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2. Insights on the echocardiographically normally functioning bicuspid aortic valve and root from a morphofunctional magnetic resonance imaging study. Valves in the Heart of the Big Apple VI: evaluation and management of valvular heart diseases 2010

Author

DELLA CORTE, Alessandro, DEL VISCOVO, Luca, Bancone C, Conti CA, Votta E, Mastroianni C, Citarella A, DE FEO, Marisa, Redaelli A, NAPPI, Gianantonio, DELLA CORTE, Alessandro, DEL VISCOVO, Luca, Bancone, C, Conti, Ca, Votta, E, Mastroianni, C, Citarella, A, DE FEO, Marisa, Redaelli, A, and Nappi, Gianantonio

Published
2010

6. Dynamic finite element analysis of the aortic root from MRI-derived parameters

Author

Emiliano Votta, Alberto Redaelli, Luca Del Viscovo, Alessandro Della Corte, Carlo Angelo Conti, Ciro Bancone, Maurizio Cotrufo, Conti, Ca, Votta, E, DELLA CORTE, Alessandro, DEL VISCOVO, Luca, Bancone, C, Cotrufo, M, and Redaelli, A.

Subjects
Male, Models, Anatomic, Finite Element Analysis, Biomedical Engineering, Biophysics, Models, Biological, Stress (mechanics), medicine.artery, medicine, Humans, Aorta, Mathematics, Cardiac cycle, medicine.diagnostic_test, Biomechanics, Magnetic resonance imaging, Commissure, Magnetic Resonance Imaging, Finite element method, Biomechanical Phenomena, Aortic Valve, cardiovascular system, Aortic pressure, Female, Stress, Mechanical, Biomedical engineering
Abstract

An understanding of aortic root biomechanics is pivotal for the optimisation of surgical procedures aimed at restoring normal root function in pathological subjects. For this purpose, computational models can provide important information, as long as they realistically capture the main anatomical and functional features of the aortic root. Here we present a novel and realistic finite element (FE) model of the physiological aortic root, which simulates its function during the entire cardiac cycle. Its geometry is based on magnetic resonance imaging (MRI) data obtained from 10 healthy subjects and accounts for the geometrical differences between the leaflet-sinus units. Morphological realism is combined with the modelling of the leaflets' non-linear and anisotropic mechanical response, in conjunction with dynamic boundary conditions. The results show that anatomical differences between leaflet-sinus units cause differences in stress and strain patterns. These are notably higher for the leaflets and smaller for the sinuses. For the maximum transvalvular pressure value, maximum principal stresses on the leaflets are equal to 759, 613 and 603 kPa on the non-coronary, right and left leaflet, respectively. For the maximum aortic pressure, average maximum principal stresses values are equal to 118, 112 and 111 kPa on the right, non-coronary and left sinus, respectively. Although liable of further improvements, the model seems to reliably reproduce the behaviour of the real aortic root: the model's leaflet stretches, leaflet coaptation lengths and commissure motions, as well as the timings of aortic leaflet closures and openings, all matched with the experimental findings reported in the literature.

Published
2009

7. Aortic Root Finite Element Modeling From MR Imaging

Author

Alberto Redaelli, Luca Del Viscovo, Carlo Angelo Conti, Maurizio Cotrufo, Emiliano Votta, Alessandro Della Corte, Conti, Ca, Votta, E, DELLA CORTE, Alessandro, DEL VISCOVO, Luca, Cotrufo, M, and Redaelli, A.

Subjects
Aorta, business.industry, Sinotubular Junction, Annulus (oil well), food and beverages, Anatomy, Finite element method, medicine.anatomical_structure, Ventricle, medicine.artery, Ascending aorta, cardiovascular system, medicine, Outflow, Cardiac skeleton, business
Abstract

The aortic root is the portion of the outflow tract of the left ventricle that includes the aortic leaflets, the aortic annulus, the sinuses of Valsalva and the sinotubular junction. The impairment of one or more of these structures can lead not only to dysfunctions of the root, but also to alterations of the adjacent anatomical sites, such as the ascending aorta. The raise and the progress of the alterations are often related to more concomitant factors, whose separated effect can be difficult to assess. At this purpose computational finite element (FE) models can be a useful tool, given their capability the recreate different scenarios by varying one or more parameters of the model in a controlled fashion.Copyright © 2008 by ASME

Published
2008

8. Restricted cusp motion in right-left type of bicuspid aortic valves: A new risk marker for aortopathy

Author

Della Corte, A., Bancone, C., Del Viscovo, L., Conti, CARLO ANGELO, Votta, Emiliano, Scognamiglio, G., Covino, F. E., Redaelli, ALBERTO CESARE LUIGI, Cotrufo, M., DELLA CORTE, Alessandro, Bancone, C, Conti, Ca, Votta, E, Redaelli, A, DEL VISCOVO, Luca, and Cotrufo, M.

Subjects
Adult, Male, Pulmonary and Respiratory Medicine, Aortic valve, medicine.medical_specialty, Gauche effect, Aortic Diseases, Young Adult, Bicuspid aortic valve, Coronary Circulation, Internal medicine, medicine, Humans, cardiovascular diseases, Systole, medicine.diagnostic_test, business.industry, Sinotubular Junction, Magnetic resonance imaging, Anatomy, Flow pattern, medicine.disease, Magnetic Resonance Imaging, medicine.anatomical_structure, Aortic Valve, Multivariate Analysis, Circulatory system, Hydrodynamics, cardiovascular system, Cardiology, Female, Surgery, Cardiology and Cardiovascular Medicine, business
Abstract

OBJECTIVE: Bicuspid aortic valve disease is heterogeneous with respect to valve morphology and aortopathy risk. This study searched for early imaging predictors of aortopathy in patients with a bicuspid aortic valve with right-left coronary cusp fusion, the most common morphotype. METHODS: Time-resolved magnetic resonance imaging was performed in 36 subjects with nonstenotic, nonregurgitant bicuspid aortic valves and nondilated aortas and in 10 healthy controls with tricuspid aortic valves. Sinus dimensions (diameter, width, and height), ascending tract diameters, and wall strain were measured for each sinus/leaflet unit and corresponding ascending tract area to account for asymmetries. A novel parameter, "cusp opening angle," measured the degree of valve leaflet alignment to outflow axis in systole, quantifying cusp motility. Phase-contrast magnetic resonance imaging and computational fluid dynamic models assessed flow patterns. Aortic growth rate was estimated over a follow-up period ranging from 9 to 84 months. RESULTS: The expected restriction of bicuspid aortic valve opening (conjoint cusp opening angle, 62° ± 5° vs 76° ± 3° for nonfused leaflet and 75° ± 3° for tricuspid aortic valve cusps; P < .001) was confirmed, and the introduced parameter reproducibly quantified this phenomenon. Phase-contrast magnetic resonance imaging demonstrated systolic flow deflection toward the right, affecting the right anterolateral ascending wall. Computational models confirmed that restricted cusp motion alone is sufficient to cause the observed flow pattern. Ascending tract wall strain was not circumferentially homogeneous in bicuspid aortic valves. In multivariable analyses, the conjoint cusp opening angle independently predicted ascending aorta diameters and growth rate (P < .001). CONCLUSIONS: In the bicuspid aortic valve commonly defined as normofunctional by echocardiographic criteria, restricted systolic conjoint cusp motion causes flow deflection. The novel measurement introduced can quantify restricted cusp opening, possibly assuming prognostic importance.

Published
2012
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9. Biomechanical implications of the congenital bicuspid aortic valve: A finite element study of aortic root function from in vivo data

Author

Ciro Bancone, Alberto Redaelli, Luca Del Viscovo, Emiliano Votta, Carlo Angelo Conti, Luca Salvatore De Santo, Alessandro Della Corte, Conti, Ca, DELLA CORTE, Alessandro, Votta, E, DEL VISCOVO, Luca, Bancone, C, DE SANTO, Luca Salvatore, and Redaelli, A.

Subjects
Adult, Heart Defects, Congenital, Male, Aortic valve, Pulmonary and Respiratory Medicine, medicine.medical_specialty, congenital, hereditary, and neonatal diseases and abnormalities, Finite Element Analysis, Diastole, Young Adult, Imaging, Three-Dimensional, Bicuspid aortic valve, Bicuspid valve, medicine.artery, Internal medicine, medicine, Humans, Computer Simulation, cardiovascular diseases, Systole, Aorta, business.industry, Models, Cardiovascular, Anatomy, Middle Aged, medicine.disease, Magnetic Resonance Imaging, Biomechanical Phenomena, Kinetics, Stenosis, medicine.anatomical_structure, Aortic Valve, Circulatory system, Cardiology, cardiovascular system, Female, Surgery, Stress, Mechanical, business, Cardiology and Cardiovascular Medicine
Abstract

Objective Congenital bicuspid aortic valves frequently cause aortic stenosis or regurgitation. Improved understanding of valve and root biomechanics is needed to achieve advancements in surgical repair techniques. By using imaging-derived data, finite element models were developed to quantify aortic valve and root biomechanical alterations associated with bicuspid geometry. Methods A dynamic 3-dimensional finite element model of the aortic root with a bicuspid aortic valve (type 1 right/left) was developed. The model's geometry was based on measurements from 2-dimensional magnetic resonance images acquired in 8 normotensive and otherwise healthy subjects with echocardiographically normal function of their bicuspid aortic valves. Numeric results were compared with those obtained from our previous model representing the normal root with a tricuspid aortic valve. The effects of raphe thickening on valve kinematics and stresses were also evaluated. Results During systole, the bicuspid valve opened asymmetrically compared with the normal valve, resulting in an elliptic shape of its orifice. During diastole, the conjoint cusp occluded a larger proportion of the valve orifice and leaflet bending was altered, although competence was preserved. The bicuspid model presented higher stresses compared with the tricuspid model, particularly in the central basal region of the conjoint cusp (+800%). The presence of a raphe partially reduced stress in this region but increased stress in the other cusp. Conclusions Aortic valve function is altered in clinically normally functioning bicuspid aortic valves. Bicuspid geometry per se entails abnormal leaflet stress. The stress location suggests that leaflet stress may play a role in tissue remodeling at the raphe region and in early leaflet degeneration.

Published
2010
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10. Impact of modeling fluid-structure interaction in the computational analysis of aortic root biomechanics.

Author

Sturla F, Votta E, Stevanella M, Conti CA, and Redaelli A

Subjects
Biomechanical Phenomena, Finite Element Analysis, Stress, Mechanical, Aorta physiology, Computer Simulation, Hydrodynamics, Mechanical Phenomena
Abstract

Numerical modeling can provide detailed and quantitative information on aortic root (AR) biomechanics, improving the understanding of AR complex pathophysiology and supporting the development of more effective clinical treatments. From this standpoint, fluid-structure interaction (FSI) models are currently the most exhaustive and potentially realistic computational tools. However, AR FSI modeling is extremely challenging and computationally expensive, due to the explicit simulation of coupled AR fluid dynamics and structural response, while accounting for complex morphological and mechanical features. We developed a novel FSI model of the physiological AR simulating its function throughout the entire cardiac cycle. The model includes an asymmetric MRI-based geometry, the description of aortic valve (AV) non-linear and anisotropic mechanical properties, and time-dependent blood pressures. By comparison to an equivalent finite element structural model, we quantified the balance between the extra information and the extra computational cost associated with the FSI approach. Tissue strains and stresses computed through the two approaches did not differ significantly. The FSI approach better captured the fast AV opening and closure, and its interplay with blood fluid dynamics within the Valsalva sinuses. It also reproduced the main features of in vivo AR fluid dynamics. However, the FSI simulation was ten times more computationally demanding than its structural counterpart. Hence, the FSI approach may be worth the extra computational cost when the tackled scenarios are strongly dependent on AV transient dynamics, Valsalva sinuses fluid dynamics in relation to coronary perfusion (e.g. sparing techniques), or AR fluid dynamic alterations (e.g. bicuspid AV)., (Copyright © 2013 IPEM. Published by Elsevier Ltd. All rights reserved.)

Published
2013
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11. Aortic valve repair via neo-chordae technique: mechanistic insight through numerical modelling.

Author

Votta E, Paroni L, Conti CA, Pelosi A, Mangini A, D'Alesio P, Vismara R, Antona C, and Redaelli A

Subjects
Aortic Valve pathology, Aortic Valve physiopathology, Aortic Valve Prolapse pathology, Aortic Valve Prolapse physiopathology, Finite Element Analysis, Humans, Aortic Valve surgery, Aortic Valve Prolapse surgery, Cardiac Valve Annuloplasty methods, Models, Cardiovascular
Abstract

Recently, the neo-chordae technique (NCT) was proposed to stabilize the surgical correction of isolated aortic valve (AV) prolapse. Neo-chordae are inserted into the corrected leaflet to drive its closure by minimal tensions and prevent relapses. In a previous in vitro study we analysed the NCT effects on healthy aortic roots (ARs). Here we extend that analysis via finite element models (FEMs). After successfully replicating the experimental conditions for validation purposes, we modified our AR FEM, obtaining a continent AV with minor isolated prolapse, thus representing a realistic clinical scenario. We then simulated the NCT, and systematically assessed the acute effects of changing neo-chordae length, opening angle, asymmetry and insertion on the aorta. In the baseline configuration the NCT restored physiological AV dynamics and coaptation, without inducing abnormal leaflet stresses. This outcome was notably sensitive only to neo-chordae length, suggesting that the NCT is a potentially easy-to-standardize technique. However, this parameter is crucial: major shortenings (6 mm) prevent coaptation and increase leaflet stresses by 359 kPa, beyond the yield limit. Minor shortenings (2-4 mm) only induce a negligible stress increase and mild leaflet tethering, which however may hamper the long-term surgical outcome.

Published
2012
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12. Cameron ulcers: you will find only what you seek.

Author

Chun CL, Conti CA, and Triadafilopoulos G

Subjects
Aged, Diagnosis, Differential, Esophageal Diseases complications, Esophageal Diseases therapy, Esophagoscopy, Female, Follow-Up Studies, Hernia, Hiatal complications, Hernia, Hiatal surgery, Humans, Ulcer complications, Ulcer therapy, Esophageal Diseases diagnosis, Fundoplication methods, Hernia, Hiatal diagnosis, Laparoscopy, Proton Pump Inhibitors therapeutic use, Ulcer diagnosis
Published
2011
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13. Left ventricular modelling: a quantitative functional assessment tool based on cardiac magnetic resonance imaging.

Author

Conti CA, Votta E, Corsi C, De Marchi D, Tarroni G, Stevanella M, Lombardi M, Parodi O, Caiani EG, and Redaelli A

Abstract

We present the development and testing of a semi-automated tool to support the diagnosis of left ventricle (LV) dysfunctions from cardiac magnetic resonance (CMR). CMR short-axis images of the LVs were obtained in 15 patients and processed to detect endocardial and epicardial contours and compute volume, mass and regional wall motion (WM). Results were compared with those obtained from manual tracing by an expert cardiologist. Nearest neighbour tracking and finite-element theory were merged to calculate local myocardial strains and torsion. The method was tested on a virtual phantom, on a healthy LV and on two ischaemic LVs with different severity of the pathology. Automated analysis of CMR data was feasible in 13/15 patients: computed LV volumes and wall mass correlated well with manually extracted data. The detection of regional WM abnormalities showed good sensitivity (77.8%), specificity (85.1%) and accuracy (82%). On the virtual phantom, computed local strains differed by less than 14 per cent from the results of commercial finite-element solver. Strain calculation on the healthy LV showed uniform and synchronized circumferential strains, with peak shortening of about 20 per cent at end systole, progressively higher systolic wall thickening going from base to apex, and a 10° torsion. In the two pathological LVs, synchronicity and homogeneity were partially lost, anomalies being more evident for the more severely injured LV. Moreover, LV torsion was dramatically reduced. Preliminary testing confirmed the validity of our approach, which allowed for the fast analysis of LV function, even though future improvements are possible.

Published
2011
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14. Trends in biomedical engineering: focus on Patient Specific Modeling and Life Support Systems.

Author

Dubini G, Ambrosi D, Bagnoli P, Boschetti F, Caiani EG, Chiastra C, Conti CA, Corsini C, Costantino ML, D'Angelo C, Formaggia L, Fumero R, Gastaldi D, Migliavacca F, Morlacchi S, Nobile F, Pennati G, Petrini L, Quarteroni A, Redaelli A, Stevanella M, Veneziani A, Vergara C, Votta E, Wu W, and Zunino P

Subjects
Adolescent, Cardiac Surgical Procedures instrumentation, Cardiac Surgical Procedures methods, Cardiac Surgical Procedures trends, Child, Child, Preschool, Humans, Imaging, Three-Dimensional methods, Imaging, Three-Dimensional trends, Infant, Software trends, Biomedical Engineering methods, Biomedical Engineering trends, Life Support Systems instrumentation, Models, Cardiovascular
Abstract

Over the last twenty years major advancements have taken place in the design of medical devices and personalized therapies. They have paralleled the impressive evolution of three-dimensional, non invasive, medical imaging techniques and have been continuously fuelled by increasing computing power and the emergence of novel and sophisticated software tools. This paper aims to showcase a number of major contributions to the advancements of modeling of surgical and interventional procedures and to the design of life support systems. The selected examples will span from pediatric cardiac surgery procedures to valve and ventricle repair techniques, from stent design and endovascular procedures to life support systems and innovative ventilation techniques.

Published
2011
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15. Biomechanical implications of the congenital bicuspid aortic valve: a finite element study of aortic root function from in vivo data.

Author

Conti CA, Della Corte A, Votta E, Del Viscovo L, Bancone C, De Santo LS, and Redaelli A

Subjects
Adult, Aortic Valve abnormalities, Aortic Valve pathology, Biomechanical Phenomena, Female, Heart Defects, Congenital pathology, Humans, Imaging, Three-Dimensional, Kinetics, Magnetic Resonance Imaging, Male, Middle Aged, Stress, Mechanical, Young Adult, Aortic Valve physiopathology, Computer Simulation, Finite Element Analysis, Heart Defects, Congenital physiopathology, Models, Cardiovascular
Abstract

Objective: Congenital bicuspid aortic valves frequently cause aortic stenosis or regurgitation. Improved understanding of valve and root biomechanics is needed to achieve advancements in surgical repair techniques. By using imaging-derived data, finite element models were developed to quantify aortic valve and root biomechanical alterations associated with bicuspid geometry., Methods: A dynamic 3-dimensional finite element model of the aortic root with a bicuspid aortic valve (type 1 right/left) was developed. The model's geometry was based on measurements from 2-dimensional magnetic resonance images acquired in 8 normotensive and otherwise healthy subjects with echocardiographically normal function of their bicuspid aortic valves. Numeric results were compared with those obtained from our previous model representing the normal root with a tricuspid aortic valve. The effects of raphe thickening on valve kinematics and stresses were also evaluated., Results: During systole, the bicuspid valve opened asymmetrically compared with the normal valve, resulting in an elliptic shape of its orifice. During diastole, the conjoint cusp occluded a larger proportion of the valve orifice and leaflet bending was altered, although competence was preserved. The bicuspid model presented higher stresses compared with the tricuspid model, particularly in the central basal region of the conjoint cusp (+800%). The presence of a raphe partially reduced stress in this region but increased stress in the other cusp., Conclusions: Aortic valve function is altered in clinically normally functioning bicuspid aortic valves. Bicuspid geometry per se entails abnormal leaflet stress. The stress location suggests that leaflet stress may play a role in tissue remodeling at the raphe region and in early leaflet degeneration., (Copyright © 2010 The American Association for Thoracic Surgery. Published by Mosby, Inc. All rights reserved.)

Published
2010
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16. Dynamic finite element analysis of the aortic root from MRI-derived parameters.

Author

Conti CA, Votta E, Della Corte A, Del Viscovo L, Bancone C, Cotrufo M, and Redaelli A

Subjects
Aortic Valve anatomy & histology, Aortic Valve physiology, Biomechanical Phenomena, Female, Humans, Male, Models, Anatomic, Models, Biological, Stress, Mechanical, Aorta anatomy & histology, Aorta physiology, Finite Element Analysis, Magnetic Resonance Imaging
Abstract

An understanding of aortic root biomechanics is pivotal for the optimisation of surgical procedures aimed at restoring normal root function in pathological subjects. For this purpose, computational models can provide important information, as long as they realistically capture the main anatomical and functional features of the aortic root. Here we present a novel and realistic finite element (FE) model of the physiological aortic root, which simulates its function during the entire cardiac cycle. Its geometry is based on magnetic resonance imaging (MRI) data obtained from 10 healthy subjects and accounts for the geometrical differences between the leaflet-sinus units. Morphological realism is combined with the modelling of the leaflets' non-linear and anisotropic mechanical response, in conjunction with dynamic boundary conditions. The results show that anatomical differences between leaflet-sinus units cause differences in stress and strain patterns. These are notably higher for the leaflets and smaller for the sinuses. For the maximum transvalvular pressure value, maximum principal stresses on the leaflets are equal to 759, 613 and 603 kPa on the non-coronary, right and left leaflet, respectively. For the maximum aortic pressure, average maximum principal stresses values are equal to 118, 112 and 111 kPa on the right, non-coronary and left sinus, respectively. Although liable of further improvements, the model seems to reliably reproduce the behaviour of the real aortic root: the model's leaflet stretches, leaflet coaptation lengths and commissure motions, as well as the timings of aortic leaflet closures and openings, all matched with the experimental findings reported in the literature., ((c) 2009 IPEM. Published by Elsevier Ltd. All rights reserved.)

Published
2010
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19. [Clinical and immunologic study of 2 cases of juvenile myasthenia gravis].

Author

Conti CA, Falcini F, Martinucci M, Monterisi N, and Calandi C

Subjects
Child, Electromyography, Female, Humans, Lymphocyte Activation, Male, Radiography, Autoantibodies analysis, Immunity, Cellular, Immunoglobulins analysis, Myasthenia Gravis diagnosis, Myasthenia Gravis diagnostic imaging, Myasthenia Gravis immunology
Published
1977

20. [Pustulous psoriasis of Zumbusch. Report of a case].

Author

Calandi C, Conti CA, and Battini M

Subjects
Child, Preschool, Cortisone therapeutic use, Humans, Male, Psoriasis diagnosis, Psoriasis drug therapy, Syndrome, Vitamin B Complex therapeutic use, Psoriasis classification
Published
1977

23. [Epidemiologic and clinico-statistical data on infantile tuberculosis in the province of Florence with special reference to morbidity related to the 10-year period of 1962-1971].

Author

Calandi C, Gatta AM, Conti CA, Pecchioli A, and Pieroni P

Subjects
Adolescent, Adult, Child, Child, Preschool, Disease Outbreaks, Europe, Humans, Infant, Infant, Newborn, Italy, Retrospective Studies, Tuberculosis, Pulmonary epidemiology, Tuberculosis, Pulmonary mortality, Tuberculosis epidemiology
Published
1973

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