Pasquale Innelli

The impact of aging on left ventricular longitudinal function in healthy subjects: a pulsed tissue Doppler study

AIMS To evaluate the influence of age on pulsed Tissue Doppler-derived measurements of right ventricular (RV) tricuspid annulus in a population of healthy subjects and to propose reference values according to age decades. METHODS AND RESULTS Two hundred and ninety-eight healthy subjects (M/F = 186/112) underwent Doppler echocardiography and pulsed Tissue Doppler of tricuspid annulus in apical four-chamber view. Tricuspid annular plane systolic excursion (TAPSE), Doppler indexes of RV outflow tract and of tricuspid inflow, right atrial dimension and inferior vena cava size, and collapsibility were measured. Pulsed Tissue Doppler lateral corner of the tricuspid annulus was also recorded and annular systolic (Sa), early diastolic (Ea), and atrial (Aa) peak velocities and Ea/Aa ratio determined. The ratio of tricuspid E peak velocity and Ea (E/Ea ratio) was calculated as an index of right atrial pressure. The population was divided in seven age decades: 10-19, 20-29, 30-39, 40-49, 50-59, 60-69, and >70 years. TAPSE, Sa, Ea, and Ea/Aa ratio were progressively reduced and both Aa and E/Ea ratio increased with the increasing age groups (all P < 0.0001). E/Ea ratio was 4.1 +/- 0.9 in the age decade 11-20 years and 5.4 +/- 1.5 in subjects >70 years (P < 0.0001). By multi-linear regression analyses, after adjusting for heart rate and body mass index, age was the main independent predictor of average Sa, Ea, and Aa velocities and of E/Ea ratio. CONCLUSIONS Ageing shows an independent impact on pulsed Tissue Doppler-derived indexes of RV myocardial function in healthy subjects. Our data provide reference values of pulsed Tissue Doppler of the right ventricle for age decades.

Nebivolol induces parallel improvement of left ventricular filling pressure and coronary flow reserve in uncomplicated arterial hypertension.

Purpose Our aim was to analyze the effects of 3-month antihypertensive therapy by nebivolol, a β-blocking agent with nitric oxide-mediated vasodilatory properties, on coronary flow reserve (CFR) and left ventricular filling pressure (LVFP) in uncomplicated arterial hypertension. Methods Twenty newly diagnosed, never treated, uncomplicated hypertensive patients (14 male and six female patients, mean age = 49 years), I–II WHO grade, underwent single-blind nebivolol treatment. At baseline and at 3-month follow-up, patients underwent Doppler echocardiography including pulsed Tissue Doppler of septal mitral annulus: the ratio between transmitral E velocity and myocardial early diastolic velocity (E/Em ratio) was calculated as an index of LVFP degree. Transthoracic Doppler-derived CFR (high-dose dipyridamole coronary diastolic peak flow velocity to resting coronary peak flow velocity ratio) of distal left anterior descending artery was also determined. Results After 3-month nebivolol therapy, rate–pressure product decreased (P < 0.0001). No significant change of left ventricular mass index, relative wall thickness and midwall shortening was detected. Left ventricular end-diastolic diameter and stroke volume were both marginally increased. Nebivolol increased Em (P < 0.0001), reduced E/Em ratio (from 9.0 ± 1.6 to 8.2 ± 1.1, P < 0.0001) and enhanced CFR (from 2.07 ± 0.2 to 2.20 ± 0.2, P = 0.003), because of increased hyperemic coronary flow velocity (P < 0.001). CFR increase remained significant (P < 0.001) after normalizing resting and dipyridamole coronary velocities for the respective rate–pressure product. The increase of normalized CFR induced by nebivolol was related with E/Em ratio decrease (r = −0.65, P < 0.002). Conclusion Nebivolol improves LVFP as well as CFR in uncomplicated hypertension. The association between changes of CFR and those of LVFP indicates a possible common denominator between improvement of coronary microvascular function and myocardial stimulation of nitric oxide release induced by the drug.

Hypertension and acute myocardial infarction: an overview.

History of hypertension is a frequent finding in patients with acute myocardial infarction (AMI) and its recurring association with female sex, diabetes, older age, less frequent smoking and more frequent vascular comorbidities composes a risk profile quite distinctive from the normotensive ischemic counterpart.Antecedent hypertension associates with higher rates of death and morbid events both during the early and long-term course of AMI, particularly if complicated by left ventricular dysfunction and/or congestive heart failure. Renin-angiotensin-aldosterone system blockade, through either angiotensin-converting enzyme inhibition, angiotensin II receptor blockade or aldosterone antagonism, exerts particular benefits in that high-risk hypertensive subgroup.In contrast to the negative implications carried by antecedent hypertension, higher systolic pressure at the onset of chest pain associates with lower mortality within 1 year from coronary occlusion, whereas increased blood pressure recorded after hemodynamic stabilization from the acute ischemic event bears inconsistent relationships with recurring coronary events in the long-term follow-up.Whether antihypertensive treatment in post-AMI hypertensive patients prevents ischemic relapses is uncertain. As a matter of fact, excessive diastolic pressure drops may jeopardize coronary perfusion and predispose to new acute coronary events, although the precise cause-effect mechanisms underlying this phenomenon need further evaluation.

Effects of different dietary protein intakes on body composition and vascular reactivity.

Objective:To assess the effects of a diet rich in protein of animal origin in comparison to one with a protein intake of about 15% of the total daily calories on body composition and arterial function.Design:Randomized prospective study with parallel groups. Body weight (BW), blood pressure (BP), main parameters of carbohydrate and lipid metabolism, body mass composition by bioelectrical impedance analysis, forearm blood flow at rest and in the postischaemic phase by strain gauge plethysmography and flow-mediated dilation of the brachial artery by echography were measured at baseline and after 6 months of the dietary intervention.Subjects:In total, 15 clinically healthy male volunteers, regularly performing a mixed training three times weekly for 90 min.Intervention:The participants were randomly prescribed a diet with high (1.9 g/kg BW) or normal (1.3 g/kg BW) protein content.Statistical analysis:Differences between means were evaluated by the t-tests for paired or unpaired data and by one way analysis of variance. The strength of correlation between variables was investigated by bivariate Pearson correlation.Results:Serum cholesterol significantly decreased with both diets in comparison to baseline values, whereas BW was slightly but significantly reduced only by the high-protein (HP) diet. No change was detected in BP and the other metabolic parameters. Body mass composition was not significantly modified by either diet. On the other hand, postischaemic flow-mediated dilation of the brachial artery was enhanced by the sole normal protein (NP) diet, whereas no change in the forearm blood flow, both at rest and in the postischaemic phase, was detected.Conclusions:These preliminary results indicate that HP diet was found to be not useful in increasing the muscle mass in comparison to a NP intake. In contrast to this, the latter diet seems to enhance the endothelial function of the arterial vessels with a more pronounced dilatation of the lumen in response to the increase in blood flow.

Parallel improvement of left ventricular geometry and filling pressure after transcatheter aortic valve implantation in high risk aortic stenosis: comparison with major prosthetic surgery by standard echo Doppler evaluation

PurposeThe effect of Transcatheter Aortic Valve Implantation (TAVI) on left ventricular (LV) geometry and function was compared to traditional aortic replacement (AVR) by major surgery.Methods45 patients with aortic stenosis (AS) undergoing TAVI and 33 AVR were assessed by standard echo Doppler the day before and 2 months after the implantation. 2D echocardiograms were performed to measure left ventricular (LV) mass index (LVMi), relative wall thickness (RWT), ejection fraction (EF) and the ratio between transmitral E velocity and early diastolic velocity of mitral annulus (E/e’ ratio). Valvular-arterial impedance (Zva) was also calculated.ResultsAt baseline, the 2 groups were comparable for blood pressure, heart rate, body mass index mean transvalvular gradient and aortic valve area. TAVI patients were older (p<0.0001) and had greater LVMi (p<0.005) than AVR group. After 2 months, both the procedures induced a significant reduction of transvalvular gradient and Zva but the decrease of LVMi and RWT was significant greater after TAVI (both p<0.0001). E/e’ ratio and EF were significantly improved after both the procedure but E/e’ reduction was greater after TAVI (p<0.0001). TAVI exhibited greater percent reduction in mean transvalvular gradient (p<0.05), Zva (p<0.02), LVMi (p<0.0001), RWT (p<0.0001) and E/e’ ratio (p<0.0001) than AVR patients. Reduction of E/e’ ratio was positively related with reduction of RWT (r = 0.46, p<0.002) only in TAVI group, even after adjusting for age and percent reduction of Zva (r =0.43, p<0.005).ConclusionsTAVI induces a greater improvement of estimated LV filling pressure in comparison with major prosthetic surgery, due to more pronounced recovery of LV geometry, independent on age and changes of hemodynamic load.

Circulating IGF-I levels are associated with increased biventricular contractility in top-level rowers

Background  The intensive physical activity is often associated with cardiac changes.

Detection of increased left ventricular filling pressure by pulsed tissue Doppler in cardiac amyloidosis.

Objective The aim of this study was to evaluate the incremental diagnostic role of tissue Doppler in primary cardiac amyloidosis (CA). Methods Eleven patients with CA at diagnosis and 11 healthy controls, matched for sex and age, underwent standard Doppler echocardiography and pulsed tissue Doppler of the left ventricular (LV) lateral annulus, in the apical four-chamber view. The ratio of early transmitral flow velocity to early diastolic mitral annular velocity (E/Em ratio) was derived as an index of LV filling pressure. Results The two groups were comparable for body mass index, blood pressure, heart rate and standard Doppler diastolic measurements. Patients with CA had a significantly higher sum of wall thickness (SWT) and LV mass, a lower Em peak velocity (P < 0.002) and a higher E/Em ratio (P < 0.001) than controls. By dividing CA patients according to the transmitral E/A ratio, patients with an E/A ratio < 1 (abnormal relaxation) (n = 5) and patients with an E/A ratio > 1 (likely pseudonormal/restrictive pattern) (n = 6) did not show any difference in the E/Em ratio (14.5 ± 7.1 vs. 15.1 ± 6.4, P = NS). In the overall population, the E/Em ratio was related to SWT (r = 0.84, P < 0.0001) and LV mass index (r = 0.72, P < 0.0001). After adjusting for age and heart rate by separate multivariate models, SWT (β = 0.78, P < 0.0001; cumulative r2 = 0.63, SE = 3.38, P < 0.0001) and LV mass index (β = 0.71, P < 0.0001; cumulative r2 = 0.53, SE = 3.80, P < 0.002) were both independently associated with the E/Em ratio. Conclusions Pulsed tissue Doppler is able to detect early myocardial diastolic impairment in CA. The E/Em ratio is very useful in diagnosing increased LV filling pressure, regardless of the transmitral pattern, and may, therefore, be helpful in the clinical management of these patients.

Currently available technology for echocardiographic assessment of left ventricular function

New ultrasound technology is mainly represented by tissue Doppler (TD), which allows the quantitative analysis of myocardial function and includes two modalies: pulsed-wave TD and color TD. Strain rate imaging (SRI) is an implementation of color TD. Pulsed-wave TD, performed and analyzed in real time, instantaneously measures myocardial velocities. Color TD, performed offline on digitally stored images, allows the quantification of mean myocardial velocities. The advantage of color TD compared with pulsed TD is the ability to simultaneously analyze multiple myocardial segments. The limit of both these methodologies consists of the myocardial velocity dependence by the base–apex myocardial gradient. SRI measures the rate and percentage of myocardial wall deformation. From digitally recorded color TD cine loops containing velocity data from the entire myocardium, SRI can be derived from regional Doppler velocity gradients. Strain rate is relatively load dependent, and, therefore, can be considered a strong index of myocardial contractility. Due to these favorable characteristics, SRI may potentially overcome the limitations of color TD, discriminating between active and merely passive wall motion. A novel technique is the implemention of 2D SRI, which is not angle dependent, and therefore potentially more feasible and reliable.

Transthoracic coronary flow reserve and dobutamine derived myocardial function: a 6-month evaluation after successful coronary angioplasty

After percutaneous transluminal coronary angioplasty (PTCA), stress-echocardiography and gated single photon emission computerized tomography (g-SPECT) are usually performed but both tools have technical limitations. The present study evaluated results of PTCA of left anterior descending artery (LAD) six months after PTCA, by combining transthoracic Doppler coronary flow reserve (CFR) and color Tissue Doppler (C-TD) dobutamine stress.Six months after PTCA of LAD, 24 men, free of angiographic evidence of restenosis, underwent standard Doppler-echocardiography, transthoracic CFR of distal LAD (hyperemic to basal diastolic coronary flow ratio) and C-TD at rest and during dobutamine stress to quantify myocardial systolic (Sm) and diastolic (Em and Am, Em/Am ratio) peak velocities in middle posterior septum. Patients with myocardial infarction, coronary stenosis of non-LAD territory and heart failure were excluded. According to dipyridamole g-SPECT, 13 patients had normal perfusion and 11 with perfusion defects. The 2 groups were comparable for age, wall motion score index (WMSI) and C-TD at rest. However, patients with perfusion defects had lower CFR (2.11 ± 0.4 versus 2.87 ± 0.6, p < 0.002) and septal Sm at high-dose dobutamine (p < 0.01), with higher WMSI (p < 0.05) and stress-echo positivity of LAD territory in 5/11 patients. In the overall population, CFR was related negatively to high-dobutamine WMSI (r = -0.50, p < 0.01) and positively to high-dobutamine Sm of middle septum (r = 0.55, p < 0.005).In conclusion, even in absence of epicardial coronary restenosis, stress perfusion imaging reflects a physiologic impairment in coronary microcirculation function whose magnitude is associated with the degree of regional functional impairment detectable by C-TD.

The left ventricle as a mechanical engine: from Leonardo da Vinci to the echocardiographic assessment of peak power output-to-left ventricular mass.

The interpretation of the heart as a mechanical engine dates back to the teachings of Leonardo da Vinci, who was the first to apply the laws of mechanics to the function of the heart. Similar to any mechanical engine, whose performance is proportional to the power generated with respect to weight, the left ventricle can be viewed as a power generator whose performance can be related to left ventricular mass. Stress echocardiography may provide valuable information on the relationship between cardiac performance and recruited left ventricular mass that may be used in distinguishing between adaptive and maladaptive left ventricular remodeling. Peak power output-to-mass, obtained during exercise or pharmacological stress echocardiography, is a measure that reflects the number of watts that are developed by 100 g of left ventricular mass under maximal stimulation. Power output-to-mass may be calculated as left ventricular power output per 100 g of left ventricular mass: 100 × left ventricular power output divided by left ventricular mass (W/100 g). A simplified formula to calculate power output-to-mass is as follows: 0.222 × cardiac output (l/min) × mean blood pressure (mmHg)/left ventricular mass (g). When the integrity of myocardial structure is compromised, a mismatch becomes apparent between maximal cardiac power output and left ventricular mass; when this occurs, a reduction of the peak power output-to-mass index is observed.