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> Disorders > Disease or Syndrome > Tricuspid Valve Insufficiency

Tricuspid Valve Insufficiency

Tricuspid Valve Insufficiency is a condition where the tricuspid valve, located between the right atrium and right ventricle of the heart, fails to close properly.
This allows blood to flow backwards (regurgitate) from the right ventricle into the right atrium, reducing the heart's pumping efficiency.
Symptoms may include fatigue, swelling in the legs, and difficulty breathing.
Accurate diagnosis and reproducible treatment approaches are crucial for effective management of this condition.
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Most cited protocols related to «Tricuspid Valve Insufficiency»

1
Randomized Norwood Procedure Study
Infants were randomly assigned to either the MBT shunt or the RVPA shunt within strata according to the presence or absence of aortic atresia and obstructed pulmonary venous return, with dynamic allocation by the surgeon.23 (link) The primary outcome was the rate of death or cardiac transplantation 12 months after randomization. Secondary outcomes included morbidity during the Norwood and stage II hospitalizations; the incidence of unintended cardiovascular interventions involving the shunt, pulmonary arteries, or neoaorta by 12 months; right ventricular function, right ventricular volume, and the degree of tricuspid-valve regurgitation at discharge after the Norwood procedure, before stage II, and at the age of 14 months on the basis of echocardiograms interpreted by the core laboratory; and the core laboratory interpretation of pulmonary-artery size by angiography before stage II. The right ventricular volumes and ejection fractions were calculated with the use of the biplane pyramidal method.24 (link)
Safety during the first 12 months after randomization was monitored with the use of three measurements: the rate of composite serious adverse events (death, acute shunt failure, cardiac arrest, extracorporeal membrane oxygenation, unplanned cardiovascular reoperation, or necrotizing enterocolitis), the rate of composite serious adverse events with death excluded, and the rate of other complications. The prespecified subgroups for analysis were as follows: birth weight (<2500 or ≥2500 g), preoperative tricuspid-valve regurgitation (proximal jet width, <2.5 or ≥2.5 mm), deep hypothermic circulatory arrest versus regional cerebral perfusion, the surgeon’s annual experience in performing Norwood procedures in infants randomly assigned to this procedure (<6, 6 to 10, 11 to 15, or >15 procedures), and the annual volume of Norwood procedures at each center (<11, 11 to 25, 26 to 40, or >40 procedures). The protocol was approved by each center’s institutional review board, and written informed consent was obtained from a parent or guardian.
Ohye R.G., Sleeper L.A., Mahony L., Newburger J.W., Pearson G.D., Lu M., Goldberg C.S., Tabbutt S., Frommelt P.C., Ghanayem N.S., Laussen P.C., Rhodes J.F., Lewis A.B., Mital S., Ravishankar C., Williams I.A., Dunbar-Masterson C., Atz A.M., Colan S., Minich L.L., Pizarro C., Kanter K.R., Jaggers J., Jacobs J.P., Krawczeski C.D., Pike N., McCrindle B.W., Virzi L, & Gaynor J.W. (2010). Comparison of Shunt Types in the Norwood Procedure for Single-Ventricle Lesions. The New England journal of medicine, 362(21), 1980-1992.
Publication 2010
Angiography Aorta atresia Birth Weight Cardiac Arrest Cardiovascular System Circulatory Arrest, Deep Hypothermia Induced Echocardiography Ethics Committees, Research Extracorporeal Membrane Oxygenation Heart Transplantation Hospitalization Infant Legal Guardians Necrotizing Enterocolitis Norwood Procedures Parent Patient Discharge Perfusion Pulmonary Artery Repeat Surgery Safety Surgeons Tricuspid Valve Insufficiency Veins, Pulmonary Ventricles, Right Ventricular Function, Right
2
Echocardiographic Evaluation of Preterm Infants

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Publication 2015
Atrial Septal Defects Birth Birth Weight Bronchopulmonary Dysplasia Childbirth Congenital Abnormality Congenital Heart Defects Echocardiography Fetal Growth Retardation Gestational Age Heart Heart Ventricle Infant Infant, Newborn Left Ventricular Systolic Dysfunction Lung Mechanical Ventilation Menstruation Oxygen Patent Ductus Arteriosus Patients physiology Pregnancy Premature Birth Preterm Infant Pulmonary Artery Pulmonary Hypertension Respiration Disorders Respiratory Failure Respiratory Rate Right Ventricular Hypertrophy Syndrome Tricuspid Valve Insufficiency
3
Echocardiographic Evaluation of Pulmonary Hypertension
Echocardiographic examinations were performed on commercially available ultrasound systems (Vivid S5, Vivid i, Vivid 7, and Vivid E9 GE Healthcare Vingmed, Trondheim, Norway and ie33, Philips, Eindhoven, the Netherlands) according to the guidelines of the American Society of Echocardiography.21 (link) Images were obtained in left lateral decubitus for parasternal and apical views and supine position for subxyphoidal views using 1.5 to 4.0 MHz phased‐array transducers. The comprehensive examination included standard 2D echocardiography for anatomic imaging and Doppler echocardiography for assessment of velocities. Doppler measurements were carried out over 3 heart cycles during passive expiration. All examinations were digitally stored in a Picture Archiving and Communication System (PACS) with accessibility for offline analysis on workstations (Centricity, GE Healthcare Vingmed, Trondheim, Norway).
Noninvasive assessment of pulmonary artery systolic pressures (sPAP) was achieved by measurement of right ventricular systolic pressure (RVSP) and adding RAP. RVSP was derived from the peak systolic velocity of the tricuspid regurgitation obtained with continuous‐wave (CW) Doppler using the modified Bernoulli equation: ΔP=4×Vmax2. RAP was estimated by the diameter of the inferior vena cava and its variability during inspiration as described before.9 (link),21 (link)–22 (link)Offline reassessment of CW Doppler spectral envelopes, as well as inferior vena cava diameter and respiratory behavior, was conducted in n=258 examination for clarification of misdiagnosis of PH by 2 independent, experienced examiners blinded to invasive data.
Greiner S., Jud A., Aurich M., Hess A., Hilbel T., Hardt S., Katus H.A, & Mereles D. (2014). Reliability of Noninvasive Assessment of Systolic Pulmonary Artery Pressure by Doppler Echocardiography Compared to Right Heart Catheterization: Analysis in a Large Patient Population. Journal of the American Heart Association: Cardiovascular and Cerebrovascular Disease, 3(4), e001103.
Publication 2014
2D Echocardiography Echocardiography Echocardiography, Doppler Heart Inhalation Physical Examination Pulmonary Artery Respiratory Rate Systole Systolic Pressure Transducers Tricuspid Valve Insufficiency Ultrasonography Vena Cavas, Inferior Ventricles, Right
4
Severe Pain Crises in Sickle Cell Anemia

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Publication 2011
Adolescent alpha-Thalassemia Analgesics Bilirubin Blood Platelets Child Clinical Laboratory Services Clinic Visits Count, Reticulocyte Diagnosis Echocardiography, Doppler Enzyme-Linked Immunosorbent Assay Ethics Committees, Research Ferritin Genotype Hemoglobin Hemoglobin, Sickle Hemoglobin Electrophoresis Hemoglobin SC Disease Hemoglobin SS High-Performance Liquid Chromatographies Homozygote Hospitalization Hydroxyurea Lactate Dehydrogenase Legal Guardians Leukocytes Pain Patient Acceptance of Health Care Pharmaceutical Preparations Pulmonary Artery Red Blood Cell Transfusion Serum Severity, Pain Systolic Pressure Thalassemia Transaminase, Serum Glutamic-Oxaloacetic Tricuspid Valve Insufficiency
5
Cardiac Metrics and Tricuspid Regurgitation

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Publication 2019
Cardiac Output Heart MLL protein, human Radius Systole Tricuspid Valve Insufficiency

Most recents protocols related to «Tricuspid Valve Insufficiency»

1
Echocardiography Characterization of Left Ventricular Diastolic Dysfunction
Echocardiography was conducted by experienced sonographers using the Vivid E95 ultrasound system (GE Vingmed Ultrasound, Horten, Norway). Images in cine loop format were analyzed offline using the EchoPAC software (EchoPAC 204, GE Vingmed Ultrasound). All indices were measured according to ASE guidelines [15 , 16 (link)]. Pulse Doppler imaging was used to measure the mitral valve peak early (E) and late (A) diastolic velocities, E/A ratio, and LV isovolumic relaxation time (IVRT). LVEF was calculated using the biplane Simpson’s method. LV global longitudinal strain (GLS) was defined as the average peak longitudinal strains obtained from three apical views [17 (link)]. Peak strain dispersion (PSD) was the standard deviation of the time-to-peak longitudinal strains for all segments [18 (link)].
According to the criteria of ASE [19 (link)], the cut-offs for abnormal LV diastolic performance were, as follows: (1) septal mitral annular e′ velocity of < 7 cm/s or lateral mitral annular e′ velocity of < 10 cm/s; (2) average E/e′ ratio of > 14; (3) LAVI of > 34 ml/m2; (4) peak tricuspid regurgitation velocity of > 2.8 m/s. The patients were diagnosed, as follows: LVDD, when > 50% of the indexes met the above criteria; indeterminate LVDD, when merely 50% of the criteria were positive; with risk of developing LVDD but not LVDD yet, when < 50% of the indexes met the above criteria [19 (link)]. For patients with LVDD, the severity of LVDD was defined according to the 2016 EACVI criteria [19 (link), 20 (link)], as follows: mild, when E/A ≤ 0.8 and E ≤ 50 cm/s or ≥ 2 negative criteria (LAVI > 34 ml/m2, average E/e’ > 14, or TR > 2.8 m/s); moderate, when E/A ≤ 0.8 and E > 50 cm/s or 0.8 < E/A < 2 + ≥ 2 positive criteria (LAVI > 34 ml/m2, average E/e’ > 14, or TR > 2.8 m/s); severe, when E/A ≥ 2. Based on the above two criteria, the patients in the present study were categorized into three subgroups: patients with risks for LVDD but without LVDD (n = 237), patients with indeterminate or mild LVDD (n = 113), and patients with moderate or severe LVDD (n = 98). Among these patients, three patients met the criteria for mild LVDD, and seven patients met the criteria for severe LVDD.
Guo Y., Wang X., Yang C.G., Meng X.Y., Li Y., Xia C.X., Xu T., Weng S.X., Zhong Y., Zhang R.S, & Wang F. (2023). Noninvasive assessment of myocardial work during left ventricular isovolumic relaxation in patients with diastolic dysfunction. BMC Cardiovascular Disorders, 23, 129.
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Publication 2023
Diastole Echocardiography Mitral Valve Patients Pulse Rate Strains Tricuspid Valve Insufficiency Ultrasonography
2
Observational Study of Severe Primary Mitral Regurgitation
All consecutive patients with severe primary mitral regurgitation, who were studied in our outpatient heart valve clinic (HVC) between 1997 and 2015 were included in the study when they had no clinical or echocardiographic indications for surgery. Exclusion criteria were previous cardiac surgery or additional hemodynamically significant valve lesions (moderate or severe) except for tricuspid regurgitation (TR). According to these criteria, 280 consecutive patients (88 females) were identified. These patients form the study population for a previous paper4 (link). The study protocol complies with the Declaration of Helsinki and was approved by the ethics committee of the Medical University of Vienna and was exempted from informed consent requirements owing to its observational study design.
Zilberszac R., Gleiss A., Massetti M., Wisser W., Binder T., Gabriel H, & Rosenhek R. (2023). Left atrial size predicts outcome in severe but asymptomatic mitral regurgitation. Scientific Reports, 13, 3892.
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Publication 2023
Echocardiography Ethics Committees Females Heart Valves Mitral Valve Insufficiency Operative Surgical Procedures Patients Surgical Procedure, Cardiac Tricuspid Valve Insufficiency
3
Comprehensive RV Echocardiographic Analysis
Standardized comprehensive echocardiographic examinations were performed in accordance with the most up-to-date version of chamber quantification guidelines [30 (link)]. Images of the RV were obtained from dedicated RV-focused apical four-chamber views, on which longitudinal strain and traditional parameters, such as tricuspid annular plane systolic excursion (TAPSE), Doppler tissue imaging (DTI)-derived tricuspid lateral annular systolic velocity (S′-wave), right ventricular index of myocardial performance (RIMP), fractional area change (FAC), and myocardial acceleration during isovolumic contraction (IVA), were analyzed during breath-hold and at a frame rate between 40 and 80 fps for strain measurements, which was increased in cases of tachycardia. End of systole was identified by pulmonary valve closure detected on pulsed-wave Doppler tracing of the RV outflow tract, whereas end of diastole was defined as the peak of the R-wave in electrocardiogram. In the case of the presence of intraventricular conduction delay, end of diastole was detected manually as tricuspid valve closure from the continuouswave Doppler profile of tricuspid regurgitation. The automatically generated region of interest (ROI) was manually adjusted in terms of width and orientation in order to include the entire RV myocardium, without the pericardium. The ROI consisted of both the IVS and RV free wall. Afterwards, detailed analysis of RV free-wall longitudinal strain (RVFWSL, 3 segments of RV free wall), RV four-chamber longitudinal strain (RV4CSL, 6 segments of both RV free wall and IVS), and RV septal longitudinal strain (RVSepSL, 3 segments of IVS) was conducted. RV4CSL was calculated in two ways: (a) the arithmetic mean of the segmental peak systolic strain values displayed by the software (RV4CSL 1) and (b) the systolic peak of the average strain curve created by the software (RV4CSL 2). According to the latest recommendations, RVFWSL > −20% (< 20% in absolute value) is likely abnormal, so we considered the value of −20% as a cut-off point [31 (link)].
Smolarek D., Sobiczewski W., Dudziak M, & Hellmann M. (2023). Speckle-tracking echocardiographic evaluation of the right ventricle in patients with ischemic left ventricular dysfunction. Cardiology Journal, 30(1), 73-81.
Publication 2023
Acceleration Diastole Echocardiography Electric Conductivity Electrocardiography Myocardial Contraction Myocardium Pericardium Physical Examination Reading Frames Strains Systole Tissues Tricuspid Valve Insufficiency Ultrasonography, Doppler, Pulsed Valves, Pulmonary Valves, Tricuspid Ventricles, Right
4
Comprehensive Transthoracic Echocardiography Protocol
A comprehensive transthoracic echocardiographic examination was performed using the same system applied for baseline examinations (Vivid E9 system, GE Vingmed, Horton, Norway, with an M5S 1.5- to 4.5-MHz transducer). The predefined echocardiographic study protocol can be inspected in the Supplementary material. Routine echocardiographic and Doppler data were obtained in accordance with the current ASE guidelines (6 (link), 21 (link)). Standard parameters to assess diastolic function included LAVI; diastolic transmitral inflow velocities derived from pulsed wave-Doppler signal as well as the deceleration time; the septal, lateral, or average early diastolic mitral annular velocity (e′) assessed by pulsed-wave tissue Doppler; and E/e′ ratio. The RV-RA pressure difference was estimated from the maximum transvalvular velocity of the tricuspid regurgitation during systole.
2D STE strain studies were analyzed offline using the EchoPAC v203 software (GE Healthcare). Global peak systolic longitudinal LV strain (LV GLS) was determined from apical 4-chamber, 2-chamber, and long-axis views (17 segment LV model). Phasic LAS was assessed as proposed by the recent EACVI recommendations (12 (link)) from an LA focused apical 4-chamber-view, avoiding foreshortening. Three cardiac cycles were recorded for each view and stored for offline analysis. Gain, depth, and frame rate (60–80 frames/s) were optimized for image acquisition. The region of interest was placed on the atrial walls, distributing the interatrial septum and atrial free wall into six segments. LAS was analyzed QRS-triggered. LASr was identified from the plotted average strain curve as the maximum amplitude during ventricular systole. LA conduit strain (during passive LV filling; LAScd) and LA contraction strain (during peak atrial contraction; LASct) were calculated from the generated strain curve as previously described (4 (link), 12 (link), 22 (link)) (Figure 1).
Brand A., Romero Dorta E., Wolf A., Blaschke-Waluga D., Seeland U., Crayen C., Bischoff S., Mattig I., Dreger H., Stangl K., Regitz-Zagrosek V., Landmesser U., Knebel F, & Stangl V. (2023). Phasic left atrial strain to predict worsening of diastolic function: Results from the prospective Berlin Female Risk Evaluation follow-up trial. Frontiers in Cardiovascular Medicine, 10, 1070450.
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Publication 2023
Deceleration Diastole Echocardiography Epistropheus Heart Heart Atrium Heart Ventricle Physical Examination Pressure Reading Frames Septum, Atrial Strains Systole Tissues Transducers Tricuspid Valve Insufficiency Ultrasonography, Doppler, Pulsed
5
Preoperative Risk Factors for POAF
Previous studies have suggested that demographic information,27 (link) clinical data, medications,28 (link) and complications29 (link) were associated with the incidence of POAF. Preoperative cardiac function was assessed by ECG (including sinus tachycardia, sinus bradycardia, arrhythmia, myocardial ischemia, conduction block, P-wave, PR interval, and QTc interval) and ultrasonic cardiogram (UCG) (including MR, tricuspid regurgitation [TR], LV mass, segmental wall motion abnormality, left atrium [LA] volume, LV ejection fraction [LVEF], rheumatic heart disease, pulmonary hypertension, aortic sinus inner diameter, and E/A]). Acute Physiology and Chronic Health Evaluation (APACHE II) and Sequential Organ Failure Assessment (SOFA) scores were used to estimate the severity of the patient’s illness on the day of ICU admission. Clinical variables containing prior health history, thoracic surgery, surgery procedure, laboratory blood tests, postoperative complications, duration of mechanical ventilation, ICU stay, and hospital stays were collected from the electronic medical record system.
Echocardiography was performed by an experienced sonographer who had received advanced training and certification in echocardiographic imaging, according to the guidelines of the American Society of Echocardiography (ASE). M-mode echocardiography was used to measure LA dimensions, and the LVEF was calculated with Simpson’s method. Doppler echocardiography assessed early (E) and late (A) diastolic mitral inflow velocities and the E/A ratio.30 (link),31 (link)
Zhang J., Wang J., Jiang Y., Zheng X., Li W, & Li H. (2023). Association of Mitral Regurgitation with Postoperative Atrial Fibrillation in Critically Ill Noncardiac Surgery Patients: A Prospective Cohort Study. International Journal of General Medicine, 16, 769-783.
Publication 2023
Atrium, Left Cardiac Arrhythmia Diastole Echocardiography Echocardiography, Doppler Echocardiography, M-Mode Heart Heart Block Hematologic Tests Mechanical Ventilation Myocardial Ischemia Operative Surgical Procedures Patients Pharmaceutical Preparations physiology Postoperative Complications Pulmonary Hypertension Rheumatic Heart Disease Sinus, Aortic Sinuses, Nasal Sinus Tachycardia Thoracic Surgical Procedures Tricuspid Valve Insufficiency Ultrasonics

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