VEGF (Vascular Endothelial Growth Factor) Inhibition and Hypertension: Does Microvascular Rarefaction Play a Role?

Drugs acting by inhibition of the angiogenic action of VEGF (vascular endothelial growth factor) have become major instruments in the treatment of cancer. The downside of their favorable effects in cancer treatment is their frequent cardiovascular side effects. The most consistent finding thus far on the cardiovascular side effects of VEGF inhibitors is the high incidence of hypertension. In this short review, we discuss the evidence that hypertension occurring during VEGF inhibitor treatment is caused by microvascular rarefaction. After a review of the role of VEGF in microvascular growth and differentiation, we present evidence from studies in experimental models of hypertension as well as clinical studies on the microvascular network changes during and after VEGF inhibitor treatment.

Central hemodynamics in relation to blood lead in young men prior to chronic occupational exposure.

Background: Aortic pulse wave velocity (aPWV) predicts cardiovascular complications, but the association of central arterial properties with blood lead level (BL) is poorly documented. We therefore assessed their association with BL in 150 young men prior to occupational lead exposure, using baseline data of the Study for Promotion of Health in Recycling Lead (NCT02243904). Methods: Study nurses administered validated questionnaires and performed clinical measurements. Venous blood samples were obtained after 8-12 h of fasting. The radial, carotid and femoral pulse waves were tonometrically recorded. We accounted for ethnicity, age, anthropometric characteristics, mean arterial pressure, heart rate, smoking and drinking, and total and high-density lipoprotein serum cholesterol, as appropriate. Results: Mean values were 4.14 µg/dL for BL, 27 years for age, 108/79/28 mm Hg for central systolic/diastolic/pulse pressure, 100/10% for the augmentation ratio/index, 1.63 for pressure amplification, 5.94 m/s for aPWV, 27/11 mm Hg for the forward/backward pulse pressure height, and 43% for the reflection index. Per 10-fold BL increase, central diastolic pressure and the augmentation ratio were respectively 5.37 mm Hg (95% confidence interval [CI], 1.00-9.75) and 1.57 (CI, 0.20-2.94) greater, whereas central pulse pressure and the forward pulse pressure height were 3.74 mm Hg (CI, 0.60-6.88) and 3.37 mm Hg (CI, 0.22-6.53) smaller (p ≤ .036 for all). The other hemodynamic measurements were unrelated to BL. The reflected pulse peak time was inversely correlated with diastolic pressure (r = -0.20; p ≤ .017). Conclusion: At the exposure levels observed in our current study, aPWV, the gold standard to assess arterial stiffness, was not associated with BL. Increased peripheral arterial resistance, as reflected by higher diastolic pressure, might bring reflection points closer to the heart, thereby moving the backward wave into systole and increasing the augmentation ratio in relation to BL.

CXCL10 Is a Circulating Inflammatory Marker in Patients with Advanced Heart Failure: a Pilot Study.

Chemokines are involved in the remodeling of the heart; however, their significance as biomarkers in heart failure is unknown. We observed that circulating CXCR3 receptor chemokines CXCL9 and CXCL10 in a rat model of heart failure were increased 1 week after myocardial infarction. CXCL10 was also increased in both remote and infarcted regions of the heart and remained elevated at 16 weeks; CXCL9 was elevated in the remote area at 1 week. In humans, hierarchical clustering and principal component analysis revealed that circulating CXCL10, MIP-1α, and CD40 ligand were the best indicators for differentiating healthy and heart failure subjects. Serum CXCL10 levels were increased in patients with symptomatic heart failure as indexed by NYHA classification II through IV. The presence of CXCL10, MIP-1α, and CD40 ligand appears to be dominant in patients with advanced heart failure. These findings identify a distinct profile of inflammatory mediators in heart failure patients.

Heritability of the retinal microcirculation in Flemish families.

BACKGROUND: Few population studies have described the heritability and intrafamilial concordance of the retinal microvessels, or the genetic or environmental correlations of the phenotypes of these vessels. METHODS: We randomly selected 413 participants from 70 families (mean age, 51.5 years; 50.1% women) from a Flemish population. We postprocessed retinal images using IVAN software to generate the central retinal arteriole equivalent (CRAE), central retinal venule equivalent (CRVE), and arteriole-to-venule-ratio (AVR) from these images. We used SAGE version 6.2 and SAS version 9.2 to compute multivariate-adjusted estimates of heritability and intrafamilial correlations of the CRAE, CRVE, and AVR of the retinal microvessels in the images. RESULTS: Sex, age, mean arterial pressure, and smoking explained up to 12.7% of the variance of the phenotypes of the retinal microvessels of the study participants. With adjustments applied for these covariates, the heritability estimates of CRAE, CRVE, and AVR were 0.213 (P = 0.044), 0.339 (P = 0.010), and 0.272 (P = 0.004), respectively. The parent-offspring correlations for CRAE, CRVE, and AVR were 0.118 (NS), 0.225 (P < 0.01), and 0.215 (P < 0.05), respectively. The corresponding values were 0.222 (P < 0.05), 0.213 (P < 0.05), and 0.390 (P < 0.001) for sib-sib correlations, respectively. The genetic and environmental correlations between CRAE and CRVE were 0.360 and 0.545 (P < 0.001 for both). CONCLUSION: Our study showed moderate heritability for CRAE, CRVE, and AVR, and a significant genetic correlation of CRAE with CRVE in the Flemish population of our study. These findings suggest that genetic factors influence the diameter of the retinal microvessels, and that CRAE and CRVE share some genetic determinants.

Role of the Rhoa/Rho kinase system in flow-related remodeling of rat mesenteric small arteries in vivo.

In small arteries, a chronic blood flow reduction leads to inward hypotrophic remodeling, while a chronic blood flow elevation induces outward hypertrophic remodeling. The RhoA/Rho kinase system was shown to be modulated by shear stress, and to be involved in other kinds of vascular remodeling. The aim of this study was to investigate the role of RhoA/Rho kinase in flow-related small artery remodeling. Rat mesenteric small arteries were subjected to flow-modifying surgery. After 1, 2, 4, 16, and 32 days, the animals were sacrificed and small arteries were harvested. Messenger RNA was isolated and amplified. Using cDNA microarray analysis, the differential expression of >14,000 genes was analyzed, part of which was confirmed by RT-PCR. In vivo treatment with fasudil (3 mg/kg/day s.c.) was used to test the effect of Rho kinase inhibition. The main findings are that: (1) blood flow alteration modified the expression of approximately 5% of the genes by >2-fold, (2) flow reduction downregulated many RhoA-related cytoskeletal markers of smooth muscle cell phenotype, (3) many RhoA-related genes were rapidly (<1 day) regulated and (4) fasudil treatment potentiated the inward hypotrophic remodeling in response to chronically reduced flow. These results indicate the importance of the RhoA/Rho kinase system in flow-related small artery remodeling.

Calcitonin gene-related peptide: exploring its vasodilating mechanism of action in humans.

OBJECTIVE: In vitro studies suggest that the vasodilator mechanism of action of calcitonin gene-related peptide (CGRP) involves various endothelium-dependent and endothelium-independent mechanisms. An in vivo analysis of the contribution of nitric oxide, prostaglandins, calcium-sensitive potassium channels (K(+)(Ca) channels), and adenosine triphosphate (ATP)-sensitive potassium channels (K(+)(ATP) channels) to CGRP-induced vasodilation in humans was performed. METHODS: CGRP (3, 10, and 30 ng x min(-1) x dL(-1) forearm) was infused into the brachial artery of 40 healthy subjects. Forearm vascular responses were measured by venous occlusion plethysmography. First, dose-response curves were constructed during coinfusion of CGRP with placebo (sodium chloride, 0.9%). After washout, in 5 subgroups (n = 8 each), the infusions of CGRP were repeated with placebo (time-control experiments), N(G)-monomethyl-L-arginine (L-NMMA, a nitric oxide-synthase inhibitor), indomethacin (a cyclooxygenase inhibitor), tetraethylammonium chloride (TEAC) (a K(+)(Ca)-channel blocker), and glyburide (INN, glibenclamide) (a K(+)(ATP)-channel blocker), respectively. RESULTS: CGRP induced a dose-dependent and reproducible decrease in forearm vascular resistance (P < .001). Compared with placebo, L-NMMA reduced the decrease in forearm vascular resistance induced by CGRP (P < .001) (3 and 10 ng x min(-1) x dL(-1) forearm). The absence of an inhibitory effect of L-NMMA on CGRP-induced vasodilation at the highest dose of CGRP suggests that still other mechanisms are involved. The vasodilator response to CGRP was not affected by coinfusion of indomethacin, tetraethylammonium chloride, or glyburide. CONCLUSIONS: The intrabrachial infusion of CGRP results in a dose-dependent and reproducible forearm vasodilator response. CGRP-induced vasodilation is dependent at least in part on the release of nitric oxide and does not involve the release of prostaglandins or the activation of K(+)(Ca) channels or K(+)(ATP) channels in humans.