Hypertension and Cerebrovascular Dysfunction

Summary

Introduction

Hypertension is one of the major health problems of the western world. Hypertension, defined as elevations in blood pressure above 140 mmHg systolic or 90 mmHg diastolic, afflicts 25% of the general population and is the premier risk factor for serious diseases affecting brain, heart and kidneys (Messerli et al., 2007). Although much is known about the mechanisms controlling blood pressure, a specific cause for hypertension can be ascertained only in a minority of patients. Therefore, in most instances a cause for the elevated blood pressure cannot be found, hence the term “essential hypertension”. Fortunately, a wide variety of treatments are available to lower blood pressure, and their use has reduced the disease burden caused by hypertension (Messerli et al., 2007). Furthermore, a better understanding is emerging of how hypertension induces damage in susceptible organs, raising the possibility of organ-specific therapies (Messerli et al., 2007).

The brain is a major target of the deleterious effects of hypertension and is responsible for a large portion of the related mortality and morbidity (Dahlof, 2007). Hypertension is the number one risk factor for stroke and is a leading cause of cognitive decline and dementia (Dahlof, 2007) (fig. 1). There is a linear relationship between blood pressure and stroke mortality, and in patients with treated hypertension a 1 mmHg increase in systolic blood pressure increases stroke deaths by 2% (Palmer et al., 1992). Furthermore, hypertension is a powerful risk factor for Alzheimer’s disease (AD) (fig. 1), the most common cause of dementia in the elderly (Kelley and Petersen, 2007). Recent advances in neurovascular regulation and in the pathobiology of hypertension have led to a deeper understanding of how hypertension disrupts the cerebral blood supply. These new findings provide the opportunity for the present reappraisal of the cerebrovascular effects of hypertension.

Figure 1

Hypertension, stroke and dementia

The cerebral blood supply

The intracranial cerebral arteries take off from the circle of Willis at the base of the brain and give rise to progressively smaller vessels traveling on the brain surface. These surface vessels, termed pial arteries, branch out into smaller vessels, which penetrate into the substance of the brain and give rise to arterioles and capillaries. Like elsewhere in the body, brain blood vessels are lined with endothelial cell. Arteries and arterioles have one or more layers of smooth muscle cells (myocytes), contractile cells that regulate vascular diameter. In capillaries, myocytes are replaced by pericytes. Cerebral arteries and arterioles are innervated by nerve fibers arising from cranial autonomic and sensory ganglia (Iadecola and Nedergaard, 2007). Smaller arterioles (≤100µm) and capillaries are fully enveloped by the end feet processes of astrocytes (Iadecola and Nedergaard, 2007). Owing to the blood-brain barrier (BBB), cerebral capillaries are impermeable to most blood-borne substances (Zlokovic, 2008). Unlike other organs, extraparenchymal arteries and arterioles account for 2/3 of the vascular resistance, while intracerebral arterioles and capillaries account for the remaining 1/3 (Faraci and Heistad, 1990). Therefore, vessels residing outside the brain have the greatest impact on parenchymal blood flow.

Adaptive responses of the cerebral circulation

The brain has limited fuel reserves and its integrity depends on a continuous supply of oxygen and energy substrates delivered through blood flow. Thus, cerebral blood vessels are endowed with adaptive mechanisms that assure that the brain receives an adequate amount of blood at all times (fig. 2). The major control mechanisms relevant to the cerebrovascular effects of hypertension are briefly examined below.

Figure 2

The neurovascular unit and adaptive responses of the cerebral circulation

Cerebrovascular autoregulation

Cerebrovascular autoregulation renders CBF independent of changes in arterial pressure within a certain range, about 60–150 mmHg mean arterial pressure (Cipolla, 2007; Paulson et al., 1990)(fig. 2, fig. 4A). Arterial pressure varies markedly during normal daily activities (Mancia et al., 1988) and these changes may lead to potentially dangerous increases or decreases in CBF. To counteract the effects of blood pressure variations on CBF, cerebral arterioles adjust their resistance according to intravascular pressure. Thus, arterioles constrict when the pressure increases and relax when the pressure decreases. Autoregulation is related to the ability of arterial myocytes to constrict when intravascular pressure rises (myogenic response) (Brayden et al., 2008). The myogenic response stems from the fact that an increase in intravascular pressure depolarizes arterial myocytes, leading to Ca²⁺ influx and vasoconstriction (Brayden et al., 2008). In addition to Ca²⁺ influx, Ca²⁺ sensitization of the smooth muscle contractile apparatus via protein kinase C (PKC) and Rho kinase also plays a role (Brayden et al., 2008; Chrissobolis and Sobey, 2006).

Figure 4

A. Cerebrovascular autoregulation: CBF is maintained relatively constant despite changes in arterial pressure within a certain range (60 to 150 mmHg mean arterial pressure). Hypertension shifts the curve to the right, so that higher levels of blood pressure ...

Hypertension alters the structure of cerebral blood vessels

Atherosclerosis and lipohyalinosis

Hypertension promotes formation of atherosclerotic plaques in cerebral arteries and arterioles, which may lead to arterial occlusions and ischemic injury (Dahlof, 2007; Lammie, 2002)(fig. 3). In addition, hypertension induces fibrinoid necrosis (lipohyalinosis) of penetrating arteries and arterioles supplying the white matter, resulting in small white matter infarcts (lacunes) or brain hemorrhage (Lammie, 2002) (fig. 3).

Figure 3

Effect of hypertension on the cerebral blood vessels

Hypertrophy, remodeling and stiffening

Hypertension induces adaptive changes in systemic and cerebral arteries known as hypertrophic and eutrophic remodeling. In hypertrophic remodeling smooth muscle cells undergo hypertrophy or hyperplasia, and grow inward encroaching into the lumen of the artery. This process increases the wall thickness and reduces the lumen of the vessel (Baumbach and Heistad, 1988). In eutrophic remodeling smooth muscle cells undergo a rearrangement that leads to a reduction of the vessel lumen without changes in total vascular mass or wall thickness (Baumbach and Heistad, 1988). Hypertension also leads to vascular stiffening, a process that increases collagen content and rigidity of the vessel wall (Baumbach and Heistad, 1988).

Several factors contribute to hypertrophy in cerebral arteries and arterioles. The sympathetic perivascular innervation, which exerts a trophic effect on the vascular wall, is required for the development of cerebrovascular hypertrophy (Baumbach et al., 1989). Furthermore, mechanical effects of the elevated intravascular pressure on the vascular wall play a role through growth factors, oxidative stress and NO (Harrison et al., 2006; O'Callaghan and Williams, 2000). Reduced availability of NO, an agent with antiproliferative activity, leads to hyperthophy, as indicated by the vascular growth observed with NOS inhibition or in eNOS-null mice (Table). Interestingly, in eNOS-null mice, which have elevated blood pressure, hyperthrophy persists even if the increase in cerebrovascular pressure is prevented by ligation of the ipsilateral carotid artery (Baumbach et al., 2004). Furthermore, in mice lacking the homocysteine metabolism enzyme cystationine-β synthase or the ROS scavenger enzyme Cu-Zn-superoxide dismutase hypertrophy develops in the absence of hypertension (Table). Therefore, hypertrophy can occur without elevations in intravascular pressure, indicating that mechanical effects on the vascular wall are not an absolute requirement.

Table

Cerebrovascular remodeling and hypertrophy in mouse models relevant to hypertension

Angiotensin II (AngII) has emerged as a key factor in the mechanisms of cerebrovascular remodeling (Schiffrin and Touyz, 2004). Treatment of spontaneously-hypertensive rats with angiotensin converting enzyme inhibitors attenuates remodeling independently of effects on blood pressure (Chillon and Baumbach, 1999). Hypertensive mice overexpressing human renin and angiotensinogen (R+/A+) exhibit both hypertrophy and remodeling, whereas BPH-2 mice, in which hypertension is not related to AngII, exhibit only hypertrophy (Table). ROS participate in the remodeling of cerebral blood vessels induced by AngII (Schiffrin and Touyz, 2004). ROS promote smooth muscle cell proliferation and initiate remodeling of the extracellular matrix via activation of matrix metalloproteases (MMP) (Flamant et al., 2007). Extracellular matrix proteins play a critical role in hypertrophy, remodeling and stiffening. AngII-induced hypertension is associated with activation of MMP and breakdown of matrix proteins (Flamant et al., 2007). Antagonists of the integrin ανβ3 prevent arterial remodeling in mesenteric arteries of renin overexpressing rats (Heerkens et al., 2007). In addition, mice lacking elastin-1 develop vascular stiffening and hypertension (Faury et al., 2003). Similarly, deficiency of the vascular matrix protein emilin-1 leads to increased vascular resistance and hypertension (Zacchigna et al., 2006). Therefore, mechanical, neural and humoral factors contribute to the changes in cerebrovascular wall structure and composition induced by hypertension.

Hypertrophy and remodeling are adaptive responses aimed at reducing stress on the vessel wall and protecting downstream microvessels from the effect of increased pressure (Baumbach and Heistad, 1988; Laurent et al., 2005). Failure of this protective mechanism leads to BBB alterations, cerebral edema and cerebrovascular pathology. Thus, ablation of perivascular sympathetic nerves early in life prevents cerebrovascular hypertrophy in stroke-prone spontaneously hypertensive rats and promotes the development of cerebrovascular lesions (Sadoshima et al., 1983). Similarly, the cerebrovascular alterations associated with eclampsia may be related to the lack of hypertrophy or remodeling during pregnancy (Cipolla, 2007). On the other hand, remodeling of systemic or cerebral vessels is potentially damaging because it reduces the vessel’s lumen and increases vascular resistance resulting in a greater propensity for vascular insufficiency (Barry, 1985; Mathiassen et al., 2007) (see next section). Arterial stiffening is also deleterious because it leads to increases in pulse pressure, a good predictor of stroke and cognitive impairment (Benjo et al., 2007; Waldstein et al., 2008).

The relationships among stiffening, hypertrophy and remodeling are poorly understood (Laurent et al., 2005). Cerebral arterioles undergoing hypertrophy or remodeling have reduced stiffening (Baumbach et al., 2003; Chillon and Baumbach, 1999). However, if hypertension is sustained the changes in vascular wall composition may lead to reduced distensibility and stiffening (Izzard et al., 2006). Therefore, duration and magnitude of the blood pressure elevation, as well as vessel size are important determinants of the alteration in the vascular wall induced by hypertension.

In summary, hypertension has profound effects on the structure of cerebral blood vessels. While atherosclerosis and lipohyalinosis may lead to vascular occlusions, rearrangement of the cellular architecture and changes in the composition of the vascular wall alters the mechanical and hemodynamic properties of the vessels. The functional implications of these structural changes are examined in the next section.

Hypertension alters resting CBF and disrupts adaptive responses of the cerebral circulation

Oxidative stress is a critical factor in the cerebrovascular effects of hypertension

Increasing evidence suggests that oxidative stress is involved in the deleterious effects of hypertension. In humans, systemic markers of oxidative stress are increases in essential hypertension, renovascular hypertension, malignant hypertension and preeclampsia (Touyz, 2004). Oxidative stress in brain and cerebral blood vessels plays a central role in the mechanisms of hypertension and its cerebrovascular effects. In models of hypertension, ROS production is elevated in central autonomic regions implicated in blood pressure control (see (Peterson et al., 2006) for a review). ROS production within these brain regions contributes to the neurohumoral changes that drive the hypertension (Peterson et al., 2006). In addition, hypertension induces oxidative stress in cerebral blood vessels. In models of AngII-induced hypertension, ROS production increases in large and small cerebral vessels, including pial arterioles (Didion et al., 2005; Girouard et al., 2006, 2007; Kazama et al., 2004). Free radical scavengers prevent the effects of hypertension on functional hyperemia and endothelium-dependent responses, indicating that the cerebrovascular dysfunction is mediated by ROS (Didion et al., 2005; Girouard et al., 2006; Kazama et al., 2004).

Hypertension and Alzheimer’s disease

AD has traditionally been considered a neurodegenerative condition caused by neuronal dysfunction resulting from brain accumulation of amyloid-β (amyloid plaques) and neuronal cytoskeletal abnormalities (neurofibrillary tangles) (Kelley and Petersen, 2007). However, epidemiological, pathological and experimental evidence suggests that vascular factors, including hypertension, play a significant role in the pathogenesis of AD (see (Iadecola, 2004) for a review). In particular, midlife hypertension increases the risk of AD later in life and accelerates the progression of AD (see (Skoog and Gustafson, 2006) for a review). Furthermore, brain atrophy, amyloid plaques and neurofibrillary tangles are increased in the brain of patients with a history of midlife hypertension (Skoog and Gustafson, 2006). AD patients have white matter lesions resembling those associated with hypertension, and if these lesions coexist with amyloid plaques they produce cognitive deficits greater than those predicted based on the AD pathology alone (Sheng et al., 2007; Snowdon et al., 1997). A proportion of patients with AD also have ischemic brain lesions and AD patients have more severe atherosclerosis in cerebral arteries than non demented controls (Roher et al., 2003; Skoog and Gustafson, 2006). Studies in mouse models of AD have demonstrated that amyloid-β disrupts the function of cerebral blood vessels (Iadecola, 2004). Amyloid-β attenuates functional hyperemia and endothelium-dependent responses (Iadecola et al., 1999; Niwa et al., 2000), and impairs cerebrovascular autoregulation (Niwa et al., 2002). Interestingly, the mechanisms of amyloid-β-induced cerebrovascular dysfunction are similar to those of AngII and involve NADPH oxidase-derived ROS. Thus, mice lacking Nox2 are protected from the deleterious cerebrovascular and cognitive effects of brain amyloid-β accumulation (Park et al., 2008b). Hypertension could promote AD by increasing the production of the amyloid-β peptide. This possibility is supported by the finding that cerebral hypoxia-ischemia, which can occur with hypertension, facilitates the cleavage of amyloid-β from its precursor protein and increase the brain’s amyloid-β burden (Sun et al., 2006). Furthermore, the brain deposition of circulating amyloid-β is increased in models of hypertension, suggesting another mechanism by which hypertension could increase brain amyloid-β (Gentile et al., 2008). However, in the years immediately preceding the onset of dementia blood pressure begins to decrease in AD patients and continues to decline during the course of the illness (Skoog and Gustafson, 2006). Because autoregulation is impaired by amyloid-β, hypotension is likely to cause cerebral hypoperfusion, which, in turn, can enhance amyloid-β cleavage and deposition (Bennett et al., 2000).

The biological bases of the reciprocal interaction between AD and hypertension remain unclear. It is unlikely that AD pathology, i.e., plaques and tangles, causes the elevation in arterial pressure, because hypertension occurs decades before the onset of symptoms. Although AD has a long presymptomatic period, this preclinical phase is not likely span over several decades (Kelley and Petersen, 2007). Therefore, hypertension may precede AD pathology and, as such, could have a role in the pathogenesis of the disease. On the other hand, the reduction in arterial pressure that occurs when AD is fully developed is more likely to be related to pathological changes in central autonomic nuclei controlling blood pressure, such as the C1 area of the rostral ventrolateral medulla (Burke et al., 1994). The reduction in physical activity, dehydration and malnutrition associated with severe dementia could also contribute to the decrease in blood pressure (Skoog and Gustafson, 2006). Therefore, while hypertension may promote the development of amyloid plaques early in the course of the disease, the pathological changes induced by AD lead to a reduction in arterial pressure in the late phase. The hypotension, in turns, may produce hypoxia-ischemia, which acts synergistically with AD pathology to worsen the dementia.

Challenges and opportunities

Great progress has been made in understanding the biological bases of hypertension and the mechanisms underlying its powerful effects on the brain circulation. Although these developments have unveiled new avenues for the treatment of the devastating effects of hypertension on the brain, they also have raised new questions that remain to be addressed. For example, the effects of blood pressure control on stroke risk are well documented and emerging data suggest that controlling blood pressure reverses some of the effects of hypertension on cerebral blood vessels and ameliorates cognition (Peila et al., 2006). Therefore, treatment of elevated blood pressure remains the mainstay of preventive approaches to protect the brain and the other organs from hypertension (Dahlof, 2007; Messerli et al., 2007). In addition, considering the role of hypertension in amyloid-β neuropathology, controlling hypertension may be valuable for AD prevention as well (Skoog and Gustafson, 2006). However, questions remain about the “ideal” blood pressure that should be achieved in hypertensive patients. The linear relationship between stroke mortality and blood pressure suggests that the lower the value the better the outcome, but excessive lowering of diastolic blood pressure may increase the incidence of periventricular white matter lesions (van Dijk et al., 2004). This is clearly an area that requires further investigation.

Another question concerns whether all blood pressure lowering agents are equivalent or whether specific agents may afford brain protection beyond that achieved by their antihypertensive effect. In clinical trials, angiotensin converting enzyme inhibitors or AT1 receptor antagonists conferred greater protection against stroke or dementia than treatment with other agents despite comparable blood pressure lowering (Dahlof, 2007; Messerli et al., 2007). This finding is consistent with the experimental observation that some of the cerebrovascular effects of AngII are independent of the blood pressure elevation (Chillon and Baumbach, 1999; Kazama et al., 2003), raising the possibility that the deleterious effects of AngII on the cerebral circulation are not secondary to the effect of this peptide on systemic blood pressure. However, some studies have failed to observe a benefit of agents targeting the renin-angiotensin system versus other antihypertensive treatments (Messerli et al., 2007; Staessen et al., 2007). Therefore, more data are needed on the effects of antagonists of the renin-angiotensin system and other antihypertensive agents in the prevention of the cerebral complications of hypertension. Interestingly, the AT1 receptor antagonist valsartan reduces amyloid plaques in a mouse model of AD and improves behavioral performance without altering arterial pressure (Wang et al., 2007). Furthermore, Rho kinase inhibitors and statins could also have a role in the treatment of the deleterious effects of hypertension on the brain (Chrissobolis and Sobey, 2006). Like AT1 receptor inhibitors, these agents are attractive because they also have neuroprotective effects against ischemia and amyloid-β pathology (Chrissobolis and Sobey, 2006; Mueller et al., 2005). Therefore, the choice of the antihypertensive agents used may also be important in the prevention of stroke and dementia.

Animal studies have demonstrated that ROS have a prominent role in the pathogenic effects of hypertension on the brain and other organs, yet free radical scavengers have failed to provide a benefit in cardiovascular diseases and stroke (Griendling and FitzGerald, 2003). The finding that NADPH oxidase is the major source of the ROS involved in the cerebrovascular effects of hypertension suggests that treatments targeting this enzyme would be effective. However, in light of the role of NADPH oxidase in immune defense, chronic inhibition of NADPH oxidase is not a viable strategy. Thus, approaches to selectively inhibit NADPH oxidase-dependent ROS production in vascular cells need to be developed. A greater understanding of the cellular and molecular features of vascular NADPH oxidase is needed to develop pharmacological strategies for its selective inhibition.

The fact that PPARγ may serve as an endogenous cerebrovasoprotective system (Halabi et al., 2008), suggests that PPARγ activators, such as thiazolidinediones used in the treatment of type 2 diabetes, could have therapeutic potential in the deleterious effects of hypertension. However, recent meta-analyses indicate that PPARγ activators increase the risk of cardiovascular events (Nissen and Wolski, 2007). Therefore, the role of PPARγ in cardiovascular and cerebrovascular diseases needs further scrutiny.

Better animal models of essential hypertension are needed to address some questions still outstanding (Lerman et al., 2005). In particular, models that allow investigators to introduce genetic manipulations in a temporally defined and cell specific fashion would be highly desirable. Furthermore, models that combine other vascular risk factors, such as aging, gender, diabetes, hyperhomocysteinemia, hyperlipidemia, etc., would be useful by reflecting more closely the context in which the human disease occurs.

Acknowledgments

Footnotes

Contributor Information

Costantino Iadecola, Division of Neurobiology, Department of Neurology and Neuroscience, Weill Cornell Medical College, New York, NY.

Robin L. Davisson, Department of Biomedical Sciences, College of Veterinary Medicine, Cornell University, Ithaca, NY, and Department of Cell and Developmental Biology, Weill Cornell Medical College, New York, NY.

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