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(Stroke. 2005;36:1077.)
© 2005 American Heart Association, Inc.

Original Contributions

Critical Role of Angiotensin II in Excess Salt-Induced Brain Oxidative Stress of Stroke-Prone Spontaneously Hypertensive Rats

Shokei Kim-Mitsuyama; Eiichiro Yamamoto; Tomoko Tanaka; Yumei Zhan; Yasukatsu Izumi; Yasuhiro Izumiya; Takeshi Ioroi; Hideki Wanibuchi Hiroshi Iwao

From the Department of Pharmacology and Molecular Therapeutics (S.K.-M., E.Y., T.T.), Kumamoto University Graduate School of Medical Sciences, Kumamoto, Japan; and Departments of Pharmacology (Y.Z., Y. Izumi, Y. Izumiya, T.I., H.I.) and Pathology (H.W.), Osaka City University Graduate School of Medical Science, Osaka, Japan.

Correspondence to Shokei Kim-Mitsuyama, MD, PhD, Department of Pharmacology and Molecular Therapeutics, Kumamoto University Graduate School of Medical Sciences, 1-1-1 Honjyo, Kumamoto 860-8556, Japan. E-mail kimmitsu{at}gpo.kumamoto-u.ac.jp

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
Background and Purpose— The detailed role of angiotensin II in salt-exacerbated stroke is unclear. We examined the role of angiotensin II in salt-accelerated stroke of stroke-prone spontaneously hypertensive rats (SHRSP).

Methods— Salt-loaded SHRSP were orally given the angiotensin II type 1 (AT1) receptor blocker candesartan (0.3 to 3 mg/kg per day) and calcium channel blocker amlodipine (1 mg/kg per day), and the effects on stroke (n=61) and brain superoxide were compared between them. We also examined the effect of angiotensin II infusion (200 ng/kg per min) on brain superoxide production and blood–brain barrier.

Results— Despite the comparable hypotensive effect between candesartan and amlodipine, candesartan prolonged survival of salt-loaded SHRSP much more than amlodipine (P<0.01), being associated with more improvement of cerebral arteriolar thickening, cerebral arteriolar cell proliferation, and hippocampal CA1 neuronal cell reduction (1024.9±20.6 versus 724.9±22.8 cells/mm²; P<0.01; n=7 to 10 in each group) in SHRSP by candesartan (P<0.05) than amlodipine. Salt loading increased superoxide and NADPH oxidase activity in brain cortex and hippocampus of SHRSP, and this increase was prevented by candesartan (P<0.01) but not amlodipine. Angiotensin II infusion, via AT1 receptor, directly increased brain superoxide by 1.8-fold (P<0.05; n=6 to 7 in each group) and impaired blood–brain barrier in salt-loaded SHRSP by 1.7-fold (P<0.05), and this increase in brain superoxide and blood–brain barrier impairment was prevented by tempol as well as candesartan.

Conclusion— Excess salt, via oxidative stress, accelerates stroke, and angiotensin II, via AT1 receptor, plays a pivotal role in brain superoxide production of SHRSP by excess salt.

Key Words: angiotensins • blood–brain barrier • stroke

	Introduction

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Stroke-prone spontaneously hypertensive rats (SHRSP) are regarded as a useful model of human hypertensive encephalopathy.¹ Excess salt intake has the pathologic effect on cardiovascular disease and stroke via not only blood pressure elevation but also unknown mechanisms.^2,3 Indeed, salt loading in SHRSP accelerates severe hypertension and hypertensive encephalopathy.^4–6 However, the mechanism by which excess salt accelerates stroke remains to be elucidated. Renin-angiotensin inhibitors, such as angiotensin-converting enzyme inhibitor^5–8 or angiotensin II type 1 (AT1) receptor blocker (ARB),^4,7,8 prevent hypertensive encephalopathy in salt-loaded SHRSP, although the detailed mechanism is unclear. In this study, under the small hypotensive effect, we compared the efficacy of ARB on encephalopathy of salt-loaded SHRSP with that of equihypotensive dose of calcium channel blocker to elucidate the mechanism underlying the beneficial effect of ARB.

	Materials and Methods

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Animals
Male SHRSP (n=235) were purchased from Japan SLC (Shizuoka, Japan). All procedures were in accordance with institutional guidelines for the care and use of laboratory animals.

Effect of Candesartan and Amlodipine on Survival Rate
SHRSP rats were fed a 0.3% NaCl diet until 8 weeks of age, and then the diet was switched to 8% NaCl diet. Eleven-week-old SHRSP, fed a high-salt diet, were given vehicle (0.5% carboxymethyl cellulose), an ARB, candesartan (Takeda Chemical Industries, Ltd)⁹ at the dose of 0.3, 1, or 3 mg/kg per day, or a calcium channel blocker, amlodipine (Pfizer), at 1 mg/kg per day by gastric gavage. Blood pressure was measured by the tail-cuff method.

Effects on Cerebral Arteriolar Thickening, Arteriolar Cell Proliferation, and Hippocampal Neuronal Cells
After 6 weeks of treatment with candesartan or amlodipine, salt-loaded SHRSP were anesthetized with ether and perfused with 10% formalin as described.¹⁰ After perfusion, the whole brain was excised, sliced into 5 coronal sections, fixed with 10% formalin overnight, embedded in paraffin, and cut into 4-µm-thick sections. For measurement of cerebral arteriolar thickening, sections were immunostained with anti–-smooth muscle actin antibody (DAKO), as described.¹¹ Cross-sectional area of the hippocampal arteriolar wall was determined by means of a light microscope connected to the image-analyzing system IPAP (Sumika Technos Corp.) as described.¹⁰ For measurement of hippocampal arteriolar cell proliferation, sections were immunostained with anti–proliferating cell nuclear antigen (PCNA) antibody (DAKO), as described,¹¹ and the percentage of PCNA-positive cells to total arteriolar cells was determined. For counting hippocampal CA1 area neuronal cells, sections were stained with Nissl, and neurons in the zone of the CA1 area were counted under a light microscope as described previously.¹² The total for 5 areas was averaged to obtain the cell number of the in the zone.

Effects of High Salt on Brain Superoxide in SHRSP and Its Inhibition by ARB
Eight-week-old SHRSP, fed 8% NaCl diet, were treated with vehicle, candesartan (1 mg/kg per day) or amlodipine (1 mg/kg per day) for 1 or 2 weeks. After treatment, rats were anesthetized with ether, and the brain was excised for detection of superoxide, as described below. We also examined the effect of apocynin¹³ (3 mmol/L in the drinking water), a highly specific NADPH oxidase inhibitor, on brain superoxide.

Effects of Angiotensin II Infusion on Brain Superoxide in SHRSP
Vehicle (0.5% carboxymethyl cellulose), candesartan (1 mg/kg per day), amlodipine (1 mg/kg per day), tempol (1 mmol/L in the drinking water), the stable membrane-permeable superoxide dismutase (SOD) mimetic,¹⁴ or apocynin (3 mmol/L in the drinking water) was given orally to SHRSP subcutaneously infused with angiotensin II (Ang II; 200 ng/kg per minute) via osmotic minipump (Alza) for 2 weeks, from 3 days before to the end of the experiments. Rats were then anesthetized with ether and the brain was excised for detection of superoxide, as described below.

Effects of Salt and Ang II on Blood–Brain Barrier of SHRSP
Eleven-week-old SHRSP, fed 0.3% or 8% NaCl diet, were subcutaneously infused with saline or Ang II (200 ng/kg per minute) via osmotic minipump for 2 weeks, accompanied by treatment with vehicle, candesartan (1 mg/kg per day), tempol (1 mmol/L in the drinking water), amlodipine (1 mg/kg per day), or apocynin (3 mmol/L in the drinking water). Rats were intravenously injected with 2% Evans blue dye in saline (4 mL/kg), for estimation of impairment of blood–brain barrier, as described.¹⁵

Detection of Superoxide in Brain
Brain Superoxide Levels Were Measured Using 2 Approaches
First, dihydroethidium (DHE) was used to evaluate superoxide levels in situ as described previously.¹⁶ Brains were removed, quickly frozen, embedded into optimal cutting temperature, and cryostat sectioned (20 µm; coronal) directly onto chilled microscope slides. Sections were thawed at room temperature, rehydrated with 1x PBS, and incubated for 5 minutes in the dark with the (Sigma; 2 µmol/L). DHE fluorescence was visualized by fluorescent microscopy using an excitation wavelength of 520 to 540 nm and a rhodamine emission filter. Detector and laser settings were kept constant across all samples within individual experiments, and control and experimental samples were always processed in parallel. DHE fluorescence was quantified using Lumina Vision version 2.2 analysis software. The mean fluorescence was quantified and expressed relative to values obtained for control rats.

Second, brain superoxide levels were measured with lucigenin chemiluminescence.¹⁷ Brain cortex sample was incubated with 100 µmol/L NADPH as the substrate to determine NADPH oxidase activity. We used 5 µmol/L lucigenin because this concentration of lucigenin accurately reflects ambient superoxide levels.¹⁸

Statistics
Results were expressed as mean±SEM. Statistical significance was determined by 1-way ANOVA, followed by Duncan’s multiple range test. Survival was analyzed by the standard Kaplan–Meier analysis with a log rank test and ² analysis. In all tests, differences were considered statistically significant at the value of P<0.05.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Survival of Salt-Loaded SHRSP
Candesartan and amlodipine slightly and comparably reduced blood pressure of salt-loaded SHRSP throughout treatment (Figure 1). As shown in Figure 2, all vehicle-treated SHRSP died of stroke by 42 days. Candesartan at all doses prolonged survival of SHRSP much more than amlodipine (P<0.01). All amlodipine-treated SHRSP died by 141 days, despite no death of candesartan-treated SHRSP throughout the medication period (150 days). The survival curves of candesartan-treated SHRSP during the withdrawal period were much more gradual than that in vehicle group, in which survival curve had dropped steeply in the early stage.

View larger version (26K): [in this window] [in a new window]   Figure 1. Blood pressure of salt-loaded SHRSP at 2, 3, and 4 weeks (wk) after treatment with candesartan or amlodipine. Values are means±SEM (n=7 to 9). Low Na indicates 0.3% NaCl diet; High Na, 8% NaCl diet; Veh, vehicle; Can (0.3), candesartan (0.3 mg/kg/day); Can (3), candesartan (3 mg/kg/day); Am (1), amlodipine (1 mg/kg/day).

View larger version (20K): [in this window] [in a new window]   Figure 2. Effects of candesartan and amlodipine on life span of salt-loaded SHRSP. Abbreviations used are the same as in Figure 1. Thirteen animals were included in Veh, Am (1), Can (1), and Can (3). Can (0.3) included 9 animals.

Cerebral Arteriolar Wall Thickening, Proliferation, and Hippocampal Neuronal Cells
Salt loading led to a higher ratio of medial to luminal area of hippocampal arteriolar wall in SHRSP (Figure 3A). Candesartan, but not amlodipine, significantly prevented the cerebral arteriolar wall thickening of SHRSP. The percentage of cerebral arteriolar PCNA-positive cells in SHRSP was significantly reduced by candesartan at either dose but not by amlodipine (Figure 3B). High salt significantly decreased CA1 hippocampal neuronal cell number in SHRSP (1024.9±20.6 versus 724.9±22.8 cells/mm²; P<0.01), and this reduction was prevented by candesartan at either 0.3 or 3 mg/kg (P<0.01) but not by amlodipine (Figure 3C).

View larger version (25K): [in this window] [in a new window]   Figure 3. Effects of candesartan and amlodipine on cerebral arteriolar thickening (A), cerebral arteriolar PCNA-positive cells (B), and hippocampal CA1 neuronal cell number (C) in salt-loaded SHRSP. Values are means±SEM (n=7 to 10). Abbreviations used are the same as in Figure 1.

Cerebral Superoxide Production in Salt-Loaded SHRSP
Candesartan and amlodipine decreased blood pressure of salt-loaded SHRSP to a similar degree (Figure 4A). To verify that the method used specifically detected tissue superoxide, in preliminary experiments, we examined the effect of preincubation with SOD (500 U/mL) on DHE staining and found that preincubation with SOD completely abolished ethidium bromide fluorescence elicited by DHE, thereby validating that superoxide was successfully detected by our present method. Salt loading increased superoxide production in cerebral cortex and hippocampus of SHRSP at 1 and 2 weeks, which was prevented by candesartan but not by amlodipine (Figure 4B). Furthermore, additional experiments on the detection of brain superoxide by the method of Chan et al¹⁹ injecting DHE intravenously agreed with the present result obtained with frozen section (supplemental Figure I, available online only at http://www.strokeaha.org), confirming the validity of our present method. On the other hand, 2 weeks of salt loading still did not cause the reduction of CA1 neuronal cell number or death in SHRSP (data not shown), indicating that the increase in brain superoxide by salt loading was the earlier event than stroke or neuronal cell death. NADPH-induced superoxide (NADPH oxidase activity) by lucigenin chemiluminescence also indicated that salt loading increased brain parenchyma superoxide in SHRSP by 1.4-fold, and candesartan significantly prevented the increase in cerebral superoxide (P<0.01), but amlodipine failed it (Figure 4B). Furthermore, to confirm the involvement of NADPH oxidase to the source of superoxide, we examined the effect of apocynin on brain superoxide and found that apocynin significantly prevented brain superoxide elevation (P<0.01; Figure 4C).

View larger version (32K): [in this window] [in a new window]   Figure 4. Effects of candesartan and amlodipine on blood pressure (A) and cerebral superoxide levels (B and C) in salt-loaded SHRSP. B, Representative confocal images show DHE fluorescence in the cerebral cortex (top panels) and hippocampal area (bottom panels) from each group of SHRSP. Bar graph shows NADPH-induced superoxide production (NADPH oxidase activity) in brain parenchyma. To verify that lucigenin signal reflected superoxide generation, diphenylene iodonium (DPI; 10µmol/L), a flavoprotein NADPH oxidase inhibitor, and tempol (10–5 mol/L) were added to the samples. As shown in left panels, DPI and tempol completely abolished the NADPH-induced increase in chemiluminescence. C, Apocynin significantly suppressed the increase in superoxide levels in SHRSP, as estimated by DHE. Values are means±SEM (n=5 to 8). Can indicates candesartan (1 mg/kg/day); Aml, amlodipine (1 mg/kg/day); Apo, apocynin (3 mmol/L in the drinking water). KCPM indicates kilocount per minute.

Direct Effect of Ang II on Cerebral Superoxide
As shown in Figure 5, Ang II infusion increased superoxide of cerebral cortex and hippocampal area in SHRSP, and candesartan or tempol treatment prevented this superoxide accumulation, whereas amlodipine failed to suppress Ang II–induced superoxide production. NADPH-induced superoxide production by lucigenin chemiluminescence also indicated that Ang II infusion increased brain NADPH oxidase activity by 1.8-fold, and this increase was prevented by candesartan but not by amlodipine (Figure 5A). Furthermore, we examined the effect of apocynin on brain superoxide and found that apocynin significantly prevented Ang II–induced brain superoxide elevation (P<0.01; Figure 5B).

Role of Ang II on Blood–Brain Barrier in SHRSP
We examined the effect of salt loading, low dose of Ang II infusion, or the combination on blood–brain barrier in young SHRSP (Figure 6). Salt loading alone for 4 weeks or Ang II infusion (200 ng/kg per minute) alone for 2 weeks did not apparently impair blood–brain barrier in young SHRSP, as shown by no significant leakage of Evans blue in brain tissue. However, Ang II infusion combined with salt loading in SHRSP, the blood pressure of which did not differ from that of salt loading alone (Figure 6A), significantly increased Evans blue leakage in brain tissue of SHRSP by 1.7-fold (P<0.05). This increase in brain Evans blue leakage was completely prevented by candesartan (P<0.01) and tempol (P<0.05). However, amlodipine, which reduced blood pressure to a comparable degree to candesartan (Figure 6A), did not suppress brain Evans blue leakage of SHRSP. Apocynin treatment abrogated Ang II–induced brain Evans blue leakage of SHRSP (Figure 6C).

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
Excess salt exacerbates not only hypertension but also cardiovascular diseases including stroke,^2,3 although the mechanism is unknown. Furthermore, it is an open question which agent is superior on antistroke effect, renin-angiotensin blocker or calcium channel blocker, because the dihydropyridine calcium channel blocker is the most often used antihypertensive drug and has vascular and cerebral protective effects.^20,21 These findings encouraged us to compare equihypotensive doses of ARB candesartan with calcium channel blocker amlodipine on cerebral protection in salt-loaded SHRSP and to explore the mechanisms linked to salt-accelerated stroke.

In the present study, of note are the observations that candesartan prevented death attributable to stroke of salt-loaded SHRSP much more than amlodipine under their same blood pressure control. This superior prevention of stroke by candesartan over amlodipine was associated with more suppression of cerebral arteriolar remodeling, arteriolar cell proliferation, and hippocampal CA1 neuronal cell reduction by candesartan. Thus, our observation provided the evidence that prevention of stroke by candesartan was at least partially mediated by inhibition of cerebral arteriolar remodeling and neuronal cell protection, independently of blood pressure–lowering effect.

Reactive oxygen species, including superoxide, play a pivotal role in cardiovascular diseases.²² Ang II increases superoxide in cardiovascular and renal tissues, via NAD(P)H oxidase activation,^22–25 thereby causing hypertension and cardiovascular diseases. However, the possible contribution of superoxide to salt-exacerbated stroke is unclear. Therefore, in this study, we examined the effect of salt loading on brain superoxide in SHRSP and a possible link of Ang II to superoxide. We obtained the evidence that preceding the onset of stroke, salt loading significantly increased superoxide in brain cortex and hippocampus of SHRSP, which was associated with the increased NADPH oxidase activity. Candesartan, tempol (superoxide scavenger), or apocynin (a specific NADPH oxidase inhibitor) prevented the increase in brain superoxide in salt-loaded SHRSP. Regardless of equihypotensive dose, amlodipine failed to prevent superoxide or NADPH oxidase activity in salt-loaded SHRSP. Hence, cerebral superoxide production by salt in SHRSP was attributable to AT1 receptor rather than hypertension. To further confirm the involvement of Ang II in salt-induced brain superoxide in SHRSP, we examined the effect of Ang II infusion on superoxide production in SHRSP without salt loading. We found that Ang II infusion significantly increased brain superoxide of SHRSP, and this increase was prevented by candesartan, tempol, or apocynin but not by amlodipine. These observations confirm the critical role of Ang II in brain superoxide production in SHRSP, independently of blood pressure. NADPH oxidase might be involved in the increased brain superoxide in SHRSP, although further study is needed to elucidate the direct role of NADPH oxidase.

The disruption of blood–brain barrier is implicated in brain edema, thereby being involved in the exacerbation of stroke. However, the role of salt and Ang II in blood–brain barrier function is poorly understood. Therefore, in this study, we examined the impact of salt, Ang II, and their combination on the disruption of blood–brain barrier in SHRSP. As shown in Figure 6, high salt alone or Ang II infusion alone for the short-term period did not apparently impair blood–brain barrier function in SHRSP. However, we found that Ang II infusion in salt-loaded SHRSP significantly impaired blood–brain barrier, and this impairment was inhibited by candesartan but not by amlodipine, despite equihypotensive dose. To elucidate the role of superoxide in Ang II–induced disruption of blood–brain barrier, we examined the effect of tempol or apocynin. We found that scavenging of superoxide by tempol or NADPH oxidase inhibition by apocynin significantly inhibited Ang II–induced brain Evans blue leakage in salt-loaded SHRSP. Thus, Ang II–induced disruption of blood–brain barrier was mediated by the increased superoxide production.

View larger version (22K): [in this window] [in a new window]   Figure 5. Effects of Ang II on brain superoxide of SHRSP. A, Photomicrographs show in-site detection of superoxide in cerebral cortex (top panels) and hippocampal area (bottom panels) from SHRSP treated with saline infusion (control) and Ang II infusion (Ang II). Tem indicates tempol. The bar graph shows quantitative measurement of brain parenchymal NADPH-induced superoxide formation. B, Apo indicates apocynin (3 mmol/L in the drinking water). Values are means±SEM (n=6 to 7). The mean value of control group is represented as 1.

View larger version (40K): [in this window] [in a new window]   Figure 6. Detrimental effects of Ang II on blood–brain barrier in salt-loaded SHRSP. A, Time course of blood pressure of SHRSP fed a low-salt and high-salt diet, throughout Ang II infusion or not. Values are means±SEM (n=4 to 7). B, Top panels show representative macroscopic pictures of Evans blue leakage in brain. Bottom bar graph shows the quantitative data of Evans blue leakage in each group of SHRSP. C, Apocynin treatment abolished Ang II–induced Evans blue leakage in the brain of SHRSP (n=5 in each group). L indicates 0.3% NaCl diet; AII, Ang II infusion; H, 8% NaCl diet; Can, candesartan; Tem, tempol; Aml, amlodipine; Apo, apocynin.

In summary, excess salt increased brain superoxide production in SHRSP, which participated in the exacerbation of encephalopathy. Salt-induced brain superoxide production in SHRSP is at least in part mediated by AT1 receptor, independently of blood pressure. Furthermore, excess salt, in concert with Ang II, was involved in the impairment of blood–brain barrier in SHRSP. However, further study is needed to elucidate the precise underlying mechanism of stroke prevention by candesartan because the brain superoxide seems not to be the sole mechanism responsible for brain protection of candesartan. Two clinical trials^26,27 recently suggested that ARB confers benefits beyond reduction in blood pressure. Together with these clinical findings, our present experimental findings may provide a novel insight into the role of ARB in antistroke effect.

	Acknowledgments

 
This work was supported in part by a grant-in-aid for scientific research (14370036 and 14570083) from the Ministry of Education, Science, and Culture.

Received December 15, 2004; revision received February 2, 2005; accepted February 25, 2005.

	References

Top Abstract Introduction Materials and Methods Results Discussion References

 
1. Okamoto K, Yamori Y, Nagaoka A. Establishment of the stroke-prone spontaneously hypertensive rats (SHR). Circ Res. 1974; 33/34: I-143–I-153.

2. Messerli FH, Schmieder RE, Weir MR. Salt. A perpetrator of hypertensive target organ disease? Arch Intern Med. 1997; 157: 2449–2452.[Abstract/Free Full Text]

3. Antonios TF, MacGregor GA. Salt—more adverse effects. Lancet. 1996; 348: 250–251.[CrossRef][Medline] [Order article via Infotrieve]

4. Camargo MJ, von Lutterotti N, Campbell WG Jr, Pecker MS, James GD, Timmermans PB, Laragh JH. Control of blood pressure and end-organ damage in maturing salt-loaded stroke-prone spontaneously hypertensive rats by oral angiotensin II receptor blockade. J Hypertens. 1993; 11: 31–40.[CrossRef][Medline] [Order article via Infotrieve]

5. Blezer EL, Nicolay K, Bar D, Goldschmeding R, Jansen GH, Koomans HA, Joles JA. Enalapril prevents imminent and reduces manifest cerebral edema in stroke-prone hypertensive rats. Stroke. 1998; 29: 1671–1677.[Abstract/Free Full Text]

6. Ogiku N, Sumikawa H, Hashimoto Y, Ishida R. Prophylactic effect of imidapril on stroke in stroke-prone spontaneously hypertensive rats. Stroke. 1993; 24: 245–252.[Abstract/Free Full Text]

7. Kim S, Iwao H. Molecular and cellular mechanisms of angiotensin II-mediated cardiovascular and renal diseases. Pharmacol Rev. 2000; 52: 11–34.[Abstract/Free Full Text]

8. Gorelick PB. Stroke prevention therapy beyond antithrombotics: unifying mechanisms in ischemic stroke pathogenesis and implications for therapy: an invited review. Stroke. 2002; 33: 862–875.[Abstract/Free Full Text]

9. Kim S, Kawamura M, Wanibuchi H, Ohta K, Hamaguchi A, Omura T, Yukimura T, Miura K, Iwao H. Angiotensin II type 1 receptor blockade inhibits the expression of immediate-early genes and fibronectin in rat injured artery. Circulation. 1995; 92: 88–95.[Abstract/Free Full Text]

10. Kim S, Wanibuchi H, Hamaguchi A, Miura K, Yamanaka S, Iwao H. Angiotensin blockade improves cardiac and renal complications of type II diabetic rats. Hypertension. 1997; 30: 1054–1061.[Abstract/Free Full Text]

11. Hamaguchi A, Kim S, Ohta K, Yagi K, Yukimura T, Miura K, Fukuda T, Iwao H. Transforming growth factor-beta 1 expression and phenotypic modulation in the kidney of hypertensive rats. Hypertension. 1995; 26: 199–207.[Abstract/Free Full Text]

12. Hirawa N, Uehara Y, Kawabata Y, Numabe A, Gomi T, Ikeda T, Suzuki T, Goto A, Toyo-oka T, Omata M. Long-term inhibition of renin-angiotensin system sustains memory function in aged dahl rats. Hypertension. 1999; 34: 496–502.[Abstract/Free Full Text]

13. Stolk J, Hiltermann TJ, Dijkman JH, Verhoeven AJ. Characteristics of the inhibition of NADPH oxidase activation in neutrophils by apocynin, a methoxy-substituted catechol. Am J Respir Cell Mol Biol. 1994; 11: 95–102.[Abstract]

14. Schnackenberg CG, Wilcox CS. Two-week administration of tempol attenuates both hypertension and renal excretion of 8-Iso prostaglandin f2alpha. Hypertension. 1999; 33: 424–428.[Abstract/Free Full Text]

15. Warnick RE, Fike JR, Chan PH, Anderson DK, Ross GY, Gutin PH. Measurement of vascular permeability in spinal cord using Evans blue spectrophotometry and correction for turbidity. J Neurosci Methods. 1995; 58: 167–171.[CrossRef][Medline] [Order article via Infotrieve]

16. Izumiya Y, Kim S, Izumi Y, Yoshida K, Yoshiyama M, Matsuzawa A, Ichijo H, Iwao H. Apoptosis signal-regulating kinase 1 plays a pivotal role in angiotensin II-induced cardiac hypertrophy and remodeling. Circ Res. 2003; 93: 874–883.[Abstract/Free Full Text]

17. Munzel T, Sayegh H, Freeman BA, Tarpey MM, Harrison DG. Evidence for enhanced vascular superoxide anion production in nitrate tolerance. A novel mechanism underlying tolerance and cross-tolerance. J Clin Invest. 1995; 95: 187–194.[Medline] [Order article via Infotrieve]

18. Skatchkov MP, Sperling D, Hink U, Mulsch A, Harrison DG, Sindermann I, Meinertz T, Munzel T. Validation of lucigenin as a chemiluminescent probe to monitor vascular superoxide as well as basal vascular nitric oxide production. Biochem Biophys Res Commun. 1999; 254: 319–324.[CrossRef][Medline] [Order article via Infotrieve]

19. Chan PH, Kawase M, Murakami K, Chen SF, Li Y, Calagui B, Reola L, Carlson E, Epstein CJ. Overexpression of SOD1 in transgenic rats protects vulnerable neurons against ischemic damage after global cerebral ischemia and reperfusion. J Neurosci. 1998; 18: 8292–8299.[Abstract/Free Full Text]

20. Cristofori P, Lanzoni A, Quartaroli M, Pastorino AM, Zancanaro C, Cominacini L, Gaviraghi G, Turton J. The calcium-channel blocker lacidipine reduces the development of atherosclerotic lesions in the apoE-deficient mouse. J Hypertens. 2000; 18: 1429–1436.[CrossRef][Medline] [Order article via Infotrieve]

21. Kyselovic J, Morel N, Wibo M, Godfraind T. Prevention of salt-dependent cardiac remodeling and enhanced gene expression in stroke-prone hypertensive rats by the long-acting calcium channel blocker lacidipine. J Hypertens. 1998; 16: 1515–1522.[CrossRef][Medline] [Order article via Infotrieve]

22. Romero JC, Reckelhoff JF. State-of-the-art lecture. Role of angiotensin and oxidative stress in essential hypertension. Hypertension. 1999; 34: 943–949.[Abstract/Free Full Text]

23. Rajagopalan S, Kurz S, Munzel T, Tarpey M, Freeman BA, Griendling KK, Harrison DG. Angiotensin II-mediated hypertension in the rat increases vascular superoxide production via membrane NADH/NADPH oxidase activation. Contribution to alterations of vasomotor tone. J Clin Invest. 1996; 97: 1916–1923.[Medline] [Order article via Infotrieve]

24. Griendling KK, Sorescu D, Ushio-Fukai M. NAD(P)H oxidase: role in cardiovascular biology and disease. Circ Res. 2000; 86: 494–501.[Abstract/Free Full Text]

25. Laursen JB, Rajagopalan S, Galis Z, Tarpey M, Freeman BA, Harrison DG. Role of superoxide in angiotensin II-induced but not catecholamine-induced hypertension. Circulation. 1997; 95: 588–593.[Abstract/Free Full Text]

26. Dahlof B, Devereux RB, Kjeldsen SE, Julius S, Beevers G, de Faire U, Fyhrquist F, Ibsen H, Kristiansson K, Lederballe-Pedersen O, Lindholm LH, Nieminen MS, Omvik P, Oparil S, Wedel H. Cardiovascular morbidity and mortality in the losartan intervention for end point reduction in hypertension study (life): a randomised trial against atenolol. Lancet. 2002; 359: 995–1003.[CrossRef][Medline] [Order article via Infotrieve]

27. Lithell H, Hansson L, Skoog I, Elmfeldt D, Hofman A, Olofsson B, Trenkwalder P, Zanchetti A. The study on cognition and prognosis in the elderly (scope): principal results of a randomized double-blind intervention trial. J Hypertens. 2003; 21: 875–886.[CrossRef][Medline] [Order article via Infotrieve]

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This Article Abstract Full Text (PDF) All Versions of this Article: 36/5/1077    most recent 01.STR.0000163084.16505.e3v1 Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Kim-Mitsuyama, S. Articles by Iwao, H. Search for Related Content PubMed PubMed Citation Articles by Kim-Mitsuyama, S. Articles by Iwao, H. Pubmed/NCBI databases Compound via MeSH Substance via MeSH Hazardous Substances DB AMLODIPINE BESYLATE SODIUM CHLORIDE Medline Plus Health Information Stroke Related Collections ACE/Angiotension receptors