Generalización diagnóstica fractal de la morfología cardiaca ventricular izquierda: anormalidades moderadas y severas a partir del ventriculograma / Fractal Diagnostic Generalization of Left Ventricular Cardiac Morphology: Moderate and Severe Anormalities from Ventriculography

Introducción: La irregularidad cardiaca es adecuadamente descrita mediante geometría fractal, la cual fue base para el desarrollo de un diagnóstico del ventriculograma izquierdo. Métodos: Se simularon la totalidad de permutaciones posibles de grados de similitud de las dimensiones fractales del ventrículo en sístole, diástole y totalidad, definidas entre los valores mínimos y máximos de los grados de similitud para anormalidad moderada y severa previamente establecidos. Resultados: Se estableció el número total de prototipos ventriculares entre anormalidad moderada y severa. El número total de prototipos de estructura ventricular posibles fue de 1614: 794 ventrículos con anonnalidad moderada y 820 con anonnalidad severa. Medidas previas de ventrículos con diagnóstico de anonnalidad moderada y severa se encontraron incluidas dentro de la generalización. Conclusiones: Se desarrolló una metodología geométrica objetiva y de ayuda diagnóstica a nivel clínico, que determinó todas las posibles estructuras ventriculares izquierdas con anonnalidad moderada y severa, independientemente de clasificaciones clínicas.

Introduction: The cardiac irregularity is adequately described by means of fractal geometry, which was the basis for the development of a diagnosis of left ventriculography. Methods: All possible pennutations of similarity degrees from fractal dimensions were done for the ventricle in systole. diastole and the totality. Pennutations were defined between the previously established mínimum and máximum valúes of similarity degrees for modérate and severe anonnality. Results: It was established the total number of possible ventricular prototypes between modérate and severe anonnality. The total number of possible ventricular structure prototypes is 1614: 794 of ventricles with modérate anonnality and 820 of ventricles with severe anonnality. Practical measures made previously were found within the generalization. Conclusions: It was developed an objective geometric methodology. which is of diagnostic aid in the clinical practice. It detennined all possible left ventricular structures with modérate and severe anonnality independent of clinical classifications.

Analysis on causes of failed procedure of transcatheter closure for ventricular septal defects in children / 中华实用儿科临床杂志

Objective To analyze the causes of failed transcatheter closure for ventricular septal defects (VSD)in children. Methods One thousand two hundred and eighty children aged 13 to 141 months who underwent transcatheter closure from June 2009 to September 2013 in Guangdong General Hospital were selected. There were 43 failures(3. 36% ). The clinical data including transthoracic echocardiograph( TTE),radiography,interventional ap-proach and surgical findings were analyzed. Results Forty - three patients included 25 male and 18 female. The pa-tients' ages ranged from 13 to 141(43. 0 ± 31. 9)months and their weight ranged from 10 to 35(16. 3 ± 5. 59)kg. The causes of failure including doubly committed subarterial VSD misdiagnosed as perimembranous VSD(PMVSD)or intracristal VSD were in 6 patients. The size of occluder was too small in 13 cases,and there were statistical differences between three measurements of size of VSD(F = 19. 134,P = 0. 001). The size of VSD measured by left ventricular an-giography was significantly smaller than that measured by TTE,and there was statistical difference[(4. 78 ± 1. 11) mm vs(6. 48 ± 1. 43)mm,t = 4. 50,P = 0. 001]. The dimension of VSD measured by left ventricular angiography was significantly smaller than that measured by surgical findings,and there was statistical difference[(4. 78 ± 1. 11) mm vs(7. 02 ± 1. 08)mm,t = 5. 92,P = 0. 001]. But,the size of VSD measured by TTE had no significant difference compared with that measured by surgical findings(t = 1. 42,P = 0. 168). Aortic regurgitation occurred in 14 cases;atrioventricular block or left bundle branch block in 3 patients;tricuspid stenosis in 2 cases and residual shunt in 5 pa-tients. Conclusions Doubly committed subarterial VSD may be misdiagnosed as PMVSD or intracristal VSD. In the ca-ses of VSD concomitant with aortic valve prolapse,size of the occluders should be referred to VSD dimensions measured by TTE. In the cases of VSD adjacent to aortic valve,suitable occluders should be selected and operation technique should be improved to avoid aortic regurgitation.

Generalización geométrica fractal de ventriculografías izquierdas normales y con disfunción leve / Fractal geometric generalization of normal left ventriculographies and with mild dysfunction

Introducción: la estructura cardiaca es por naturaleza, irregular, su adecuada caracterización se hace mediante la aplicación de la geometría fractal. Desde esta geometría se desarrolló un diagnóstico objetivo del ventriculograma izquierdo. Objetivo: desarrollar una generalización teórica de la dinámica ventricular izquierda en los estados de normalidad y enfermedad leve, a partir del diagnóstico matemático objetivo y reproducible desarrollado previamente. Se calcularon todas las posibles estructuras ventriculares durante la dinámica cardiaca a partir de los grados de similitud para casos que evolucionan entre normales y leves en busca de los prototipos matemáticos ventriculares de normalidad y enfermedad leve. Resultados: se estableció que la totalidad de posibles prototipos de la estructura ventricular para normalidad y enfermedad leve son 1345; 551 corresponden a normalidad y 794 a enfermedad leve. Al comparar los grados de similitud de ventrículos previamente medidos, con los prototipos obtenidos, se encontró que sus medidas estaban incluidas en la generalización. Conclusión: se desarrolló una nueva metodología de aplicación clínica reproducible y de ayuda diagnóstica objetiva, independiente de clasificaciones clínicas, con base en la generalización geométrica de la dinámica ventricular. (Acta Med Colomb 2014; 39: 131-136).

Introduction: Cardiac structure is irregular by nature; its proper characterization is done by application of fractal geometry. From this geometry an objective diagnosis of left ventriculogram was developed. Objective: to develop a theoretical generalization of left ventricular dynamics in states of normality and mild disease, from the objective and reproducible previously developed mathematical diagnosis. All possible ventricular structures were calculated during cardiac dynamics from the degrees of similarity for cases that evolve between normal and mild in search of mathematical prototypes of normality and mild disease. Results: It was established that all of the possible prototypes for normal ventricular structure and mild disease are 1345; 551 correspond to normality and 794 to mild disease. Comparing the degree of similarity of previously measured ventricles, with the obtained prototypes, it was found that its measures were included in the generalization. Conclusion: a new methodology for clinical application reproducible and of objective diagnostic aid independently of clinical classifications, based on the geometric generalization of ventricular dynamics, was developed. (Acta Med Colomb 2014; 39: 131-136).

Diagnóstico fractal del ventriculograma cardiaco izquierdo: geometría fractal del ventriculograma durante la dinámica cardiaca / Fractal diagnosis of left heart ventriculograms: fractal geometry of ventriculogram during cardiac dynamics

Antecedentes y objetivos: la geometría fractal permite describir y caracterizar los objetos irregulares, lo que resulta adecuado para medir estructuras del cuerpo humano. El propósito de este trabajo es caracterizar el ventrículo izquierdo durante la dinámica cardiaca con dimensiones fractales para desarrollar un diagnóstico matemático objetivo y reproducible de la ventriculografía izquierda. Método: este es un estudio de concordancia diagnóstica donde se calcularon las dimensiones fractales del ventrículo en sístole, en diástole y en un total de 36 ventriculogramas evaluados como normales, y anormales en leves, moderados y severos de acuerdo con la fracción de eyección según el diagnóstico clínico convencional; posteriormente se determinaron los grados de similitud de las dimensiones fractales entre los tres objetos componentes. Resultados: los grados de similitud estuvieron entre 1 y 9.000, y al organizar estos valores en conjuntos, se encontró una progresión a partir de los normales hasta los anormales severos. Se establecieron los grados de similitud característicos que permiten diferenciar normalidad de enfermedad y evolución entre éstas, evidenciando que la clasificación de la clínica convencional presenta dificultades al evaluar de forma precisa y objetiva la evolución de un ventriculograma hacia la normalidad o la enfermedad. Conclusiones: se desarrolló una nueva metodología diagnóstica objetiva y reproducible de aplicación clínica basada en evaluaciones geométricas independiente de la clasificación clínica.

Background and Objectives: fractal geometry allows to describe and characterize irregular objects, which is appropriate for measuring human body structures. The purpose of this study is to characterize the left ventricle during cardiac dynamics by means of fractal dimensions to develop an objective, mathematical and reproducible diagnosis of left ventriculography. Method: this is a diagnostic concordance study in which we calculated the fractal dimensions of the ventricle in systole, in diastole and in a total of 36 ventriculograms evaluated as normal, mild, moderate and severe according to the ejection fraction in accordance with the conventional clinical diagnosis ; subsequently, the degree of similarity of the fractal dimensions between the three components were determined. Results: the degrees of similarity were between 1 and 9,000, and when arranging these values into sets, there was a progression from normal to severe. We established the characteristic degrees of similarity that allow to distinguish normality from disease and the evolution between them, showing that the conventional clinical classification presents difficulties to assess accurately and objectively the evolution of a ventriculogram towards normality or disease. Conclusions: we developed a new objective and reproducible diagnostic methodology of clinical application based on geometric assessments that is independent from the clinical classification.

Left ventricular ejection fraction measurement using cardiovascular magnetic resonance imaging in patients with post-myocardial infarction: assessment of reproducibility by a cardiovascular radiologist and a trained technologist.

Background: Cardiovascular magnetic resonance imaging (CMR) has recently been accepted as a preferential method for evaluation left ventricular ejection fraction (LVEF). The LVEF analysis by CMR is usually performed by trained technologists in many institutions of Thailand. Objective: Assess the reproducibility of LVEF measured by a cardiovascular radiologist and a trained technologist using CMR in patients with post-myocardial infarction (MI). Methods: Twenty-one MI patients (18 men and 3 women) were recruited, where nine patients underwent CMR and left ventriculography to follow-up LVEF two times in six months. Both CMR and left ventriculography were examined within two weeks. LVEF from CMR were measured by a cardiovascular radiologist and a trained technologist and the correlation between the left ventriculography and CMR was determined. Results: In 30 CMR studies, interobserver reliability (intraclass correlation coefficient ICC=0.94) and intraobserver reliability (ICC=0.96) was excellent. LVEF measured by left ventriculography was higher compared with that by CMR, and their correlation was moderate (ICC=0.56). Conclusion: The LVEF measurement by a cardiovascular radiologist and a trained technologist using CMR was very reproducible, but the correlation between CMR and left ventriculography was moderate.

The evaluation of left ventricular function by pressure-volume loop in patients with different extents of coronary stenosis / 中国介入心脏病学杂志

Objective To evaluate the left ventricular function in patients with different extents of coronary stenosis by the left ventricular pressure volume loop Methods In 65 patients who were undergoing coronary angiography and left ventriculography examinations, materials of clinical and cardiac catheter examinations were collected In right anterior oblique 30 degrees the left ventriculography was progressed The pressure curves of the left ventricle and the aorta were recorded continuously and volumes of the left ventricles were measured with the dot tracing method Pressure volume loop was set up and ventricular energy indexes embodied by the pressure volume loop were measured and calculated Results In normal group, pressure volume loop was located in the left and lower portion of the coordinate system Along with the levels of the coronary stenosis becoming more severe, pressure volume loops moved to the right and upper portion of the coordinate system Little changes occurred in ejection fraction except that there was a decreasing in patients with lesions of three branches; Stroke work showed no obvious changes; Filling energy became larger; Total energy increased obviously in both groups with lesions of double branches and three branches; End systolic energy increased gradually while energy efficiency decreased gradually Conclusion The ventricular pressure volume loop can be obtained in routine ventriculography which can reflect many indexes of ventricular function quantitatively The ventricular energy indexes change correspondingly with coronary artery lesions and may be useful to assess ventricular function in patients with different levels of coronary stenosis

Reconstruction of the Transmitral Flow Rate Curve with M-Mode,2-Dimensional and Doppler Echocardiography -Validation Study-

To validate ventricular diastolic phase parameters of reconstructed transmitral flow rate curve by M-mode, 2-dimensional and pulsed Doppler Echocardiography, these parameters were compared with same parameters by left ventriculography. The study population was 22 patients who received both coronary arteriography and echocardiographic examination. Transmitral flow rate curve and left ventricular filling volume curve were reconstructed from transmitral flow velocity curve by pulsed Doppler, mitral annulus diameter by two diameter by two dimensional and diastolic motion of both mitral leafltes by M-mode echocardiography. From left ventriculography, left ventricular filling volume curve and transmitral flow rate curve were made using area-length method by Sandler and Dodge. From trasmitral flow fraction, 1/2 diastolic time filling fraction, normalized peak filling volume, 1/3 diastolic time filling fraction, 1/2 diastolic time fraction, normalized peak early filling rate and ratio of early to late peak filling rate were measured. Correlation between same parameters derived from echocardiography and left ventriculography were observed. 1) Total diastolic filling volume:correlation coefficient r=0.47, P<0.05. 2) 1/3 diastolic time filling fraction:correlation coefficient r=0.90, P<0.001. 3) 1/2 diastolic time filling fraction:correlation coefficient r=0.80, P<0.001. 4) Normalized peak early filling rate:correlation coefficient r=0.57, P<0.01. 5) Ratio of early to late peak filling rate:correlation coefficient r=0.85, P<0.001. Therefore, left ventricular diastolic phase parameters of reconstructed transmitral flow rate curve using, M-mode, 2-dimensional and pulsed Doppler echocardiography seems to be useful for the noninvasive evaluation of the left ventricular diastolic function.

Real-time three dimensional echocardiography in evaluation of left ventricular volume and ejection fraction in patients with aneurysm combined with myocardial infarction / 第二军医大学学报

Objective:To assess the feasibility and accuracy of real-time three dimensional echocardiography(RT-3DE) in quantitative evaluation of left ventricular(LV) volume and ejection fraction(EF) in patients with ventricular aneurysm and myocardial infarction.Methods: Twenty-three patients with left ventricular aneurysm combined with myocardial infarction were examined by RT-3DE,two dimensional echocardiography Simpson's method,and M-mode Teichholz method separately.The following parameters: left ventricular end diastolic volume(LVEDV),end systolic volume(ESV),stroke volume(SV) and EF were obtained by each method and the results were compared with those obtained by left ventriculography(LVG).Results: The values of LVEDV,LVESV,SV,and EF determined by RT-3DE showed good correlations with those determined by LVG(r=0.92,0.90,0.88,and 0.91,respectively;P(0.05).) The values of LVEDV,LVESV,SV,and EF determined by Simpson's method also showed good correlations with those determined by LVG(r=0.85,0.87,0.86,0.91,respectively;P