Determination of left ventricular systolic wall thickness by digital subtraction angiography

The accuracy of digital subtraction angiography (DSA) for determination of left ventricular (LV) systolic wall thickness and muscle mass was evaluated in 20 patients (mean age 50 +/- 11 years). Conventional LV angiograms were digitized and subtracted using a combined subtraction mode ('mask mode' and 'time interval difference' subtraction). Wall thickness and muscle mass were determined at end-diastole, after the first- and second-third of systole and at end-systole. M-mode echocardiography (Echo), which was obtained from beam selection of the two-dimensional echocardiogram and conventional angiography (LVA), served as reference techniques. Angiographic LV wall thickness and muscle mass were determined according to the technique of Rackley in both, right (RAO) and left (LAO) anterior oblique projections, whereas echocardiographic wall thickness was measured just below the mitral valve orthogonal to the posterior wall (= LAO equivalent). Percent wall thickening was calculated in all patients. LV end-diastolic wall thickness and muscle mass correlated well between DSA and LVA (LV end-diastolic wall thickness in LAO projection r = 0.72, biplane LV end-diastolic muscle mass r = 0.83), LV end-systolic wall thickness (1.44 vs 1.33 cm, P less than 0.05) and percent wall thickening (52 vs 42%, P less than 0.05) compared favourably between echocardiography and DSA but was significantly larger when echocardiographically measured than with DSA (LAO projection). DSA and echocardiography showed a good correlation in regard to LV end-diastolic and end-systolic wall thickness (correlation coefficient r = 0.89, standard error of estimate SEE = 0.15 cm or 13% of the mean value).(ABSTRACT TRUNCATED AT 250 WORDS)     

Impact of body mass index on markers of left ventricular thickness and mass calculation: results of a pilot analysis

Specific correlations between body mass index (BMI) and left ventricular (LV) thickness have been conflicting. Accordingly, we investigated if a particular correlation exists between BMI and echocardiographic markers of ventricular function. METHODS: A total of 122 patients, referred for routine transthoracic echocardiography, were included in this prospective pilot study using a 3:1 randomization approach. Patient demographics were obtained using a questionnaire. RESULTS: Group I consisted of 80 obese (BMI was >30 kg/m2), Group II of 16 overweight (BMI between 26 and 29 kg/m2), and Group III of 26 normal BMI (BMI < 25 kg/m2) individuals. No difference was found in left ventricular wall thickness, LV end-systolic cavity dimension, fractional shortening (FS), or pulmonary artery systolic pressure (PASP) among the groups. However, mean LV end-diastolic cavity dimension was greater in Group I (5.0 +/- 0.9 cm) than Group II (4.6 +/- 0.8 cm) or Group III (4.4 +/- 0.9 cm; P < 0.006). LV mass indexed to height(2.7) was also significantly larger in Group I (61 +/- 21) when compared to Group III (48 +/- 19; P < 0.001). Finally, left atrial diameter (4.3 +/- 0.7 cm) was also larger (3.8 +/- 0.6 and 3.6 +/- 0.7, respectively; P < 0.00001). DISCUSSION: We found no correlation between BMI and LV wall thickness, FS, or PASP despite the high prevalence of diabetes and hypertension in obese individuals. However, obese individuals had an increased LV end-diastolic cavity dimension, LV mass/height(2.7), and left atrial diameter. These findings could represent early markers in the sequence of cardiac events occurring with obesity. A larger prospective study is needed to further define the sequence of cardiac abnormalities occurring with increasing BMI.     

Left ventricular wall thickness measurements by magnetic resonance: a validation study

Summary Left ventricular (LV) wall thickness was determined by magnetic resonance (MR) in 15 patients (7 controls and 8 patients with coronary artery disease). End-diastolic (ed) and end-systolic (es) wall thickness were measured in a short axis view perpendicular to the LV long axis. Wall thickness measurements were compared to data obtained by digital subtraction angiography (DSA) and M-mode echocardiography (Echo).End-diastolic and end-systolic wall thickness were significantly overestimated by MR (34% and 37%, respectively) when compared to DSA. In contrast, LV end-diastolic and end-systolic chamber diameter were significantly underestimated by MR (25% and 30%, respectively) when compared to DSA. However, fractioned shortening was similar (all NS) for MR (48±22%), DSA (54±15%) and Echo (44±10%), respectively.The mean difference (= accuracy) and the standard deviation of difference (= precision) for LV wall thickness was 0.4±0.2 cm between MR and DSA, 0.4±0.3 cm between MR and ECHO and 0.03±0.1 cm between DSA and ECHO. The correlation of wall thickness between MR and DSA (correlation coefficient r=0.74, p<0.001) and between MR and Echo (r=0.70, p<0.001) was good although the standard error of estimate (SEE) was 17% for MR vs. DSA and 21% for MR vs. Echo. The corresponding SEE for chamber diameter was 16% between MR and DSA and 19% between MR and Echo, respectively. Intraobserver variability for wall thickness determination by MR was excellent (correlation coefficient r=0.99, p<0.001) SEE of 4%. Interobserver variability was also good (correlation coefficient r=0.90, p<0.001) with a SEE of 12%.It is concluded that LV wall thickness and chamber diameter (short axis plane) can be determined by MR with good precision but only satisfactory accuracy. LV wall thickness is significantly overestimated probably due to signals from static blood which might be indistinguishable from the subendocardium.     

Determination of left ventricular mass by real-time three-dimensional echocardiography: in vitro validation

Twenty-one explanted fixed hearts (14 dogs and 7 pigs) were examined to validate newly developed real-time three-dimensional (RT3D) echocardiography for measurement of left ventricular (LV) mass in vitro and to compare its accuracy and variability with those of conventional echocardiographic measurements. There was an excellent correlation and high degree of agreement for the determination of LV mass between RT3D echocardiography and true mass measurement (r = 0.98; standard error of the estimate [SEE] = 7.3 g; absolute difference [AD] = 2.8 g; y = 1.00 x -4.0, interobserver variability; 5.0%). The conventional echocardiographic methods yielded weaker correlations, larger standard errors, and interobserver variability (area-length method: r = 0.90; SEE = 13.3 g; AD = 13.2 g; 13.3 % / truncated ellipsoid method: r = 0.91; SEE = 14.7 g; AD = 10.5 g; 7. 9% / M-mode: r = 0.91; SEE = 16.2 g; AD = 9.4 g; 15.3%). Determination of LV mass by RT3D echocardiography has a high degree of accuracy and is superior to conventional one- and two-dimensional echocardiographic methods.     

Comparison of intravenous digital subtraction cineangiocardiography with conventional contrast ventriculography for the determination of the left ventricular volume at rest and during exercise

Left ventricular volumes were determined by means of digitalsubtraction cineangiocardiography (DSA) which was performedin the right anterior oblique projection after contrast agentinjection into the superior vena cava. Monoplane end-diastolic(EDV), end-systolic volumes (ESV), and ejection fraction (EF)were calculated using the ‘area–length’ methodand were compared with the same parameters obtained by conventionalleft ventricular cineangiocardiography. A first group of 20patients was studied at rest and a second group of 10 patientsduring bicycle exercise at a work load of 64 watts during 2min, by DSA and conventional cineangiocardiography. Three differentsubtraction modes were evaluated: (1) mask mode subtraction(MMS), (2) time interval difference (TID) method and (3) a combinationof MMS and TID called MMS+TID method. With the MMS method goodcorrelations were obtained for EDV, ESV and EF at rest (r>0.91)and during exercise (r>0.91). The TID method showed onlymoderate correlations for patients at rest (r>0.86) and duringexercise (r>0.79). Similar results as with MMS were achievedby the combined method (MMS+TID) at rest (r>0.91) and duringexercise (r>0.91). Interobserver variability indicated ahigh reproducibility for all methods except for TID during exercise.Itis concluded that DSA is an accurate technique for left ventricularvolume determination not only at rest but also during exercise.The best results are obtained with MMS or MMS+TID methods, whileleft ventricular contour detection is easier and more convenientwith MMS+TID.     

Repeat determination of left ventricular wall thickness from mass and volume during one cardiac cycle for the calculation of left ventricular wall stress parameters

Left ventricular end-diastolic wall stress, end-systolic wall stress, and systolic stress-time integral are important parameters to characterize left ventricular load and function. To obtain these parameters, left ventricular pressure, volume, and wall thickness data must be determined at short time intervals throughout one cardiac cycle. However, the measurement of wall thickness at short intervals (i.e., 20 ms) throughout a cardiac cycle is tedious. Furthermore, measurements of wall thickness are less accurate at end-systole compared with end-diastole. For these reasons we developed a computer program for calculating wall thickness at short intervals (20 ms) throughout the cardiac cycle from one single determination of left ventricular wall mass and repetitive measurements of left ventricular (LV) volume.     

Rapid quantification of left ventricular function and mass using transoesophageal three-dimensional echocardiography: validation of a method that uses long-axis cutplanes.

AIMS: Despite its proven superiority compared to conventional echocardiographic techniques, three-dimensional (3D) echocardiography has not gained widespread acceptance in clinical medicine for the quantification of left ventricular volumes, function and mass. This is mainly due to the large, time-consuming process of data analysis. We sought to validate a new method that enables the accurate quantification of the left ventricle in a clinically acceptable short period of time. METHODS AND RESULTS: Left ventricular volumes, ejection fraction and mass were determined in 44 patients using 3D echocardiography. The 3D echocardiographic data sets were analysed: (i) using the conventional 'summation of slices' algorithm (slice thickness 5 and 10mm), which is based on the analysis of the 3D reconstructed left ventricle in short-axis cross-sections; and (ii) using the new method which is based on the analysis of the 3D reconstructed left ventricle in long-axis images. In each patient measurements were repeated using 3, 6, 7, 8, 9, 12 and 15 long-axis images. For all volumetric measurements there was a continuous reduction of measurement variability using increasing numbers of long-axis images. The use of more than nine long-axis images for volumes, and eight long-axis images for ejection fraction and mass, did not result in a further reduction of variability. The analysis time for volumes and masses averaged less than 5 min for the long-axis method using nine component images, compared to 20-43 min for the short-axis method. CONCLUSION: 3D echocardiography combined with a novel method based on the analysis of long-axis cross-section allows accurate quantification of left ventricular volumes, function and mass in a clinically acceptable short period of time. In the future, the combination of a real-time 3D echocardiographic acquisition technique with this analysis method should have important implications for the introduction of 3D echocardiography in clinical practice.     

Association between fasting plasma glucose and left ventricular mass and left ventricular hypertrophy over 4 years in a healthy population aged 60 and older

OBJECTIVES: To test the association between fasting glucose level and left ventricular mass (LVM) and left ventricular hypertrophy (LVH) in people aged 60 and older. DESIGN: Population-based prospective study with 4-year follow-up. SETTING: Department of Internal Medicine and Family Medicine, Kaohsiung Medical University (KMU), Chung-Ho Memorial Hospital, and Graduate Institute of Medicine and Public Health, KMU. PARTICIPANTS: Of 1,500 people screened, 105 without symptoms or signs of diabetes mellitus, hypertension, or cardiovascular disease were recruited from senior activity centers in Kaohsiung city. MEASUREMENTS: All received two-dimensional echocardiography and fasting glucose examination at baseline and at 2- and 4-year follow-up. LVH was defined as a LVM index (LVMI) greater than 122.4 g/m(2) or 51 g/m(2.7). RESULTS: Age ranged from 60 to 81 (mean 71.7+/-3.9). Baseline glucose ranged from 83 to 118 mg/dL (mean 99.7+/-7.9 mg/dL). LVMI was significantly higher at the 4-year follow-up (97.5+/-24.9 vs 104.5+/-27.5 g/m(2) and 44.2+/-12.1 vs 47.2+/-13.4 g/m(2.7), both P<.01), as was the occurrence of LVH (16% vs 32% and 25% vs 39%, both P<.01). Baseline glucose correlates with 4-year change in LVMI (both P<.02). In the fourth year, baseline glucose was a significant predictor of LVMI (both P<.01) and LVH (P=.03 in g/m(2) definition) using logistic regression analysis. CONCLUSION: Because fasting glucose is an independent predictor for greater LVM and for development of LVH, it should be considered in assessment of cardiac disease and LVM in healthy older people without diabetes mellitus.     

Comparison of electrocardiographic versus echocardiographic detection of left ventricular mass changes over time and evaluation of new onset left ventricular hypertrophy

We assessed the value of 3 electrocardiographic (EKG) voltage criteria in detecting variations of left ventricular mass (LVM) over time, taking echocardiographic (ECHO) LVM as reference, in the Pressioni Arteriose Monitorate E Loro Associazioni study. In 927 subjects (age 47 ± 13 years on entry, 49.9% men) an ECHO evaluation of LVM and EKG suitable for measurement of EKG-LVH criteria (Sokolow-Lyon voltage, Cornell voltage and R-wave voltage in aVL) were available at baseline and at a 2^nd evaluation performed 10 years later. Δ (delta) LVM, Δ LVMI, and Δ EKG parameters values were calculated from 2^nd evaluation to baseline. The sensitivity of the EKG criteria in the diagnosis of LVH, poor at baseline, becomes even worse after 10 years, reaching very low values. Only the sensitivity of R-wave amplitude exhibited slight increase over time but with unsatisfactory absolute values. Despite the prevalence of ECHO-LVH at the 2^nd evaluation was threefold increased compared to baseline (29.3% and 33.7% for LVM indexed to BSA and height^2.7, respectively), the prevalence of EKG-LVH was unchanged when evaluated by Sokolow-Lyon criteria, significantly reduced when assessed by Cornell voltage index, while significantly increased using R-wave voltage in aVL criteria. Despite an ECHO-LVM increase over the time, mean EKG changes were of opposite sign, except for R-wave amplitude in aVL. Our study highlights the discrepancy between ECHO and EKG in monitoring LVM changes over the time, especially for Sokolow-Lyon and Cornell voltage. Thus, EKG is an unsuitable method for the longitudinal evaluation of LVM variations.     

Quantitation of left ventricular wall motion in normal subjects: Comparison of various methods

Computer-assisted analysis of percent change in the square root of area in each of 12 consecutive 30-degree, pie-shaped ventricular segments was obtained in 48 normal subjects who underwent cardiac catheterization and left ventriculography. The information obtained permitted establishment of objective confidence limits for normal left ventricular regional wall motion. As an index of dynamic changes in segmental wall motion, the percent change in the square root of area method compared favorably with existing radius, area, hemichord, and chord methods. It also possessed a variety of theoretical advantages over these techniques: 1) large numbers of points were analyzed, 2) wall motion disorders in all areas except base were evaluated, 3) taking the square root of area's percent change provided both area information with least splay and an average measure of radius.     

A semiautomated technique for the rapid evaluation of left ventricular regional wall motion

A semiautomated system for the rapid evaluation of left ventricular regional wall motion is described. The system includes direct projection of the cineangiogram film on an X-Y digitizer which is interfaced with a PDP-9 computer. The ventricular model used to evaluate regional wall motion and the methods of data analysis are described. Validation of the accuracy of the technique and specific clinical applications are presented. It is concluded that this technique provides a rapid means of evaluating left ventricular regional wall motion and that the accuracy of the technique is acceptable for clinical application.     

Echocardiographic left ventricular mass in African-Americans: the Jackson cohort of the Atherosclerosis Risk in Communities Study

Characterization of target organ damage from hypertension is of particular interest in African-Americans, and evidence from electrocardiographic studies suggests that left ventricular hypertrophy is a frequent clinical finding of considerable prognostic importance. Echocardiographic studies may permit more precise characterization of the pathologic impact of hypertension on cardiac structure and function. The objective of this study is to characterize left ventricular (LV) structure including measures of wall thickness, septal thickness, internal dimension, and mass in a middle-aged sample of African-Americans using echocardiography. This study is a cohort (cross-sectional) study in which 2445 middle-aged African-American study participants from a population-based sample initially enrolled by the Atherosclerosis Risk in Communities, Jackson, Mississippi Examination Center in 1987-1989 underwent an M-mode echocardiograpic examination at their third or fourth clinic visit in 1993-1996. Measures of LV mass, even where indexed by size were conspicuously greater in men compared to women, and men exhibited a demonstrably steeper gradient of LV mass across the rather restricted age range of the study. However, when gender specific thresholds for LV hypertrophy were utilized, African-American men appear to have lower prevalence of LV hypertrophy than women. The lowest prevalence of LV hypertrophy was observed in African-American men who did not have hypertension (28.4%). The findings confirm previous suggestions from electrocardiographic investigations that cardiac hypertrophy is common, if not epidemic in middle-aged African-American men and women, whether or not they have hypertension.     

Variability in frame by frame analysis of left ventricular wall motion from contrast angiograms

Background. Measurement of the timing of left ventricular (LV) wall motion, of asynchrony, and of diastolic function from contrast angiograms requires delineation of the endocardial border frame by frame through the cardiac cycle. This study was performed to determine the magnitude of intraobserver and interobserver variability in manual border tracing, and to measure the impact of this variability on the derived functional parameters. Methods. The contrast ventriculograms of 25 patients with coronary artery disease (CAD) or with normal coronary arteries were analyzed frame by frame, by two observers or twice by the same observer. Motion was measured using the centerline method at each twelfth of systole and of diastole. Variability was calculated as the absolute difference between repeated measurements of: wall motion, asynchrony, and the time at which each region of the LV reached 10%, 50%, and 100% of peak contraction, and 50% of filling. Results. Intraobserver and interobserver variability in wall motion were similar, and varied with time in the cycle, and with location on the LV contour. Variability was highest at end systole, when it averaged 8% of the normal mean for wall motion. Variability in timing was highest at peak contraction; however, the variability in measuring asynchrony averaged only 18 msec. Conclusion. Analysis of the magnitude and synchrony of regional LV wall motion through the cardiac cycle from contrast ventriculograms can be performed with reproducibility comparable to that at end systole.     

A quantitative relationship of electrocardiographic criteria of left ventricular hypertrophy with echocardiographic left ventricular mass: a multivariate approach

The purpose of this study was to evaluate the sensitivity of various electrocardiographic (EKG) criteria of left ventricular hypertrophy (LVH) in relation to echocardiographic left ventricular mass (LVME) and to assess the relative strength of various EKG variables used in the diagnosis of LVH by multivariate analysis. An attempt was also made to determine if a new combination of precordial and T-wave voltage could improve the sensitivity of EKG. In 89 patients, M-mode echocardiograms and standard EKGs were studied. Correlation of Romhilt-Estes point-score system with LVME was r = 0.621, sensitivity and specificity was 57 and 81%, respectively. Other voltage criteria had lower sensitivity. Various combinations of precordial and T-wave voltage were not superior. The quantitative relationship of individual EKG variable, QRS duration, S V1-3, R V4-6, strain T wave, left atrial abnormality, intrinsicoid deflection and axis, with LVM was, r = 0.661, 0.595, 0.429, 0.42, 0.347, and 0.225, respectively. By multivariate analysis, QRS duration, S V1-3, T-wave and R V4-6 voltage had F-value (relative strength) of 27.95, 27.15, 22.02, and 4.03, respectively, other variables were statistically insignificant. In conclusion, the most important EKG variables predictive of LVH are QRS duration, S V1-3, strain T-wave and lateral voltage in decreasing value. Rescoring these variables in accordance to their correlation to LVM may improve EKG sensitivity for the diagnosis of LVH.     

In vitro validation of right ventricular volume and mass measurement by real-time three-dimensional echocardiography

OBJECTIVE: To evaluate initially the feasibility and accuracy of real-time three-dimensional echocardiography (RT-3DE) for quantifying right ventricular (RV) volume and wall mass in an in vitro experimental study. METHODS: In ten excised porcine hearts, measurements of RV volume and free wall mass with RT-3DE were outlined and calculated by 2-, 4-, 8- and 16-plane methods with Tom Tec 4D Cardio-View RT 1.0. The results were compared with those of 2D length method and 2D biplane Simpson method. The values of RV silicone latex cast and free wall mass measured by water displacement were served as reference values. RESULTS: RV shapes of excised porcine hearts with RT-3DE were similar to those of the actual anatomic RVs and RV silicone latex casts. From the findings of analysis of variance and Student-Newman-Keuls test, there was no significant difference between measurements of RV volume with RT-3DE 16-plane (mean 64.05 ml), 8-plane (61.83 ml) and the reference values of RV silicone latex casts (62.94 ml). No significant difference was found between measurements of RV free wall mass with 16-plane (72.81 g), 8-plane (71.05 g) and the reference values of RV free wall masses (76.21 g). However, there was significant difference between measurements of RV volume and free wall mass with 2-plane, 2D biplane Simpson method and the reference values. Furthermore, the measurements of RV volume and free wall mass with 16-plane and 8-plane were better correlated with the reference values than those with 4-plane and 2D length method. CONCLUSIONS: RT-3DE will be a valuable technique for quantifying irregular crescentic RV volume and wall mass.     

Radionuclide assessment of regional differences in left ventricular wall motion and myocardial perfusion in idiopathic dilated cardiomyopathy

Regional variations in left ventricular contractility and myocardialperfusion are frequent in idiopathic dilated cardiomyopathyand might result from an increase in left ventricular wall stressresponsible for regional wall motion abnormalities. The aimof the study was to perform radionuclide studies in patientswith idiopathic dilated cardiomyopathy to assess regional leftventricular wall motion and myocardial perfusion abnormalitiesin this myocardial disease. We studied 29 men referred withidiopathic dilated cardiomyopathy and normal coronary angiograms.Rest radionuclide left ventriculography and exercise thallium-201tomography were performed in all patients. The thallium-201tomograms were divided into 20 segments for each patient. Meanleft ventricular ejection fraction was 27±11%; 17 patientshad diffuse hypokinesia (mean left ventricular ejection fraction:24±9%) and 12 patients had predominant regional hypokinesia(mean left ventricular ejection fraction: 32±12%). Ofall 580 tomographic segments, 186 had a reduction of thallium-201uptake at exercise. Among them, reversibility was found in 53%.On the whole, 68% (158/232) of anterior, inferior and apicalsegments had a perfusion abnormality, compared with 8% (28/348)of septal and lateral segments (P<0.0001). Left ventricular wall motion and myocardial perfusion abnormalitiesare heterogeneous and not evenly distributed in dilated cardiomyopathy.The alterations are predominant on the myocardial regions delineatingthe antero-posterior axis of the left ventricle. These findingssuggest the possible role of increased left ventricular wallstress on this axis.     

Three-dimensional echocardiography for quantitative left ventricular wall motion analysis: a method for reconstruction of endocardial surface and evaluation of regional dysfunction

A method for quantitative LV wall motion analysis based on 3-D reconstruction of the LV endocardial surface is presented. The reconstruction is based on a minimum of three transthoracic apical 2-D cineloops of the LV, digitally transferred from the ultrasound scanner to a computer. Images are obtained by rotating the transducer around the LV long axis. Endocardial borders are traced with an automatic edge detection algorithm with manual correction. These borders are used with a specially designed computer algorithm for reconstruction of LV cavity 3-D shape, and LV volumes, ejection fraction, and endocardial surface area can be determined. The end-diastolic and end-systolic endocardial surfaces are compared for analysis of regional wall motion. A threshold value is selected to discriminate between normal and abnormal wall motion. Regional wall motion abnormalities are displayed in a bull's eye plot, and the corresponding endocardial surface area is expressed in percent of the total endocardial area. Phase analysis is performed from reconstruction of the endocardial surface throughout the cardiac cycle, and displays regions with abnormal wall motion as being out of phase with LV volume variation. Thus, LV 3-D reconstruction performed by this method can be used for quantitative analysis of wall motion in several clinical situations, and due to the simplicity of processing the data, can be useful outside the research laboratory.     

Maximum stress-volume index ratio of the left ventricle in hypertrophic cardiomyopathy

To evaluate the left ventricular contractile state in patients with nonobstructive hyper-trophic cardiomyopathy (HCM), we analyzed the maximum stress-volume index ratio (MSVR) using catheter-tip cineangiography in 11 patients with HCM and 16 normal subjects. The value of the MSVR in normal subjects was 6.48±1.25 kdyn/cm⁵/m² (mean±SD) and we defined the range of the mean±2 SD as the normal MSVR range. Six patients with HCM placed inside the normal MSVR range (IN), but the other 5 patients placed outside and to the right of the normal range (RIGHT). This suggests that the contractile states of the patients of the RIGHT group were depressed. Compared with IN, the end-diastolic and end-systolic volume Indices of RIGHT were larger (EDVI; 69.3±6.9 vs. 96.1 ±11.1 ml/m², p<0.01, ESVI; 18.2 ± 3.2 vs. 29.1 ±8.3 ml/m², p<0.05), but the ejection fraction did not differ (IN 73.5±5.7 vs. RIGHT 69.6±8.3%, NS). End-diastolic pressure of IN and RIGHT was higher than that of normal subjects (IN 16.5±4.5, RIGHT 16.7±4.6 vs. 8.3±2.5 mm Hg, both p<0.05), but there was no difference between the two groups in HCM. End-systolic pressure did not differ among the three groups. End-diastolic, mean systolic, and end-systolic stresses of IN were similar to those of RIGHT Left ventricular wall thickness (RIGHT 1.66±0.22 vs. IN 1.36±0.14 cm, p<0.05) and mass index (RIGHT 272.2±25.5 vs. IN 176.1 ±19.0 g/m², p<0.01) of RIGHT were larger than those of IN. Furthermore, there were linear inverse relations between the MSVR and the end-diastolic volume index (r= ?0.84) and between the MSVR and mass index (r=-0.91) in the 11 patients with HCM. These results suggest that there were two groups among the HCM patients, that is, those with normal (or preserved) and those with depressed contractile states, and patients with large end-diastolic volume indices and increased mass indices tended to have depressed contractile states. © 1992 Wiley-Liss, Inc.     

Left ventricular function and wall thickness in long-term insulin-dependent diabetes mellitus: an echocardiographic study

Left ventricular function and wall thickness were evaluated in 111 type I diabetic subjects (mean age 25.5 +/- 9 years, mean duration of diabetes 13.4 +/- 6.2 years), using 2-D-derived M-mode echocardiography. Patients were carefully selected for the absence of major coronary risk factors or manifest cardiac disorders, and compared with 91 age- and sex-matched control subjects. Fractional shortening and the maximal velocity of cirumferential fibre shortening did not differ significantly between the two groups. Furthermore, no differences were found in the diastolic functional parameter of velocity of circumferential fibre extension. Posterior wall thickness was significantly increased in the diabetic patients compared to the controls (9.5 +/- 1.8 mm vs. 8.4 +/- 1.3 mm. P less than 0.01). As the thickness of the interventricular septum was also moderately increased (9.2 +/- 2.2 mm vs. 8.9 +/- 1.7 mm, NS), these findings provide evidence for an early structural change of the myocardium in young diabetic patients without clinically relevant functional consequences.     

Diverging effects of postextrasystolic potentiation on left ventricular segmental wall motion in coronary heart disease

The effects of postextrasystolic potentiation (PESP) on regional left ventricular (LV) wall motion were evaluated in 40 coronary artery disease (CAD) patients. Of the 40 CAD patients, 20 had a prior myocardial infarction and 20 had a history of angina pectoris. PESP was obtained by applying programmed atrial stimulation during LV angiography, in a way that basal cycle length, premature beat, and postextrasystolic pause were almost identical in all patients. Segmental wall motion was evaluated by calculating regional ejection fraction (EF) of 5 different areas with a computerized method before and after the premature beat. The results were compared to those obtained in a group of 8 normal subjects. LV areas were classified as normokinetic, mildly hypokinetic, severely hypokinetic, and hyperkinetic, on the basis of their regional EF in respect to normals, and classified as "responder" (R) and "nonresponder" on the basis of the magnitude of the increase of regional EF with PESP. Of a total of 200 areas 129 were normokinetic (68% R), 45 were mildly hypokinetic (78% R), 17 severely hypokinetic (76% R), and 9 were hyperkinetic (78% R). Infarcted patients had a higher percentage of hypokinetic areas in basal conditions (p less than 0.001), however, the percentage of hypokinetic areas that responded to PESP was not significantly different from noninfarcted patients. In CAD patients, as a whole, a significant direct correlation was found between basal regional EF and regional EF after PESP (r = 0.88, p less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)