Hypertension Is Associated with White Matter Disruption in Apparently Healthy Middle-Aged Individuals.

BACKGROUND AND PURPOSE: Traditional cardiovascular risk factors have been associated with white matter disease. Because hypertension results in vascular stiffness and impaired cerebral perfusion, we hypothesized that it would be the most relevant risk factor for microstructural white matter disruption in apparently healthy middle-aged individuals with a family history of early-onset coronary artery disease. MATERIALS AND METHODS: This was a cross-sectional analysis of participants in the Genetic Study of Atherosclerosis Risk with DTI. Regional fractional anisotropy of 181 segmented brain regions was measured using Eve WM Atlas. Risk factors were examined using univariate analysis for 48 regions representing deep WM structures. Minimal multivariable linear regression models adjusting for age, sex, and race and maximal linear regression models adjusting for cardiovascular risk factors were performed for regions meeting the Bonferroni threshold in the initial analysis. RESULTS: Included were 116 subjects (mean age, 49 ± 11 years; 57% men) with a moderate load of cardiovascular risk factors. Subjects with hypertension had significantly lower regional fractional anisotropy in the right cingulum and left stria terminalis in the minimal and maximal regression models. Additionally, there was lower regional fractional anisotropy in the left fornix in the maximal model and right sagittal stratum in the minimal model. Systolic blood pressure values were significantly associated with regional fractional anisotropy in the left superior longitudinal fasciculus in the maximal model. There were no significant differences among regional fractional anisotropy values for other cardiovascular risk factors. CONCLUSIONS: In middle-aged apparently healthy individuals with susceptibility to vascular disease, among all known cardiovascular risk factors, hypertension was associated with microstructural WM disruption.

Racial differences in low-density lipoprotein particle size in families at high risk for premature coronary heart disease.

OBJECTIVE: Although small, dense low-density lipoprotein (LDL) has been implicated in atherogenesis and coronary heart disease (CHD) events, little is known about possible racial differences in LDL particle size. This study was designed to examine racial differences in the prevalence of small, dense LDL among 159 African-American and 477 White siblings of persons with premature (<60 years of age) CHD. METHODS AND RESULTS: This study examined fasting levels of total cholesterol, LDL cholesterol, high-density lipoprotein cholesterol, apolipoprotein B (ApoB), apolipoprotein A-1, and triglycerides, as well as factors known to be associated with small, dense LDL, including age, sex, obesity, hypertension, and diabetes. Relative LDL particle size was defined by the LDL cholesterol to ApoB ratio. Direct measurement of LDL particle size was obtained by proton NMR spectroscopy in a subset of 64 siblings. Despite similar levels of total and LDL cholesterol, White siblings were more likely to have low LDL cholesterol to ApoB ratios, indicative of atherogenic small, dense LDL, compared with African-American siblings. Multiple logistic regression analysis predicting the presence of LDL cholesterol/ApoB < or = 1.0 demonstrated that race (P = .009), triglyceride level (P = .0001), and diabetes (P = .02) were independent predictors, controlling for age and all other variables. Direct measurement of LDL particle size by NMR spectroscopy supported these findings. CONCLUSION: These findings provide the first known evidence that White individuals from a population at high risk for premature CHD have a greater probability of having a preponderance of small, dense LDL particles than do African Americans, independent of triglyceride levels, and despite comparable levels of total and LDL cholesterol.

Higher prevalence of GPIIIa PlA2 polymorphism in siblings of patients with premature coronary heart disease.

BACKGROUND: The Pl(A2) polymorphism of GPIIIa has been associated with unstable coronary syndromes in some studies, but the association has remained debated. None of the previous studies have focused on families at high risk. Risk factors tend to cluster within kindreds with high prevalence of premature coronary heart disease (CHD). Therefore, a heightened prevalence of the Pl(A2) polymorphism among siblings of patients with CHD would support the hypothesis that Pl(A2) is linked, directly or indirectly, to CHD. OBJECTIVES: To measure the prevalence of the Pl(A2) polymorphism among siblings of patients with CHD before the age of 60 years and to seek an association between the Pl(A2) polymorphism and established atherosclerotic and thrombogenic risk factors. METHODS: From January 1994 to April 1996, we genotyped 116 asymptomatic siblings (60 Caucasians, 56 Afro-Caribbeans) of patients with CHD manifestations before the age of 60 years for the Pl(A) polymorphism (also called HPA-1). A control cohort was used for comparison, consisting of individuals that were matched for race and geographic area but were free of CHD (n = 268, 168 Caucasians and 100 Afro-Caribbeans). In addition, we have characterized the sibling cohort for other atherogenic and thrombogenic risk factors. RESULTS: The prevalence of Pl(A2)-positive individuals (Pl(A2)[+], Pl(A1/A2) heterozygotes plus Pl(A2/A2) homozygotes) in the sibling cohort was high: 41.4%. When analyzed separately, the prevalence of Pl(A2)(+) siblings was 53.3% among Caucasians and 28.6% among Afro-Caribbeans. There was no association between Pl(A2) and other established atherogenic or thrombogenic risk factors. Interestingly, the clustering of other risk factors was lesser among Pl(A2)(+) siblings than their Pl(A1) counterparts. CONCLUSIONS: This study supports the hypothesis that the prevalence of Pl(A2)(+) individuals is high in kindreds with premature CHD. Hence, like the established risk factors that tend to cluster in families with premature CHD and contribute strongly to the accelerated atherosclerotic process affecting these individuals, the Pl(A2) polymorphism of GPIIIa may represent an inherited risk that promotes the thromboembolic complications of CHD. That these asymptomatic Pl(A2)(+) siblings had overall less established risk factors than their Pl(A1) counterparts might represent an explanation for why they remained asymptomatic despite their Pl(A2) positivity.

Nurse-mediated cholesterol management compared with enhanced primary care in siblings of individuals with premature coronary disease.

BACKGROUND: Siblings of individuals with premature coronary heart disease have a high prevalence of low-density lipoprotein cholesterol (LDL-C) levels requiring treatment. OBJECTIVE: To evaluate management strategies for high LDL-C levels in apparently healthy 30- to 59-year-old siblings of individuals with documented coronary heart disease prior to age 60 years. METHODS: In a 2-year trial of care provided by either a nurse trained in lipid management (NURS) or enhanced primary care (EPC), in which physicians received recommendations based on national guidelines, 156 siblings with LDL-C levels of 4.14 mmol/L (160 mg/dL) were randomized by family. The LDL-C goal levels below 3.36 mmol/L (130 mg/dL) were compared between and within intervention groups. Multiple logistic regression analyses were applied to predict 2-year achievement of the goal. RESULTS: The NURS group achieved a significantly greater percentage of goal LDL-C levels than the EPC group (26% vs 10%; P=.008). The NURS LDL-C levels decreased an average of 0.91 mmol/L (35 mg/dL) while EPC levels decreased by 0.52 mmol/L (24 mg/dL) (P=.09). In the final multivariate model, siblings taking lipid-lowering drug treatment were 6.02 times more likely (95% confidence interval, 2.24-16.18) than those not receiving pharmacotherapy to achieve LDL-C goals; nurse management (P=.09) was marginally significant. Pharmacotherapy was instituted in 45.2% of NURS and 16.7% of EPC siblings (P=.001). CONCLUSIONS: High LDL-C levels in siblings were more effectively treated by a trained nurse, probably related to greater adherence to the application of national guidelines. Nonetheless, the majority of siblings with high LDL-C levels did not meet goal levels 2 years after an index case coronary heart disease event.

Exaggerated reactivity to mental stress is associated with exercise-induced myocardial ischemia in an asymptomatic high-risk population.

BACKGROUND: This study was done to determine whether cardiovascular reactivity to mental stress is associated with exercise-induced occult ischemia in an asymptomatic population at high risk for premature coronary heart disease (CHD). METHODS AND RESULTS: One hundred fifty-two siblings of persons with premature CHD underwent mental stress testing. Exercise thallium tomography and 24-hour Holter monitoring were also performed. Hemodynamic changes were monitored during both stressors. Siblings positive for exercise-induced ischemia were offered cardiac catheterization. During mental stress, siblings with an abnormal exercise ECG and/or thallium scan (n=15) had greater maximal increases in systolic blood pressure (SBP, P=.0004) and diastolic blood pressure (DBP, P=.05) and had greater heart rate variability in the normalized low frequency domain of an analysis of Holter monitor recordings, compared with siblings without exercise-induced ischemia. Coronary arteriography confirmed coronary atherosclerosis in 85% of siblings with exercise-induced ischemia. Regression analyses showed that occult ischemia during exercise was a strong independent predictor of maximal change in SBP and DBP during mental stress. A multivariate logistic model demonstrated that siblings with exercise-induced occult ischemia were 21 times more likely to be "hot" responders (top quartile of change in SBP and DBP) during mental stress. CONCLUSIONS: An exaggerated cardiovascular response to mental stress is associated with exercise-induced myocardial ischemia in persons with preclinical coronary heart disease.