Cigarette smoking impairs nitric oxide-mediated cerebral blood flow increase: Implications for Alzheimer's disease.

Cerebral blood flow is mainly regulated by nitrergic (parasympathetic, postganglionic) nerves and nitric oxide (NO) liberated from endothelial cells in response to shear stress and stretch of vasculature, whereas sympathetic vasoconstrictor control is quite weak. On the other hand, peripheral vascular resistance and blood flow are mainly controlled by adrenergic vasoconstrictor nerves; endothelium-derived NO and nitrergic nerves play some roles as vasodilator factors. Cigarette smoking impairs NO synthesis in cerebral vascular endothelial cells and nitrergic nerves leading to interference with cerebral blood flow and glucose metabolism in the brain. Smoking-induced cerebral hypoperfusion is induced by impairment of synthesis and actions of NO via endothelial nitric oxide synthase (eNOS)/neuronal NOS (nNOS) inhibition and by increased production of oxygen radicals, resulting in decreased actions of NO on vascular smooth muscle. Nicotine acutely and chronically impairs the action of endothelial NO and also inhibits nitrergic nerve function in chronic use. Impaired cerebral blood supply promotes the synthesis of amyloid ß that accelerates blood flow decrease. This vicious cycle is thought to be one of the important factors involving in Alzheimer's disease (AD). Quitting smoking is undoubtedly one of the important ways to prevent and delay the genesis or slow the progress of impaired cognitive function and AD.

Hyperhomocysteinemia impairs regional blood flow: involvements of endothelial and neuronal nitric oxide.

Increasing evidence support the idea that hyperhomocysteinemia (HHcy) is responsible for pathogenesis underlying cerebral, coronary, renal, and other vascular circulatory disorders and for hypertension. Impaired synthesis of nitric oxide (NO) in the endothelium or increased production of asymmetric dimethylarginine and activated oxygen species are involved in the impairment of vasodilator effects of NO. Impaired circulation in the brain derived from reduced synthesis and actions of NO would be an important triggering factor to dementia and Alzheimer's disease. Reduced actions of NO and brain hypoperfusion trigger increased production of amyloid-ß that inhibits endothelial function, thus establishing a vicious cycle for impairing brain circulation. HHcy is involved in the genesis of anginal attack and coronary myocardial infarction. HHcy is also involved in renal circulatory diseases. The homocysteine (Hcy)-induced circulatory failure is promoted by methionine and is prevented by increased folic acid and vitamin B6/B12. Eliminating poor life styles, such as smoking and being sedentary; keeping favorable dietary habits; and early treatment maintaining constitutive NOS functions healthy, reducing oxidative stresses would be beneficial in protecting HHcy-induced circulatory failures.

Recent advances in research on nitrergic nerve-mediated vasodilatation.

Cerebral vascular resistance and blood flow were widely considered to be regulated solely by tonic innervation of vasoconstrictor adrenergic nerves. However, pieces of evidence suggesting that parasympathetic nitrergic nerve activation elicits vasodilatation in dog and monkey cerebral arteries were found in 1990. Nitric oxide (NO) as a neurotransmitter liberated from parasympathetic postganglionic neurons decreases cerebral vascular tone and resistance and increases cerebral blood flow, which overcome vasoconstrictor responses to norepinephrine liberated from adrenergic nerves. Functional roles of nitrergic vasodilator nerves are found also in peripheral vasculature, including pulmonary, renal, mesenteric, hepatic, ocular, uterine, nasal, skeletal muscle, and cutaneous arteries and veins; however, adrenergic nerve-induced vasoconstriction is evidently greater than nitrergic vasodilatation in these vasculatures. In coronary arteries, neurogenic NO-mediated vasodilatation is not clearly noted; however, vasodilatation is induced by norepinephrine released from adrenergic nerves that activates ß1-adrenoceptors. Impaired actions of NO liberated from the endothelium and nitrergic neurons are suggested to participate in cerebral hypoperfusion, leading to brain dysfunction, like that in Alzheimer's disease. Nitrergic neural dysfunction participates in impaired circulation in peripheral organs and tissues and also in systemic blood pressure increase. NO and vasodilator peptides, as sensory neuromediators, are involved in neurogenic vasodilatation in the skin. Functioning of nitrergic vasodilator nerves is evidenced not only in a variety of mammals, including humans and monkeys, but also in non-mammals. The present review article includes recent advances in research on the functional importance of nitrergic nerves concerning the control of cerebral blood flow, as well as other regions, and vascular resistance. Although information is still insufficient, the nitrergic nerve histology and function in vasculatures of non-mammals are also summarized.

Obesity-induced cerebral hypoperfusion derived from endothelial dysfunction: one of the risk factors for Alzheimer's disease.

Increasing evidence supports the idea that chronic hypoperfusion in the brain is responsible for the pathogenesis underling Alzheimer's disease (AD). Obesity at midlife is associated with the risk of cognitive loss and AD at later life. Obesity decreases cerebral blood flow that is associated with decreased synthesis and actions of nitric oxide (NO) derived from the endothelium and also increases the production of oxidative stress. Increased plasma levels of asymmetric dimethylarginine decreases the production of NO by inhibiting NO synthase activity, leading to cerebral hypoperfusion and cognitive and neurodegenerative changes in AD. Adiponectin has a cerebroprotective action through an eNOSdependent mechanism. Obesity-induced endothelial dysfunction and cerebral hypoperfusion enhance the production of ß-amyloid that in turn impairs endothelial function; this vicious cycle promotes the pathogenic changes leading to AD. Interrupting this cycle by enhancement of NO-mediated cerebral blood flow is expected to promote prophylaxis against AD pathogenesis. This review summarizes recent advances in prophylactic or therapeutic measures, including physical exercise, nutritionally adequate dietary intake, pharmacological treatments such as acetylcholinesterase inhibitors and antioxidants, and bariatric surgery that are efficient in protecting and retarding the progress of cognitive failure and neurodegeneration.

Obesity impairs vasodilatation and blood flow increase mediated by endothelial nitric oxide: an overview.

Obesity dramatically increases the risk of development of cardiovascular and metabolic diseases. Endothelial dysfunction induced by obesity is an important risk factor that impairs blood flow controls in various organs. Impaired endothelial function occurs early in life in obese children. Obesity-induced endothelial dysfunction is associated with decreased nitric oxide (NO) production due to impaired endothelial NO synthase activity and expression and increased production of superoxide anion and the endogenous NOS inhibitor ADMA, together with increased vasoconstrictor factors, such as endothelin-1 and sympathetic nerve activation. Decreased endothelial progenitor cells are also involved in endothelial cell senescence in obese individuals. Insulin resistance and diabetes mellitus augment obesity-induced endothelial dysfunction. Adipokines liberated from adipose tissues play roles in modulating endothelial function; adiponectin and ghrelin have beneficial effects on endothelial cells. Effects of leptin on endothelial function are controversial. Decreased body weight by physical exercise, dietary interventions, and bariatric surgery are effective measures that reverse endothelial dysfunction; however, the weight control is not only the reason for improving of endothelia function. Pharmacological therapies with ß-adrenoceptor antagonists, resveratolol, anti-obesity agents, nifedipine, and NADPH oxidase inhibitors may also be effective; however, these treatments have to be utilized under the basis of exercise and dietary controls.

Regulation of myometrial circulation and uterine vascular tone by constitutive nitric oxide.

Pregnancy is a physiological state that involves an increase in uterine blood flow, which is mediated in part by nitric oxide (NO) liberated from the endothelium and nitrergic neurons. The main focus of this review article is to provide information about how endogenous NO regulates uterine and placental blood flow and vascular tone in experimental animals and humans in vivo or in vitro in non-pregnant and pregnant states as well as pregnancy with pre-eclampsia. Uterine arteries from non-pregnant women respond to NO liberated from the endothelium and nitrergic nerves with relaxations, and the release of endothelial NO is influenced by the phase of the estrous cycle, with its enhanced release at the follicular phase when the estrogen level is high. NO bioavailability in the uteroplacental circulatory system is gradually increased during pregnancy. Pre-eclamptic pregnancies with or without intrauterine growth restriction show impaired uteroplacental blood flow accompanied by reduced NO synthesis due to down-regulation of eNOS as well as asymmetric dimethylarginine accumulation and by augmented NO degradation by oxidative stress. Further studies are expected to provide new mechanistic insights into the fascinating process of maternal uterine adaptation in humans and novel prophylactic and therapeutic measures against pre-eclampsia.

Aldosterone affects blood flow and vascular tone regulated by endothelium-derived NO: therapeutic implications.

Aldosterone, in doses inappropriate to the salt status, plays an important role in the development of cardiovascular injury, including endothelial dysfunction, independent of its hypertensive effects. Acute non-genomic effects of aldosterone acting on mineralocorticoid receptors are inconsistent in healthy humans: vasoconstriction or forearm blood flow decrease via endothelial dysfunction, vasodilatation mediated by increased NO actions, or no effects. However, in studies with experimental animals, aldosterone mostly enhances vasodilatation mediated by endothelium-derived NO. Chronic exposure to aldosterone, which induces genomic responses, results in impairments of endothelial function through decreased NO synthesis and action in healthy individuals, experimental animals and isolated endothelial cells. Chronic aldosterone reduces NO release from isolated human endothelial cells only when extracellular sodium is raised. Oxidative stress is involved in the impairment of endothelial function by promoting NO degradation. Aldosterone liberates endothelin-1 (ET-1) from endothelial cells, which elicits ET(A) receptor-mediated vasoconstriction by inhibiting endothelial NO synthesis and action and through its own direct vasoconstrictor action. Ca(2+) flux through T-type Ca(2+) channels activates aldosterone synthesis and thus enhances unwanted effects of aldosterone on the endothelium. Mineralocorticoid receptor inhibitors, ET(A) receptor antagonists and T-type Ca(2) + channel blockers appear to diminish the pathophysiological participation of aldosterone in cardiovascular disease and exert beneficial actions on bioavailability of endothelium-derived NO, particularly in resistant hypertension and aldosteronism.

Cerebral blood flow regulation by nitric oxide in Alzheimer's disease.

Cerebral hypoperfusion due to impaired bioavailability of nitric oxide (NO) synthesized by endothelial nitric oxide synthase and neuronal nitric oxide synthase leads to cognitive decline and neurodegeneration in Alzheimer's disease (AD). Risk factors for endothelial dysfunction, such as inadequate lifestyle, cardiovascular/metabolic diseases, and aging, evokes cerebral hypoperfusion, impaired autoregulation, and increased production of amyloid-ß peptides (Aß) in association with vasculogenic memory loss and dementia. Decrease in parasympathetic nitrergic nerve activity also plays a role in cerebral hypoperfusion. Aß is a functional obstacle to NO-mediated vasodilatation; therefore, it decreases cerebral blood flow. Generation of reactive oxygen species by Aß is a major action in promoting NO degradation. Effective strategies for the prophylaxis or treatment of AD includes acetylcholinesterase inhibitors, drugs acting on the NO-cyclic GMP signaling pathway, antioxidants, peroxisome proliferator-activated receptor γ-agonists, and hydroxymethylglutaryl-CoA reductase inhibitors. Here our hypothesis about the mechanisms underlying the actions of acetylcholinesterase inhibitors in relation to NO-mediated cerebral blood flow is presented. Future detailed analyses of the relationship between cerebral blood flow regulation by constitutive NO and cognitive decline/neurodegeneration will provide clues for developing novel prophylactic measures and therapeutic means to alleviate AD.

Neurogenic and endothelial nitric oxide regulates blood circulation in lingual and other oral tissues.

Blood flow in oral tissues, including the tongue, salivary glands, gingiva, dental pulp, and lip, plays an important role in modulating the complex oral functions involved in food intake. Oral tissue circulation is regulated by nitric oxide (NO) synthesized by neuronal NO synthase mainly present in parasympathetic vasodilator neurons and also by endothelial NO sythase. Electrical stimulation of parasympathetic nerves causes vasodilatation and blood flow increase in the tongue, submandibular gland, and lip in various mammals in vitro and in vivo. Lingual arteries isolated from Japanese monkeys respond to perivascular nerve stimulation by electrical pulses and nicotine with relaxations that are mediated via neurogenic NO. There is evidence supporting the hypothesis that the superior salivatory nucleus delivers central information through the geniculate ganglion and greater petrosal nerve to the pterygopalatine ganglion, which sends off impulses through nitrergic nerves to oral tissues. Endothelial NO also plays an important role in improving oral blood circulation not only in resting conditions but also under conditions activated by chemical and physical stimuli in the tongue, submandibular and parotid glands, dental pulp/gingiva, and cheek pouch. Maintenance of health in oral circulation by minimizing factors responsible for impairment of endothelial and neurogenic NO bioavailability would be important for the prophylaxis of life-style related diseases.

Age-related changes in endothelial function and blood flow regulation.

Vascular endothelial dysfunction is regarded as a primary phenotypic expression of normal human aging. This senescence-induced disorder is the likely culprit underlying the increased cardiovascular and metabolic disease risks associated with aging. The rate of this age-dependent deterioration is largely influenced by the poor-quality lifestyle choice, such as smoking, sedentary daily life, chronic alcohol ingestion, high salt intake, unbalanced diet, and mental stress; and it is accelerated by cardiovascular and metabolic diseases. Although minimizing these detrimental factors is the best course of action, nonetheless chronological age steadily impairs endothelial function through reduced endothelial nitric oxide synthase (eNOS) expression/action, accelerated nitric oxide (NO) degradation, increased phosphodiesterase activity, inhibition of NOS activity by endogenous NOS inhibitors, increased production of reactive oxygen species, inflammatory reactions, decreased endothelial progenitor cell number and function, and impaired telomerase activity or telomere shortening. Endothelial dysfunction in regional vasculatures results in cerebral hypoperfusion triggering cognitive dysfunction and Alzheimer's disease, coronary artery insufficiency, penile erectile dysfunction, and circulatory failures in other organs and tissues. Possible prophylactic measures to minimize age-related endothelial dysfunction are also summarized in this review.

How mental stress affects endothelial function.

Mental stress is an important factor contributing to recognized mechanisms underlying cardiovascular events. Among these, stress-related endothelial dysfunction is an early risk factor that predicts future development of severe cardiovascular disorders. Acute mental stress by a variety of tests impairs endothelial function in humans, although the opposite results have been reported by some investigators. Chronic stress always deteriorates endothelial function in humans and experimental animals. Stress hormones, such as glucocorticoids and pro-inflammatory cytokines, and endothelin-1 liberated in response to mental stress participate in endothelial dysfunction possibly via downregulation of endothelial nitric oxide synthase (eNOS) expression, eNOS inactivation, decreased nitric oxide (NO) actions, and increased NO degradation, together with vasoconstriction counteracting against NO-induced vasodilatation. Catecholamines do not directly affect endothelial function but impair its function when blood pressure elevation by the amines is sustained. Endogenous opioids favorably affect endothelial function, which counteract deteriorating effects of other stress hormones and mediators. Inhibition of cortisol and endothelin-1 production, prevention of pro-inflammatory mediator accumulation, hypnotics, mirthful laughter, humor orientation, and lifestyle modification would contribute to the prevention and treatment for stress-related endothelial dysfunction and future serious cardiovascular disease.

Coronary hemodynamic regulation by nitric oxide in experimental animals: recent advances.

Nitric oxide (NO) formed via endothelial NO synthase (eNOS) plays crucial roles in the regulation of coronary blood flow through vasodilatation and decreased vascular resistance and in the inhibition of platelet aggregation and adhesion, leading to the prevention of coronary circulatory failure, thrombosis, and atherosclerosis. NO restrains myocardial oxygen consumption, when coronary perfusion is restricted. Endothelial function is impaired by pathogenic factors including smoking, excess salt intake, obesity, aging, hypercholesterolemia, hyperglycemia, and hypertension. The mechanisms involved in endothelial dysfunction are reduced NOS expression and activity, decreased NO bioavailability, and increased production of oxygen radicals and endogenous NOS inhibitors. NADPH oxidase, xanthine oxidase, and NOS uncoupling are involved in increased superoxide generation. Plasma levels of asymmetric dimethylarginine, the endogenous NOS inhibitor, are increased by an impairment of enzymatic degradation by dimethylarginine dimethylaminohydrolase and alanine-glyoxylate aminotransferase 2. Impairment of coronary arteriolar dilatation induced by perivascular nitrergic nerve activation is involved in decreased coronary blood flow. NO derived from nNOS singly or in combination with eNOS protects against serious myocardial injury through ischemic insults. Ischemia-induced iNOS upregulation contributes to myocardial contractile dysfunction. Preventive and therapeutic measures, such as improvement of life-style and treatment with therapeutic agents, to eliminate pathogenic factors for endothelial dysfunction or nNOS-derived NO deprivation would be quite important for the prophylaxis and minimizing the development of coronary artery disease.

Salt-induced hemodynamic regulation mediated by nitric oxide.

Excess daily salt intake impairs vasodilatation and enhances vasoconstriction, resulting in reduction of regional blood flow and elevation of blood pressure in healthy individuals and hypertensive patients with either salt sensitivity or not tested for salt sensitivity or not evaluated for salt sensitivity. The mechanism may involve decreased production of nitric oxide via endothelial nitric oxide synthase (eNOS), impaired bioavailability of nitric oxide, and elevated plasma levels of asymmetric dimethylarginine (ADMA). Experimental animals, irrespective of salt sensitivity, although less extensive in those with salt-resistance, fed a high-salt diet have deteriorated endothelial functions; the mechanisms involved include an impairment of eNOS activation, a decrease in eNOS expression, and an increase in oxidative stress and ADMA. The imbalance of interactions between nitric oxide and angiotensin II is also involved in salt sensitivity. Deficiency of nitric oxide formed via neuronal NOS and inducible NOS may contribute to salt-induced hypertension. Reduced daily salt intake, therefore, would be the most rational prophylactic measure against the development of hypertension.

Nitric oxide-mediated coronary flow regulation in patients with coronary artery disease: recent advances.

Nitric oxide (NO) formed via endothelial NO synthase (eNOS) plays crucial roles in the regulation of coronary blood flow through vasodilatation and decreased vascular resistance, and in inhibition of platelet aggregation and adhesion, leading to the prevention of coronary circulatory failure, thrombosis, and atherosclerosis. Endothelial function is impaired by several pathogenic factors including smoking, chronic alcohol intake, hypercholesterolemia, obesity, hyperglycemia, and hypertension. The mechanisms underlying endothelial dysfunction include reduced NO synthase (NOS) expression and activity, decreased NO bioavailability, and increased production of oxygen radicals and endogenous NOS inhibitors. Atrial fibrillation appears to be a risk factor for endothelial dysfunction. Endothelial dysfunction is an important predictor of coronary artery disease (CAD) in humans. Penile erectile dysfunction, associated with impaired bioavailability of NO produced by eNOS and neuronal NOS, is also considered to be highly predictive of ischemic heart disease. There is evidence suggesting an important role of nitrergic innervation in coronary blood flow regulation. Prophylactic and therapeutic measures to eliminate pathogenic factors inducing endothelial and nitrergic nerve dysfunction would be quite important in preventing the genesis and development of CAD.

Modulation of renal blood flow and vascular tone by neuronal nitric oxide synthase-derived nitric oxide.

Nitric oxide (NO) formed via neuronal nitric oxide synthase (nNOS) in renal vasculature and tissues and in the brain plays an important role in controlling renal hemodynamics, renal function, and systemic blood pressure. Activation of parasympathetic nitrergic nerves innervating renal vasculature contributes to vasodilatation in renal arteries and pre- and postglomerular arterioles, an increase in renal blood flow, and a decrease in vascular resistance. NO released from autonomic nitrergic nerves interferes with the release of norepinephrine from adrenergic nerve terminals or the amine actions on smooth muscle. The pre- or postjunctional mechanisms of NO actions participate in vasodilatation through a diminution of sympathetic vasoconstrictor influence. On the other hand, NO from neurons in the brain acts on the paraventricular nucleus of the hypothalamus and the rostral ventrolateral medulla and inhibits the central sympathetic nerve activity to the kidney, leading to renal vasodilatation and increased renal blood flow. The present article summarizes information concerning the renal blood flow and vascular tone through nNOS-derived NO produced in peripheral autonomic nerves and the brain. The nNOS-derived NO-cyclic GMP pathway would be an important target for the treatment of renal circulatory dysfunction and chronic kidney disease.

Nitric oxide-mediated blood flow regulation as affected by smoking and nicotine.

Cigarette smoking is a major risk factor for atherosclerosis, cerebral and coronary vascular diseases, hypertension, and diabetes mellitus. Chronic smoking impairs endothelial function by decreasing the formation of nitric oxide and increasing the degradation of nitric oxide via generation of oxygen free radicals. Nitric oxide liberated from efferent nitrergic nerves is also involved in vasodilatation, increased regional blood flow, and hypotension that are impaired through nitric oxide sequestering by smoking-induced factors. Influence of smoking on nitric oxide-induced blood flow regulation is not necessarily the same in all organs and tissues. However, human studies are limited mainly to the forearm blood flow measurement that assesses endothelial function under basal and stimulated conditions and also determination of penile tumescence and erection in response to endothelial and neuronal nitric oxide. Therefore, information about blood flow regulation in other organs, such as the brain and placenta, has been provided mainly from studies on experimental animals. Nicotine, a major constituent of cigarette smoke, acutely dilates cerebral arteries and arterioles through nitric oxide liberated from nitrergic neurons, but chronically interferes with endothelial function in various vasculatures, both being noted in studies on experimental animals. Cigarette smoke constituents other than nicotine also have some vascular actions. Not only active but also passive smoking is undoubtedly harmful for both the smokers themselves and their neighbors, who should bear in mind that they can face serious diseases in the future, which may result in lengthy hospitalization, and a shortened lifespan.

Vascular actions of nitric oxide as affected by exposure to alcohol.

Vasodilator substances liberated from endothelial cells, mainly nitric oxide (NO), play important roles in physiologically regulating blood flow and blood pressure and preventing pathological vascular damage. Impairment of these actions promotes the genesis of cardiovascular diseases such as hypertension, cerebral and cardiac hypoperfusion, impaired vasodilatation and atherosclerosis. Low concentrations of alcohol induce increased release of NO from the endothelium due to activation and expression of NO synthase (NOS). In contrast, administration of high concentrations of alcohol or its chronic ingestion impairs endothelial functions in association with reduced NO bioavailability. The endogenous NOS inhibitor asymmetric dimethylarginine may participate in decreased synthesis of NO. Chronic alcohol intake also impairs penile erectile function possibly by interfering with endothelial, but not nitrergic nerve, function. This review article summarizes the vascular actions of NO derived from endothelial and neuronal NOS as affected by alcohol, other than wine, and acetaldehyde in healthy individuals, human materials and various experimental animals.

Alteration of nitric oxide-mediated blood flow regulation in diabetes mellitus.

Nitric oxide (NO) formed via endothelial NO synthase (eNOS) and neuronal NO synthase (nNOS) plays crucial roles in the regulation of blood flow through vasodilatation and decreased vascular resistance in various organs and tissues. NO derived from eNOS also contributes to the inhibition of platelet aggregation, adhesion, and smooth muscle proliferation and acts as an antiatherosclerotic agent. Endothelial and autonomic nitrergic nerve functions are impaired in experimental animals and patients with diabetes mellitus, resulting in regional blood flow decrease. Such a pathological phenomenon is caused by reduced NOS expression and activity and/or NO availability, increased production of reactive oxygen species and endogenous NOS inhibitors, and also increased actions of vasoconstrictor factors. Endothelial and nitrergic nerve dysfunction under diabetic conditions interferes with blood flow in the brain, eye, heart, kidney, skeletal muscle, skin, and penile tissues, where similar or different mechanisms underlying the dysfunction have been evidenced. NO formed via immunological (inducible) NOS seems to deteriorate regional circulation. The present article describes and discusses alterations of NO-mediated blood flow regulation by type I and type II diabetes in experimental animals and humans.