Association of inappropriate left ventricular mass with systolic and diastolic dysfunction: the HyperGEN study

BACKGROUND: Left ventricular mass (LVM) exceeding values appropriate for individual workload is associated with concentric LV geometry and systolic dysfunction at both the midwall and chamber levels, even independently of clearcut LV hypertrophy, and is a marker of adverse prognosis. No information is available on whether inappropriate LVM is associated with alterations of LV diastolic properties in unselected population-based studies. METHODS: We examined 1513 hypertensive participants from the HyperGEN population who were without prevalent cardiovascular disease. The LVM prediction from stroke work (systolic blood pressure x Doppler stroke volume), sex, and height (in meters2.7) was derived in 210 nonobese, normal individuals. Observed/predicted LVM >133% defined inappropriate LVM. RESULTS: Participants with inappropriate LVM (229 subjects [15%]) exhibited higher LV dimensions and relative wall thickness, lower ejection fraction, midwall shortening and cardiac output, and prolonged isovolumic relaxation time (IVRT; P < or = .001). Other diastolic abnormalities were not associated with inappropriate LVM. After accounting for demographic and hemodynamic confounders, IVRT was directly related to excess LVM, whereas deceleration time of E velocity was negatively related to excess LVM. Nonechocardiographic correlates of prolonged relaxation included aging, African American ethnicity, male gender, and diabetes. CONCLUSIONS: The LVM exceeding the compensatory needs for workload is associated with delayed LV relaxation as well as mild midwall and chamber systolic dysfunction, independently of demographic, clinical, and hemodynamic confounders. Inappropriately high LVM also correlates with features of increased myocardial stiffness, coexisting with evidence of prolonged LV relaxation.     

Sex-specific associations of serum prolactin concentrations with cardiac remodeling: longitudinal results from the Study of Health Pomerania (SHIP)

BackgroundPrevious experimental and patient-based studies suggest that prolactin (PRL) and its 16 kDa fragment influence cardiovascular phenotypes by modulating angiogenesis. The association between serum PRL and cardiac remodeling in the general population is unknown.MethodsWe evaluated 804 individuals (441 women) from the population-based Study of Health in Pomerania, aged ≥45 years, with available baseline serum PRL who underwent serial echocardiography at baseline and five-year follow-up. Left ventricular mass (LVM) was calculated and left ventricular hypertrophy (LVH) defined by sex-specific distributions of LVM. LV geometry was defined on the basis of relative wall thickness (RWT) and LVH. Sex-specific multivariable regression analyses were performed relating PRL (independent variable modelled as a continuous variable and as sex-specific quartiles) to change in LVM, RWT, and to incident LVH and abnormal geometry.ResultsBaseline PRL concentrations were inversely associated with LVM change in men, but not in women (β per 10% decrease in PRL: 0.37; 95% CI, 0.13–0.60 in men and ?0.02; 95% CI, ?0.21 to 0.17 in women, respectively). In men, baseline PRL concentrations were also inversely associated with incident LVH [first vs. fourth PRL quartile: relative risk (RR) 2.26 (95% CI, 1.20–4.24)] and altered LV geometry on follow-up [RR for incident concentric hypertrophy per 10% decrease in PRL: 1.20 (95% CI, 1.06–1.37)]. None of the longitudinal associations were observed in women.ConclusionWe observed inverse associations of PRL with LVM change, incident LVH, and altered LV geometry in men, but not in women. Additional studies are warranted to confirm our findings and to elucidate the mechanisms underlying these sex-specific associations.     

Appropriate or inappropriate left ventricular mass in the presence or absence of prognostically adverse left ventricular hypertrophy

OBJECTIVES: To evaluate whether assessment of appropriateness of left ventricular mass (LVM) adds to the traditional definition of left ventricular hypertrophy (LVH). DESIGN: Cross-sectional, relational. METHODS: Echocardiographic LVH and appropriateness of LVM were studied in 562 subjects (231 normotensive controls, aged 35+/-11 years, 142 women; 331 hypertensive patients, aged 47+/-11 years, 135 women) classified on the basis of either the presence or the absence of both LVH (LVM index > or = 51 g/m2.7) and inappropriate LVM (LVM > 128% of the value predicted by an equation including age, sex and stroke work). RESULTS: Body mass index was comparable in hypertensive patients and controls. Hypertensive patients without LVH but with inappropriate LVM (n = 21) had higher relative wall thickness and total peripheral resistance than all other groups, whereas cardiac output was lower (all P < 0.001). Midwall mechanics was normal with appropriate LVM, independently of presence of LVH, whereas it was depressed in inappropriate LVM, either with or without LVH (both P < 0.0001). There was no substantial difference in ejection fraction among controls and hypertensive groups. Stress-corrected midwall shortening was more closely related to deviation of LVM from the value appropriate for stroke work, body size and gender (r = -0.56, P < 0.0001) than to LVM index (r = -0.26). CONCLUSIONS: Inappropriate LVM is associated with concentric geometry, high peripheral resistance and depressed wall mechanics. The deviation of LVM from the value appropriate for stroke work, body size and sex correlates with measures of myocardial function better than LVM.     

Three-dimensional analysis of left ventricular geometry using magnetic resonance imaging: feasibility and comparison with echocardiographic analysis

OBJECTIVES: Reliability of left ventricular geometry assessed by echocardiography (Echo) using an assumed left ventricular mass (LVM) and one-dimensional eccentricity (relative wall thickness: RWT), remains questionable. This study evaluated the feasibility of three-dimensional left ventricular geometric analysis using magnetic resonance imaging (MRI). METHODS: Echocardiography and MRI were performed on 55 patients with hypertension. LVM was calculated using 0.8 (American Society of Echocardiography-cube LVM) + 0.6 g for Echo and the slice summation method for MRI. Eccentricity was determined by RWT (septal wall thickness + posterior wall thickness/left ventricular inner diameter) for Echo and LVM/1.05/left ventricular end-diastolic volume (LVEDV) ratio [MRI-mass volume/cavity (M/C) ratio] for MRI. Left ventricular geometry was classified into four patterns according to the presence/absence of left ventricular hypertrophy and abnormal/normal eccentricity (partition value: RWT = 0.44, MRI; M/C ratio = 2.0), and the patient distribution was compared between the two methods. RESULTS: Although the mean values for LVM were similar, the mean value for LVEDV by echocardiography was significantly higher (p < 0.0001) and the mean M/C ratio was significantly lower (r = 0.004) than those by MRI. There were widely dispersed LVM values at higher underlying values of LVM and significant correlations between MRI-LVEDV and MRI-LVM (r = 0.87) and between Echo-LVEDV and Echo-LVM (r = 0.75). There was a significant difference in patient distribution according to left ventricular geometric pattern between the two methods (p < 0.01). Concentric (n = 18) and eccentric hypertrophy (n = 12) were dominant patterns in Echo analysis, and concentric hypertrophy (n = 23) and concentric remodeling (n = 21) were dominant in MRI analysis. The left ventricular geometric patterns were different in 32 patients (58.0%). Inadequate LVEDV values in Echo were the primary cause of this phenomenon. CONCLUSIONS: Left ventricular geometric analysis by Echo results in inaccurate values. Three-dimensional left ventricular geometric analysis using MRI provides more accurate information about left ventricular geometry.     

Left ventricular function and hemodynamic features of inappropriate left ventricular hypertrophy in patients with systemic hypertension: the LIFE study

BACKGROUND: Predicted left ventricular (LV) mass for sex, height (2.7), and hemodynamic load can be used as an intrapatient reference for the observed LV mass. The ratio of observed/predicted LV mass may allow more physiologically correct comparisons of LV geometry, systolic and diastolic functions, and hemodynamics among hypertensive patients. METHODS: We studied 659 participants in the LIFE (Losartan Intervention for Endpoint Reduction in Hypertension) study with both electrocardiographic and echocardiographic LV hypertrophy (68% of the echocardiographic cohort) without previous myocardial infarction. LV mass was predicted by an equation including sex, stroke work, and height (2.7). Observed/predicted LV mass > 128% defined inappropriate LV hypertrophy (iLVH). Relative wall thickness > or = 0.43 defined concentric LV geometry. Systolic myocardial dysfunction was assessed by midwall mechanics and abnormal LV relaxation by isovolumic relaxation time (IVRT). RESULTS: Compared with patients with appropriate LV hypertrophy (aLVH), those with iLVH had higher body mass index, LV mass index, relative wall thickness, prevalences of systolic myocardial dysfunction and prolonged IVRT and lower end-systolic stress and cardiac index. Patients with eccentric iLVH had the highest wall stress and lowest ejection fraction; 43% had systolic myocardial dysfunction. Of patients with concentric iLVH, 79% had systolic myocardial dysfunction but normal ejection fraction and the lowest wall stress. Systolic myocardial dysfunction was present in 12% with concentric aLVH and none with eccentric aLVH. Prevalence of prolonged IVRT was high in all 4 groups (65% to 77%). Cardiac index was similarly lower with concentric or eccentric iLVH than with aLVH. CONCLUSIONS: Among hypertensives with LV hypertrophy, iLVH identified cardiac phenotypes with a high prevalence of myocardial systolic dysfunction.     

Inappropriate left ventricular mass is associated with microalbuminuria independently of left ventricular hypertrophy in primary hypertension

OBJECTIVE: Inappropriate left ventricular mass (LVM) and microalbuminuria predict cardiovascular events in hypertension. We attempted to evaluate the relationship between inappropriate LVM and albuminuria in hypertensive patients. PATIENTS AND METHODS: Four hundred and two nondiabetic, untreated patients with primary hypertension were studied. The appropriateness of LVM to cardiac workload was calculated by the ratio of observed LVM to the predicted value using the reference equation. Albuminuria was evaluated by the urinary albumin to creatinine ratio. RESULTS: The deviation of LVM from the predicted value was positively related to albuminuria (P < 0.0001). Multiple regression analysis showed that albuminuria (0.0182), pulse pressure (P < 0.0001) and left ventricular hypertrophy (LVH) (P < 0.0001) were the only independent predictors of observed/predicted LVM. When subjects were divided into subgroups on the basis of the presence/absence of inappropriate LVM, patients with inappropriate LVM showed higher urinary albumin excretion (P < 0.0001), regardless of potential confounding factors, including LVH (analysis of covariance, P = 0.0453), and higher prevalence of microalbuminuria (P = 0.0024) compared to those without it. Analogous results were obtained by looking at the study patients on the basis of the presence of micro- or normoalbuminuria. Indeed, patients with microalbuminuria showed higher prevalence of inappropriate LVH compared to other left ventricular geometries (appropriate LVH and absence of LVH) (P < 0.0001). After adjusting for confounders, microalbuminuria entailed a three- and five-fold greater risk of having appropriate and inappropriate LVH, respectively. CONCLUSIONS: Inappropriate LVM is associated with albuminuria in hypertension. These data strengthen the role of microalbuminuria as an indicator of high cardiovascular risk.     

A new parameter of pulsed-wave tissue Doppler imaging: IVRa

Objective: We investigated how velocity of isovolumetric relaxation period on pulsed‐wave tissue Doppler trace (IVRa and IVRb) is affected by the left ventricular (LV) geometry changes. Methods: Two hundred cases without exclusion criteria were included in the study. Normal LV mass index (LVMI) and normal relative wall thickness (RWT) was assigned to group 1 (n = 72). Concentric remodeling (normal LVMI and increased RWT) was defined to group 2 (n = 25). Eccentric LV hypertrophy (LVH) (increased LVMI and normal RWT) was defined to group 3 (n = 62). And finally, concentric LVH (increased LVMI and increased RWT) was defined to group 4 (n = 41). Results: Patients with LVH (groups 3 and 4) were older than group 1 (P = 0.017 and 0.001). It was observed in the assessment of M‐mode ECHO parameters that the aortic valve diameter, aortic valve opening, LV end‐systolic diameter (LVESD), LV end‐diastolic diameter (LVEDD), and left atrium (LA) were higher in cases with eccentric LVH. It was shown that Ea velocity and Sa velocity time integral (Sa‐VTI) were decreased with LV geometry change. However, IVRa velocity and E/Ea were increased as LV geometry change. A positive correlation between IVRa velocity and LVMI (correlation ratio = 34%, P = 0.000) was found. Similarly, a positive correlation between IVRa velocity and RWT (correlation ratio = 17%, P = 0.025) was found. Conclusion: IVRa velocity exhibits a positive correlation with LV geometry changes indicating that IVRa velocity is affected by LV geometry like the other parameters influenced by LV geometry.     

Arterial hypertension,left ventricular geometry and QT dispersion in a middle-aged Estonian female population

The aim of the present study was to determine the prevalence of Left ventricular hypertrophy (LVH) and different left ventricular (LV) geometric patterns in the middle-aged women population of Tallinn, to assess the relationship between LV geometry, age, blood pressure and LV repolarization duration and inhomogeneity. A random sample of the population, 482 women aged 35-59, was examined in the framework of a cardiovascular risk factors survey for the WHO/CINDI programme years 1999-2000. Patients with valvular pathology, primary cardiomyopathy, atrial fibrillation, bundle branch blocks and flat T wave on electrocardiography (ECG) were excluded; 398 (82.2%) of the participants underwent echocardiography (Echo) and standard 12-lead ECG at rest and were included in the study. LVH was defined if left ventricular mass (LVM), LVM/height and LVM/BSA were >198 g, >121 g/m and > 120 g/m2, respectively. Arterial hypertension was determined in 23.1% of the women. The prevalence of arterial hypertension was three times higher in those aged 50-59 than in those aged 40-49 (37.4% vs 13.2%; p < 0.05). Different geometric patterns were found as follows: concentric hypertrophy in 9.1%; eccentric hypertrophy 33.9%; concentric remodelling 9.5% and normal geometry 47.5% of the participants. Concentric hypertrophy was found exclusively in hypertensive women and increased with age. No age-related eccentric hypertrophy and concentric remodelling differences were found, either in the normotensive or in the hypertensive group. Prolonged QT dispersion--a marker of increased myocardial electrical instability, was associated with LVH and arterial hypertension and was related mostly to concentric hypertrophy in hypertensives.     

Prevalence and correlates of left atrial enlargement in essential hypertension: role of ventricular geometry and the metabolic syndrome: the Evaluation of Target Organ Damage in Hypertension study

BACKGROUND: The cardiac effects of hypertension include a variety of structural changes such as increases in left ventricular mass (LVM) and left atrium (LA) size. Although data on hypertension-induced left ventricular changes are extensive, relatively little information is available on LA size from large-scale studies. OBJECTIVE: We sought to assess the prevalence of LA enlargement in a large selected hypertensive population and to determine the relations of LA size to several biologic variables including left ventricular hypertrophy (LVH) and metabolic disturbances. METHODS: A total of 2500 untreated and treated uncomplicated essential hypertensives consecutively attending, for the first time, our hospital out-patient hypertension clinic and included in the Evaluation of Target Organ Damage in Hypertension, an observational ongoing registry of hypertension-related target organ damage (TOD), were considered for this analysis. All patients underwent extensive clinical, laboratory and ultrasonographic investigations searching for cardiac (and extracardiac) TOD. The LA was considered enlarged when its anteroposterior diameter exceeded 3.7 cm in women and 4.1 cm in men. LVH was defined according to two different criteria: >/= 125 g/m in men and >/= 110 g/m in women; or >/= 51 g/m in men and >/=47 g/m in women. RESULTS: Enlarged LA diameter was present in 24.5% of women and in 21.5% of men. Compared with 1925 patients with normal LA size, the 575 patients with enlarged LA were older, more frequently overweight, had higher systolic blood pressure and included a greater proportion of subjects under antihypertensive treatment, with diabetes and metabolic syndrome. Both LA size and prevalence of LA enlargement differed significantly in relation to left ventricular geometry and LVM, being greater in patients with concentric or eccentric LVH than in those with left ventricular concentric remodeling or normal geometry. The prevalence of LA enlargement was similar in patients with concentric and eccentric LVH. According to a logistic regression analysis, overweight, LVH, fasting blood glucose > 7.0 mmol/l and metabolic syndrome were the main independent predictors of LA enlargement in the overall population as well as in both untreated and treated hypertensive subgroups. CONCLUSIONS: Our study suggests that: LA enlargement is a common echocardiographic finding in selected essential hypertensive patients with different left ventricular geometric patterns; LA size and LA enlargement is related to LVM rather than the type of LVH; and, in addition to LVH, overweight, high fasting glucose and metabolic syndrome are associated with LA dimensions.     

Angiotensin-converting enzyme gene polymorphism and geometric patterns of hypertensive left ventricular hypertrophy

Polymorphism in the angiotensin-converting enzyme (ACE) gene has been found to be associated with left ventricular hypertrophy (LVH) in patients with essential hypertension (EHT) in certain populations. We sought to evaluate, in a Japanese population, whether ACE genotype is related to left ventricular mass, or to the geometry of LVH in EHT. Eighty-seven patients with EHT were examined. Their relative wall thickness (RWT) and left ventricular mass index (LVMI), determined by echocardiogram, were used to divide them into 4 groups: normal (normal RWT and LVMI, n = 35); concentric remodeling (increased RWT but normal LVMI, n= 10); eccentric hypertrophy (increased LVMI but normal RWT, n = 20); and concentric hypertrophy (increased LVMI and RWT, n = 22). Genetic analysis for ACE genotypes was performed on peripheral leukocytes using PCR techniques. Interventricular septal thickness and RWT were significantly greater in the patients with the DD genotype than in those with the II genotype, but LVMI did not differ among the three ACE genotypes. The frequency of the DD genotype was higher in the concentric hypertrophy group than in each of the other groups, and the frequency of the II genotype was lower in the concentric hypertrophy group than in either the normal or eccentric hypertrophy group. The geometric pattern of hypertensive LVH was associated with ACE genotype in a Japanese population. The DD genotype may contribute to concentric hypertrophy, but not to eccentric hypertrophy.     

Left ventricular systolic and diastolic dysfunction in patients with chronic renal failure treated with hemodialysis

Systolic and diastolic left ventricular dysfunction is common and important predictor of risk of death in end-stage renal failure. Systolic dysfunction is defined echocardiographically by a shortening fraction < 25% or an ejection fraction < 40%. Systolic dysfunction has a poor prognosis, strongly associated with myocardial ischemia and left ventricular hypertrophy (LVH). Diastolic dysfunction combines relaxation problems with compliance abnormalities and usually is associated with LVH. It is not clinically possible to distinguish systolic from diastolic LV dysfunction. This underlines the importance of echocardiographic diagnosis. In the present study we have analysed echocardiographically the left ventricular systolic and diastolic function and some possible risk factors contributing to its dysfunction development in patients with chronic renal failure (crf) treated by hemodialysis (HD). From a cohort of 85 patients with crf we selected for analysis 59 clinically stable patients. Echocardiography (ECHO), ECG, body mass index (BMI), serum creatinine, urea, total protein, albumin, hemoglobin, hematocrit, electrolytes, endothelin (ET-1) and parathyroid hormone (PTH) concentrations were evaluated in all patients after HD session. In all HD patients systolic and diastolic LV dysfunction was observed as well as LVH: concentric LVH was detected by ECHO in 46 patients and in 13 patients excentric LVH was observed. Mean serum concentrations of urea, creatinine, endothelin (ET-1), PTH and phosphate were increased while serum concentration of hemoglobin, total protein, albumin, sodium, potassium, calcium were in the normal range. Positive correlation was found between PTH serum concentration and LVM r = 0.704 (p < 0.001), between PTH serum concentration and IVS r = 0.267 (p < 0.04), between PTH serum concentration and PW r = -0.238 (p < 0.04), between ET-1 and RWT r = 0.447 (p < 0.04) and negative correlation between BMI and LVMI r = -0.451 (p < 0.05). Our observations suggests that uremic cardiomyopathy is heterogenous (systolic and diastolic dysfunction) and multifactoral. The correlations between serum PTH concentration and LVH and between BMI and LVH confirmed that both hyperparathyroidism and malnutrition are important factors influencing the development of LVH which plays an important role in the systolic and diastolic cardiac failure in HD patients.     

Left ventricular hypertrophy in Caucasian master athletes: Differences with hypertension and hypertrophic cardiomyopathy

AIM: To study, by conventional echocardiography, left ventricular remodelling and function in master athletes, hypertension and hypertrophic cardiomyopathy. METHODS: We studied 30 master athletes (MA; soccer players; mean age 43.9+/-5.9), 24 subjects with essential hypertension (HYP; 46.6+/-6), 20 patients with hypertrophic cardiomyopathy (HCM; 42.2+/-9) and 30 normal individuals (CG; 43.4+/-5). An integrated M-mode/two-dimensional echocardiographic analysis was performed to determine chambers dimensions, relative wall thickness (RWT) and left ventricular mass (LVM), indexed to height in meters raised to the power of 2.7 (LVM/h(2.7)). Cut-off levels for LVM/h(2.7) and RWT were defined to assess 4 different patterns of LV geometric remodelling. In addition, we measured indexes of global systolic performance and indexes of global diastolic function. RESULTS: LV wall thickness and LV end-diastolic dimensions were higher in MA than controls, but significantly lower than other groups. LVH/h(2.7) was increased in 79% of HYP and in 95% of HCM, but was within the normal limits in MA. LV geometry was normal in 22 out of 30 MA (73%), while the remaining (8 athletes, 27%) showed a concentric remodelling. Systolic function (FS and EF) was normal in MA, but was slightly reduced in HYP and increased in HCM. Analysis of diastolic function showed an abnormal relaxation pattern in all HYP and 95% of HCM, but was normal in all MA. The ratio between peak filling rate and stroke volume (PFR/SV), a relatively independent index of diastolic function, was significantly greater in hypertensive patients with normal LV remodelling compared to those without it (4+/-0.39 vs. 4.91+/-0.19; P = 0.0002). CONCLUSION: MA showed lower values of wall thickness, LV dimensions and LV mass compared with HYP and HCM. Despite an abnormal remodelling, all the athletes showed a normal systolic and diastolic function. The differential diagnosis between MA, HYP and HCM is feasible by accurate, comprehensive standard Doppler echocardiography.     

Gender and the relationship between resting heart rate and left ventricular geometry

OBJECTIVES: Heightened mortality is common to both an elevated resting heart rate and left ventricular hypertrophy (LVH). We examined the relationship between resting heart rate and left ventricular geometry. METHODS: We analysed resting heart rate and echocardiographic data on 1,685 individuals aged 25-93 years, 756 males and 929 females, without heart failure. The study population, 719 normotensives and 966 untreated hypertensives, was derived from the Egyptian National Hypertension Project (1991-94); a cross-sectional study of the prevalence of hypertension and cardiovascular risk factors in Egyptians. The mean of the last two of three heart rate readings was used to represent the resting heart rate. RESULTS: Left ventricular mass index (LVMI) was weakly inversely related to heart rate in total males (r= -0.14, P< 0.0005) and total females (r= -0.1, P= 0.007) after controlling for age and blood pressure. The relative wall thickness (RWT) of the left ventricle was positively associated with heart rate in females. Resting heart rate increased linearly from 83.8 to 89 b.p.m. (P= 0.03) from the lowest (< or = 0.33) to highest (> or = 0.47) RWT quintiles in hypertensive females after adjusting for age and blood pressure. In both those with and without LVH (defined as LVMI > 125 g/m2), hypertensive females with RWT > 0.45 compared to those with RWT < or = 0.45 had consistently higher resting heart rate (93.8 b.p.m. versus 84.2 b.p.m., P = 0.047 and 88.9 b.p.m. versus 85 b.p.m., P = 0.005, respectively) after adjusting for age and blood pressure. No such relationship was found in males. CONCLUSIONS: Among hypertensive females, an elevated resting heart rate is associated with abnormal left ventricular geometry, namely, concentric left ventricular remodelling and hypertrophy.     

高血压左心室肥厚患者B型钠尿肽与早期舒张功能不全的关系

目的研究B型钠尿肽(BNP)与高血压左心室肥厚(LVH)以及LVH时无症状的左心室舒张性心功能不全(LVDD)的关系,探讨高血压LVH伴LVDD时的诊断方法。方法 113例高血压患者采用彩色多普勒超声心动图检测舒张末左心室室间隔厚度(IVSD)、左心室后壁厚度(PWT)、二尖瓣舒张早期最大峰值速度(E)、舒张晚期最大峰值速度(A)、E/A、左心室等容舒张时间(IVRT)等,计算左心室重量(LVM)、左心室重量指数(LVMI);采用酶联免疫法检测BNP,BNP与高血压LVH及LVDD的关系采用相关性分析。结果所有患者BNP与收缩压呈正相关(r=0.190,P<0.05),与IVSD、PWT、LVM、LVMI呈正相关(r=0.399、0.394、0.678、0.795、P<0.01);与E、E/A呈负相关(r=-0.885、-0.869,P<0.01);与A、IVRT呈正相关(r=0.735、0.817,P<0.01)。BNP在82.79ng/L时,诊断LVDD的敏感性为90%,特异性为100%,准确性为92%。结论高血压LVH时,BNP明显升高,而当高血压LVH伴LVDD时,BNP升高更明显,BNP是反映LVH及LVH伴早期LVDD的敏感指标。     

Left ventricular geometric patterns and QT dispersion in untreated essential hypertension

The spectrum of left ventricular adaptation to hypertension, different types of hypertrophy patterns, and QT dispersion in different types of hypertrophy was investigated in 107 patients with untreated essential hypertension and 30 age- and gender-matched normal adults studied by 12-derivation electrocardiogram (ECG), two-dimensional, and M-mode echocardiography.Left ventricular mass (LVM), body mass index, total peripheral resistance (TPR), relative wall thickness (RWT), and QT dispersion were found to be statistically significantly higher in the hypertension group (P < .001 for all). Among hypertensive patients, 41.1% had both normal LVM and RWT, here called normal left ventricle in hypertension; 10.3% had concentric hypertrophy with increased LVM and RWT; 14.95% had eccentric hypertrophy with increased LVM and normal RWT; and 32.7% had concentric remodeling with normal LVM and increased RWT.Echocardiographically derived cardiac index was higher in the concentric hypertrophy and eccentric hypertrophy patterns (P = .002 and P < .0001, respectively), whereas TPR was higher in the concentric hypertrophy and concentric remodeling patterns (P = .017 and .02, respectively).QT dispersion values were found to be increased in the hypertensive group (P = .001), whereas similar values were calculated for different types of hypertrophy patterns.We conclude that the more common types of ventricular adaptation to essential hypertension are eccentric hypertrophy and concentric remodeling. Concentric hypertrophy is found to be associated with both volume and pressure overload, whereas eccentric hypertrophy is associated with volume overload only and concentric remodeling is associated with pressure overload. But different left ventricular geometric patterns seem to have similar effects on QT dispersion.     

左心室功能、质量及几何构型对高血压患者自主神经功能的影响

目的 探讨高血压患者不同左心室功能、质量、几何构型心率变异性(HRV)指标的差别及对自主神经调节的影响。方法将300例高血压患者分别分为收缩功能不全与正常组;舒张功能异常与正常组;左心室肥厚(LVH)与正常组及几何构型正常和异常组,后者包括向心性重构、离心性肥厚和向心性肥厚三个亚组,分别比较各对应组间HRV指标的差别,并对左心室射血分数(LVEF)、二尖瓣血流频谱E峰、A峰比值(E/A)、左心室质量指数(LVMI)、相对室壁厚度(RWT)与HRV各指标间的相关性进行了分析。结果 左心室收缩功能不全组与正常组间HRV各项指标无显著性差异,舒张功能异常组HRV各项指标均显著低于正常组,LVH组部分指标[正常窦性心搏间期的标准差(SDNN)、5min连续时间段标准差的平均值(SDNNI)、低频功率(LF)和高频功率(HF)]明显低于正常组,除相邻正常窦性心搏间期(NN)间期差的均方根(rMMSD)和NN间期差大于50ms心搏与总NN间期的百分比(PNN50)外,3个几何构型异常组HRV各项指标均明显低于正常组,但各异常组间无显著性差异。单变量回归分析提示RWT、LVMI、LVEF与HRV主要指标存在显著的相关性,E/A与HRV各项指标均显著相关。多变量分析提示RWT与SDNN、LVMI与SDANN、LVEF与SDNN、E/A与LF独立相关。结论 左心室功能损害、LVH及几何构型异常可影     

Natural history of concentric left ventricular geometry in community-dwelling older adults without heart failure during seven years of follow-up

Presence of concentric left ventricular (LV) geometry has important pathophysiologic and prognostic implications. However, little is known about its natural history in older adults. Of the 5,795 community-dwelling adults ≥65 years of age in the Cardiovascular Health Study, 1,871 without baseline heart failure had data on baseline and 7-year echocardiograms. Of these 343 (18%) had baseline concentric LV geometry (concentric remodeling 83%, concentric LV hypertrophy [LVH] 17%) and are the focus of the present study. LV geometry at year 7 was categorized into 4 groups based on LVH (LV mass indexed for height >51 g/m2·?) and relative wall thickness (RWT): eccentric hypertrophy (RWT ≤0.42 with LVH), concentric hypertrophy (RWT >0.42 with LVH), concentric remodeling (RWT >0.42 without LVH), and normal (RWT ≤0.42 without LVH). At year 7, LV geometry normalized in 57%, remained unchanged in 35%, and transitioned to eccentric hypertrophy in 7% of participants. Incident eccentric hypertrophy occurred in 4% and 25% of those with baseline concentric remodeling and concentric hypertrophy, respectively, and was associated with increased LV end-diastolic volume and decreased LV ejection fraction at year 7. Previous myocardial infarction and baseline above-median LV mass (>39 g/m2·?) and RWT (>0.46) had significant unadjusted associations with incident eccentric LVH; however, only LV mass >39 g/m2·? (odds ratio 17.52, 95% confidence interval 3.91 to 78.47, p <0.001) and previous myocardial infarction (odds ratio 4.73, 95% confidence interval 1.16 to 19.32, p = 0.031) had significant independent associations. In conclusion, in community-dwelling older adults with concentric LV geometry, transition to eccentric hypertrophy was uncommon but structurally maladaptive.     

The Natural History of Left Ventricular Geometry in the Community: Clinical Correlates and Prognostic Significance of Change in LV Geometric Pattern

ObjectivesThis study sought to evaluate pattern and clinical correlates of change in left ventricular (LV) geometry over a 4-year period in the community; it also assessed whether the pattern of change in LV geometry over 4 years predicts incident cardiovascular disease (CVD), including myocardial infarction, heart failure, and cardiovascular death, during an additional subsequent follow-up period.BackgroundIt is unclear how LV geometric patterns change over time and whether changes in LV geometry have prognostic significance.MethodsThis study evaluated 4,492 observations (2,604 unique Framingham Heart Study participants attending consecutive examinations) to categorize LV geometry at baseline and after 4 years. Four groups were defined on the basis of the sex-specific distributions of left ventricular mass (LVM) and relative wall thickness (RWT) (normal: LVM and RWT <80th percentile; concentric remodeling: LVM <80th percentile but RWT ≥80th percentile; eccentric hypertrophy: LVM ≥80th percentile but RWT <80th percentile; and concentric hypertrophy: LVM and RWT ≥80th percentile).ResultsAt baseline, 2,874 of 4,492 observations (64%) had normal LVM and RWT. Participants with normal geometry or concentric remodeling progressed infrequently (4% to 8%) to eccentric or concentric hypertrophy. Change from eccentric to concentric hypertrophy was uncommon (8%). Among participants with concentric hypertrophy, 19% developed eccentric hypertrophy within the 4-year period. Among participants with abnormal LV geometry at baseline, a significant proportion (29% to 53%) reverted to normal geometry within 4 years. Higher blood pressure, greater body mass index (BMI), advancing age, and male sex were key correlates of developing an abnormal geometry. Development of an abnormal LV geometric pattern over 4 years was associated with increased CVD risk (140 events) during a subsequent median follow-up of 12 years (adjusted-hazards ratio: 1.59; 95% confidence interval: 1.04 to 2.43).ConclusionsThe longitudinal observations in the community suggest that dynamic changes in LV geometric pattern over time are common. Higher blood pressure and greater BMI are modifiable factors associated with the development of abnormal LV geometry, and such progression portends an adverse prognosis.     

Impaired left ventricular synchronicity in hypertensive patients with ventricular hypertrophy

OBJECTIVES: The influence of left ventricular hypertrophy (LVH) on left ventricular synchronicity, and the prevalence of left ventricular dyssynchrony in hypertensive patients with LVH are unknown. The purpose of this study was to determine the influence of LVH on left ventricular synchronicity in hypertensive subjects. METHOD: Tissue Doppler imaging (TDI) was performed in 115 hypertensive and 30 control individuals. Hypertensive patients were divided into a LVH group and a non-LVH group according to the left ventricular mass index (LVMI). Diastolic and systolic asynchrony was determined by measuring the maximal differences in time to peak myocardial systolic contraction (Ts-max) and early diastolic relaxation (Te-max) between any two of the left ventricular segments and the standard deviation of time to peak myocardial systolic contraction and early diastolic relaxation of all 12 segments. RESULTS: Ts-max was greater in both the non-LVH and LVH groups than in controls, (96.68 +/- 26.21 versus 79.30 +/- 25.19 versus 53.20 +/- 15.24 ms, both P < 0.001) and in the LVH group than in the non-LVH group (96.68 +/- 26.21 versus 79.30 +/- 25.19 ms, P < 0.01). Te-max was prolonged in both patient groups, being most advance in the LVH group (67.39 +/- 11.01 versus 57.18 +/- 11.42 versus 46.72 +/- 13.24 ms, both P < 0.001 versus control group and P < 0.001 versus non-LVH group). LVH patients had shown a greater prevalence of both systolic and diastolic asynchrony than non-LVH patients. A Ts-max value greater than 88 ms had 68% sensitivity and 71% specificity for detecting hypertensive patients with LVH. CONCLUSION: Left ventricular systolic synchronicity was impaired in hypertensive patients with LVH. TDI was shown to be useful for the detection of myocardial abnormalities in such patients.     

Associations of Left Ventricular Hypertrophy and Geometry with Adverse Outcomes in Patients with CKD and Hypertension

Background and objectives

Left ventricular hypertrophy (LVH) and abnormal left ventricular (LV) geometry predict adverse outcomes in the general and hypertensive populations, but findings in CKD are still inconclusive.

Design, setting, participants, & measurements

We enrolled 445 patients with hypertension and CKD stages 2–5 in two academic nephrology clinics in 1999–2003 who underwent both echocardiography and ambulatory BP monitoring. LVH (LV mass >100 g/m² [women] and >131 g/m² [men]) and relative wall thickness (RWT) were used to define LV geometry: no LVH and RWT≤0.45 (normal), no LVH and RWT>0.45 (remodeling), LVH and RWT≤0.45 (eccentric), and LVH and RWT>0.45 (concentric). We evaluated the prognostic role of LVH and LV geometry on cardiovascular (CV; composite of fatal and nonfatal events) and renal outcomes (composite of ESRD and all-cause death).

Results

Age was 64.1±13.8 years old; 19% had diabetes, and 22% had CV disease. eGFR was 39.9±20.2 ml/min per 1.73 m². LVH was detected in 249 patients (56.0%); of these, 125 had concentric LVH, and 124 had eccentric pattern, whereas 71 patients had concentric remodeling. Age, women, anemia, and nocturnal hypertension were independently associated with both concentric and eccentric LVH, whereas diabetes and history of CV disease associated with eccentric LVH only, and CKD stages 4 and 5 associated with concentric LVH only. During follow-up (median, 5.9 years; range, 0.04–15.3), 188 renal deaths (112 ESRD) and 103 CV events (61 fatal) occurred. Using multivariable Cox analysis, concentric and eccentric LVH was associated with higher risk of CV outcomes (hazard ratio [HR], 2.59; 95% confidence interval [95% CI], 1.39 to 4.84 and HR, 2.79; 95% CI, 1.47 to 5.26, respectively). Similarly, greater risk of renal end point was detected in concentric (HR, 2.33; 95% CI, 1.44 to 3.80) and eccentric (HR, 2.30; 95% CI, 1.42 to 3.74) LVH. Sensitivity analysis using LVH and RWT separately showed that LVH but not RWT was associated with higher cardiorenal risk.

Conclusions

In patients with CKD, LVH is a strong predictor of the risk of poor CV and renal outcomes independent from LV geometry.