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High Salt Intake (high + salt_intake)

Distribution by Scientific Domains
Medical Sciences75%

Selected Abstracts

Angiotensin II Is a Critical Mediator of Prazosin-Induced Angiogenesis in Skeletal Muscle

MICROCIRCULATION, Issue 6 2007
Matthew C. Petersen
ABSTRACT Objective: The purpose of this study was to determine whether a high-salt diet modulates physiological angiogenesis in skeletal muscle by altering angiotensin II (ANGII) and vascular endothelial growth factor (VEGF) levels. Methods: Sprague-Dawley rats were placed on a control diet (0.4% NaCl by weight) or high-salt diet (4.0% NaCl) prior to treatment with the vasodilator prazosin in the drinking water. In addition, a group of animals fed high salt were infused intravenously with ANGII at a low dose to prevent ANGII suppression by high salt, and a group of rats fed control diet were treated with the angiotensin II type I (AT1) receptor blocker losartan and prazosin. Results: Prazosin induced significant angiogenesis in the tibialis anterior muscle after 1 week of treatment. High-salt-fed rats demonstrated a complete inhibition of this angiogenic response. Maintenance of ANGII levels restored prazosin-induced angiogenesis in animals fed a high-salt diet. In addition, losartan treatment blocked prazosin-induced angiogenesis in animals on a control diet. Western blot analysis indicated that prazosin-induced angiogenesis was independent of changes in muscle levels of VEGF. Conclusions: This study demonstrates an inhibitory effect of high salt intake on prazosin-induced angiogenesis. Further, these results indicate that ANGII acting through the AT1 receptor is a critical pathway in this model of angiogenesis. [source]

Microvascular Structure and Function in Salt-Sensitive Hypertension

MICROCIRCULATION, Issue 4 2002
Dr. Matthew A. Boegehold
In many individuals with essential hypertension, dietary salt can further increase blood pressure by augmentation of an already elevated total peripheral resistance. There is little information on the microvascular changes that contribute to salt-sensitive hypertension in humans, but studies in the Dahl salt-sensitive rat have provided some knowledge of the microcirculation in this form of hypertension. These studies, most of which have used intravital microscopy or isolated vessel technology, are the focus of this review. The salt-induced exacerbation of hypertension in Dahl rats is due to a uniform increase in hemodynamic resistance throughout most of the peripheral vasculature. In the spinotrapezius muscle, this resistance increase is largely due to the intense constriction of proximal arterioles. The mechanisms responsible for this increased arteriolar tone include increased responsiveness to oxygen and a loss of tonic nitric oxide (NO) availability caused by reduced endothelial NO production and/or accelerated NO degradation by reactive oxygen species. Within the last decade, it has become increasingly clear that high salt intake can also lead to changes in microvascular structure and function in the absence of increased arterial pressure. This effect must also be considered when evaluating microvascular changes and their functional consequences in salt-sensitive hypertension. [source]

Maternal renal dysfunction in sheep is associated with salt insensitivity in female offspring

THE JOURNAL OF PHYSIOLOGY, Issue 1 2009
A. E. Brandon
To examine the programming effects of maternal renal dysfunction (created by subtotal nephrectomy in ewes prior to mating; STNx), renal and cardiovascular function were studied in 6-month-old male and female offspring of STNx and control pregnancies. After studies were conducted on a low salt diet (LSD) some female offspring underwent salt loading (0.17 m NaCl in the drinking water for 5,7 days; HSD). On LSD both male and female offspring of STNx had similar mean arterial pressures (MAP), heart rates, cardiac outputs and renal function to those measured in offspring of control ewes. In female STNx offspring on a HSD, plasma sodium levels increased and haematocrits fell, indicating volume expansion (P < 0.05). Plasma renin levels were not suppressed despite the increases in plasma sodium concentrations, but aldosterone levels were reduced. In control animals plasma renin levels fell (P < 0.05) but there was no change in plasma aldosterone concentrations. There was a positive relationship between GFR and MAP which was present only in female STNx offspring. In conclusion, in STNx offspring there was an impaired ability to regulate glomerular filtration independent of arterial pressure, renin release was insensitive to a high salt intake and control of aldosterone secretion was abnormal. This study provides evidence of abnormal programming of the renin,angiotensin system and glomerular function in offspring of pregnancies in which there is impaired maternal renal function. [source]

Interactions Between Sodium And Angiotensin

CLINICAL AND EXPERIMENTAL PHARMACOLOGY AND PHYSIOLOGY, Issue 12 2001
Trefor Morgan
SUMMARY 1. Increased sodium intake causes decreased formation of angiotensin (Ang) II and increased AngII causes increased Na+ retention. 2. Increased sodium intake and increased AngII causes cardiac hypertrophy, but decreased sodium intake regresses cardiac hypertrophy despite high AngII levels. Likewise, decreased Na+ and blockers of the renin,angiotensin system (RAS) in neonatal rats have similar effects on subsequent blood pressure development. 3. Cardiac hypertrophy due to renal hypertension does not regress when the RAS is blocked and rats are on a high salt intake. Likewise, sodium restriction alone does not cause regression; combination of reduced NaCl intake and RAS blockade is required. 4. High doses of perindopril and losartan in combination cause a syndrome in rats on 0.2% NaCl that leads to profound hypotension, polyuria, renal impairment and involution of the heart and death. This is reversed or prevented by a high (4%) NaCl intake, which also prevents the plasma angiotensinogen depletion that occurs with combined blockade on 0.2% NaCl intake. 5. Intake of NaCl and AngII interact at many levels. It is postulated that there is an important interaction at the cellular level that can explain the above events. [source]