.
Male ; Humans ; Pulmonary Valve/surgery* ; Heart Valve Prosthesis/adverse effects* ; Heart Valve Prosthesis Implantation ; Constriction, Pathologic/surgery* ; Prospective Studies ; Ventricular Outflow Obstruction/surgery* ; Treatment Outcome ; Cardiac Catheterization/methods* ; Transcatheter Aortic Valve Replacement

Humans ; Transcatheter Aortic Valve Replacement/adverse effects* ; Heart Septal Defects, Ventricular/surgery* ; Heart Valve Prosthesis Implantation ; Iatrogenic Disease ; Ventricular Outflow Obstruction/surgery* ; Treatment Outcome ; Aortic Valve/surgery*

Objectives: To evaluate the feasibility and preliminary clinical results of transcatheter pulmonary valve replacement (TPVR) with the domestically-produced balloon-expandable Prizvalve system. Methods: This is a prospective single-center observational study. Patients with postoperative right ventricular outflow tract (RVOT) dysfunction, who were admitted to West China Hospital of Sichuan University from September 2021 to March 2023 and deemed anatomically suitable for TPVR with balloon-expandable valve, were included. Clinical, imaging, procedural and follow-up data were analyzed. The immediate procedural results were evaluated by clinical implant success rate, which is defined as successful valve implantation with echocardiography-assessed pulmonary regurgitationResults: A total of 5 patients were included, with 4 males, aged 14 to 37 years. The initial diagnosis included Tetralogy of Fallot (2 cases), truncus arteriosus (1 case), pulmonary atresia (1 case) and subaortic stenosis (1 case, prior Ross procedure). Four patients underwent RVOT reconstruction with homograft or artificial conduit, and one patient was treated with trans-annular patch technique. The indications of TPVR included RVOT obstruction and regurgitation (3 cases), isolated obstruction (1 case), and isolated regurgitation (1 case). Of the 4 patients with varying severity of ROVT obstruction, the average preprocedural peak jet velocity of RVOT was 3.5 m/s, and the average peak pressure gradient was 50.0 mmHg. Except for one patient, who had previously been implanted with a covered Cheatham-Platinum (CP) stent due to severe stenosis of the main pulmonary artery, other patients underwent pre-stenting with a covered CP stent before TPVR. Clinical implant success was achieved in all of the 5 patients, and there was no serious periprocedural complications. The average trans-pulmonary peak jet velocity and peak pressure gradient derived from postprocedural echocardiography was 2.3 m/s and 21.2 mmHg, respectively. All patients experienced significant symptom relief after the procedure. All patients completed 3-month follow-up, and 4 completed 6-month follow-up. There was no case of infectious endocarditis during follow-up. All patients were graded as NYHA functional class one at the latest follow-up. Conclusions: TPVR using the domestically-produced balloon-expandable Prizvalve system is safe and feasible for the treatment of patients with post-surgical RVOT dysfunction and suitable landing-zone anatomy. The safety, effectiveness, and long-term valve durability of the Prizvalve system deserve further research.
Male ; Humans ; Pulmonary Valve/surgery* ; Heart Valve Prosthesis/adverse effects* ; Heart Valve Prosthesis Implantation ; Constriction, Pathologic/surgery* ; Prospective Studies ; Ventricular Outflow Obstruction/surgery* ; Treatment Outcome ; Cardiac Catheterization/methods* ; Transcatheter Aortic Valve Replacement

Humans ; Transcatheter Aortic Valve Replacement/adverse effects* ; Heart Septal Defects, Ventricular/surgery* ; Heart Valve Prosthesis Implantation ; Iatrogenic Disease ; Ventricular Outflow Obstruction/surgery* ; Treatment Outcome ; Aortic Valve/surgery*

Humans ; Aortic Valve/surgery* ; Heart Valve Prosthesis/adverse effects* ; Heart Valve Prosthesis Implantation ; Treatment Outcome ; Transcatheter Aortic Valve Replacement/adverse effects* ; Aortic Valve Stenosis/surgery* ; Aortic Valve Insufficiency/surgery*

OBJECTIVES: Due to the lack of large-sized pulmonary valved conduit products in clinical practice, hand-sewn expanded polytetrafluoroethylene (ePTFE) valved conduit has been used for right ventricular outflow tract (RVOT) reconstruction in many heart centers around the world. This study aims to summarize the early results of the ePTFE valved conduit and the sewing technology of the conduit in combination with the latest progress, and to provide a reference for the application of ePTFE valved conduit. METHODS: A total of 21 patients using ePTFE valved conduit for RVOT reconstruction in the Second Xiangya Hospital, Central South University from October 2018 to October 2020 were prospectively enrolled in this study. The age at the implantation of the conduit was 4.3 to 43.8 (median 15.1) years old, with weight of (38.9±4.1) kg. In this cohort, 14 patients underwent re-reconstruction of RVOT, including 12 patients with pulmonary regurgitation at 6.3 to 31.0 (median 13.8) years after tetralogy of Fallot (TOF) repair, and 2 patients with failed bovine jugular vein conduit (BJVC). Seven patients underwent Ross operations. Among them, 3 were for aortic valve stenosis, 2 were for aortic regurgitation, and 2 were for both stenosis and regurgitation. The ePTFE valved conduits were standard hand-sewn during the surgery. The 3 leaflets were equal in size with arc-shaped lower edge of the valve sinus. The free edge of the valve leaflets was straight with the length of about 1 mm longer than the diameter. The height of the valve sinus was 4/5 of the diameter. The junction of the valve leaflet was 3/4 of the height of the sinus. The designed leaflets were then continuous non-penetrating sutured into the inner surface of Gore-Tex vessel to make a valved conduit. Valved conduits with diameter of 18, 20, and 22 mm were used in 2, 9, and 10 cases, respectively. The surgical results, postoperative recovery time, and serious complications were summarized, and the changes of postoperative cardiac function status and hemodynamic status of the conduits were investigated. RESULTS: During the implantation of ePTFE valved conduit for RVOT reconstruction, 2 patients underwent mechanical mitral valve replacement with Ross operation, 2 patients with pulmonary regurgitation with repaired TOF underwent left and right pulmonary artery angioplasty, and 1 patient with failed BJVC underwent tricuspid valvuloplasty. The cardiopulmonary bypassing time for patients underwent re-reconstruction of RVOT was (130.9±16.9) min, with aorta clamping for 1 patient to repair the residual defect of the ventricular septum. The cardiopulmonary bypassing and aorta clamping time for Ross operation were (242.7±20.6) min and (145.6±10.5) min, respectively. The duration of postoperative ventilator assistance, intensive care unit stay, and hospital stay were 3.5 h to 7.7 d (median 17.1 h),11.2 h to 29.5 d (median 1.9 d), and 6.0 to 56.0 (median 13.0) d, respectively. All patients survived after discharge from hospital. The follow-up rate after discharge was 100% with median time at 15.0 (13.0 to 39.0) months. No death happened during the follow-up. One patient underwent stent implantation due to right coronary stenosis 2 months after Ross operation. One patient underwent balloon dilation due to right pulmonary artery ostium stenosis 1 year after re-reconstruction of RVOT. The cardiac function of all patients recovered to NYHA class I 6 months after operation. The peak pressure gradient across the valve measured by transthoracic echocardiography before discharge was (9.4±2.6) mmHg (1 mmHg=0.133 kPa), and (18.3±6.1) mmHg at the last follow-up. There was no significant increase in the gradient during the follow-up (P=0.134). No patient suffered from mild or more pulmonary regurgitation. CONCLUSIONS Hand-sewn ePTFE valved conduit is feasible for RVOT reconstruction. It is a promising material for RVOT reconstruction which can effectively meet clinical need. In our experience, the ePTFE valved conduit is simple to manufacture with satisfactory early outcomes.In the application of ePTFE valved conduit, attention should be paid to implantation indications and postoperative anticoagulation management, especially to the preparation details of the valved conduit, to obtain better function and durability of the conduit after implantation.
Adolescent ; Animals ; Cattle ; Constriction, Pathologic/surgery* ; Heart Valve Prosthesis/adverse effects* ; Heart Valve Prosthesis Implantation/methods* ; Humans ; Infant ; Polytetrafluoroethylene ; Prosthesis Design ; Pulmonary Valve Insufficiency/surgery* ; Retrospective Studies ; Treatment Outcome ; Ventricular Outflow Obstruction/surgery*

Anticoagulation drugs should be used for patients with mechanical heart valve (MHV) in case of potential risk of thrombosis. Pregnant women with MHV have to change therapies due to teratogenic effect of some anti-coagulation drugs. European Society of Cardiology clinical guidelines for the management of cardiovascular diseases during pregnancy gives specific suggestions for anticoagulation therapy.We have treated 2 patients with mechanical heart valve thrombosis (MVT) during pregnancy: One received low molecular weight heparin (LMWH) throughout the pregnancy and developed MVT at the third trimester of pregnancy; one developed MVT at the first trimester when replacing vitamin K antagonists (VKA) with LMWH. These patients raised secondary reflection on the balance between clinical guideline and personalized medicine. During LMWH therapy, we should dynamically monitor patients' anti-activated factor X (anti-Xa) level to evaluate coagulation function during pregnancy. When a pregnant woman with MHV develops symptoms of acute heart failure, stuck mechanical valve should be paid attention to and surgery should be promptly performed if necessary.
Anticoagulants/adverse effects* ; Female ; Heart Valve Prosthesis/adverse effects* ; Heart Valves ; Heparin, Low-Molecular-Weight/adverse effects* ; Humans ; Pregnancy ; Pregnancy Complications, Cardiovascular/drug therapy* ; Thrombosis/drug therapy*