VC receives inflow from popular Tenidap Biological Activity pulmonary vein, i.e., supracardiac totalVC receives inflow

VC receives inflow from popular Tenidap Biological Activity pulmonary vein, i.e., supracardiac totalVC receives inflow

VC receives inflow from popular Tenidap Biological Activity pulmonary vein, i.e., supracardiac total
VC receives inflow from popular pulmonary vein, i.e., supracardiac total anomalous pulmonary monary venous return (see, below); widespread atrium, complete AV defect; double outlet suitable ventricle/transposition of venous return (see, below); prevalent atrium, comprehensive models were instrumental in preparing for complete biventricular the good arteries with pulmonary atresia. 3D-printed AV defect; double outlet suitable ventricle/transposition with the good arteries with pulmonary atresia. 3D-printed models have been instrumental AAo: ascending aorta, Cx: circumflex coronary repair the patient successfully underwent subsequently. Abbreviations:in preparing for total biventricular repair the patient successfully underwent subsequently. Abbreviations: AAo: ascending aorta, Cx: LPA: left pulmonary artery, LV: artery, DAo: descending aorta, L-AA: left-sided morphologically appropriate atrial D-Fructose-6-phosphate disodium salt manufacturer appendage, circumflex coronary artery, DAo: left ventricle, PDA:L-AA: left-sided morphologically correct morphologically appropriate atrial pulmonary artery, LV: leftAV valve, descending aorta, patent arterial duct, R-AA: right-sided atrial appendage, LPA: left appendage, RAVV: suitable ventricle, RV: suitable ventricle, SVC: right-sided superior vena cava, VSD: ventricular septal defect. RAVV: appropriate AV valve, RV: right PDA: patent arterial duct, R-AA: right-sided morphologically appropriate atrial appendage, ventricle, SVC: right-sided superior vena cava, VSD: ventricular septal defect.Biomolecules 2021, 11, 1703 Biomolecules 2021, 11, x FOR PEER REVIEW10 of 20 10 ofFigure five. 3D-printed blood volume (A) and hollow (B) models of suitable atrial isomerism, visceral heterotaxy, and dextroFigure five. 3D-printed blood volume (A) and hollow (B) models of ideal atrial isomerism, visceral heterotaxy, and dextrocardia cardia (Case ten). Posterior view: right-sided atrium is opened around the hollow model. Complicated anomalies are illustrated on (Case 10). Posterior view: right-sided atrium is opened around the hollow model. Complicated anomalies are illustrated around the the models left-sided IVC; right-sided SVC receives inflow from typical pulmonary vein (cPV), i.e., supracardiac total models left-sided IVC; right-sided SVC receives inflow from prevalent pulmonary vein (cPV), i.e., supracardiac total anomalous pulmonary venous return. Tortuous patent arterial duct (PDA) reaches the left pulmonary artery (LPA); there anomalous pulmonary venous the entry point. The models were instrumental in preparing for full biventricular repair is pulmonary coarctation () at return. Tortuous patent arterial duct (PDA) reaches the left pulmonary artery (LPA); there’s pulmonarysuccessfully () in the entry point. The models had been instrumental in organizing for complete biventricular repair the patient coarctation underwent subsequently. Abbreviations: cPV: prevalent vertical pulmonary vein, DAo: descending the patient effectively underwent subsequently. Abbreviations: cPV: widespread vertical pulmonaryLV: left ventricle, PDA: aorta, IVC: left-sided inferior vena cava, LPA: left pulmonary artery, LPV: left pulmonary vein, vein, DAo: descending aorta, IVC: left-sided inferior vena cava, LPA: left pulmonary artery, LPV: RPV: ideal pulmonary vein, SVC: right-sided patent arterial duct, R-A: right-sided atrium, RPA: ideal pulmonary artery, left pulmonary vein, LV: left ventricle, PDA: superior vena duct, patent arterial cava. R-A: right-sided atrium, RPA: proper pulmonary artery, RPV: suitable pulmonary vein, SVC: right-sided superior vena cava.Patients with un.

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