Is Vitamin C Good For Low Blood Pressure
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Vitamin C in plasma is inversely related to blood pressure and change in blood pressure during the previous year in young Black and White women
Nutrition Journal volume 7, Article number:35 (2008) Cite this article
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Abstract
Background
The prevalence of hypertension and its contribution to cardiovascular disease risk makes it imperative to identify factors that may help prevent this disorder. Extensive biological and biochemical data suggest that plasma ascorbic acid may be such a factor. In this study we examined the association between plasma ascorbic acid concentration and blood pressure (BP) in young-adult women.
Methods
Participants were 242 Black and White women aged 18–21 yr from the Richmond, CA, cohort of the National Heart, Lung and Blood Institute Growth and Health Study. We examined the associations of plasma ascorbic acid with BP at follow-up year 10, and with change in BP during the previous year.
Results
In cross-sectional analysis, plasma ascorbic acid at year 10 was inversely associated with systolic BP and diastolic BP after adjusting for race, body mass index, education, and dietary intake of fat and sodium. Persons in the highest one-fourth of the plasma ascorbic acid distribution had 4.66 mmHg lower systolic BP (95% CI 1.10 to 8.22 mmHg, p = 0.005) and 6.04 mmHg lower diastolic BP (95% CI 2.70 to 9.38 mmHg, p = 0.0002) than those in the lowest one-fourth of the distribution. In analysis of the change in BP, plasma ascorbic acid was also inversely associated with change in systolic BP and diastolic BP during the previous year. While diastolic blood pressure among persons in the lowest quartile of plasma ascorbic acid increased by 5.97 mmHg (95% CI 3.82 to 8.13 mmHg) from year 9 to year 10, those in the highest quartile of plasma vitamin C increased by only 0.23 mmHg (95% CI -1.90 to +2.36 mmHg) (test for linear trend: p < 0.0001). A similar effect was seen for change in systolic BP, p = 0.005.
Conclusion
Plasma ascorbic acid was found to be inversely associated with BP and change in BP during the prior year. The findings suggest the possibility that vitamin C may influence BP in healthy young adults. Since lower BP in young adulthood may lead to lower BP and decreased incidence of age-associated vascular events in older adults, further investigation of treatment effects of vitamin C on BP regulation in young adults is warranted.
Background
Elevated blood pressure (BP) is a major public health problem in the United States with almost 60% of American adults having pre-hypertension or hypertension [1]. The disorder is prevalent in all major ethnic groups, although Blacks are disproportionately affected [1]. As elevated BP is a strong and independent risk factor for cardiovascular and renal disease morbidity and mortality [2], identifying preventive measures is an important public health goal.
The Dietary Approaches to Stop Hypertension (DASH) trial demonstrated that diet is an important factor in BP regulation. In that study, a diet rich in vegetables, fruit, low-fat dairy foods, and with reduced saturated and total fat intake significantly reduced systolic BP and diastolic BP over a period of 8 weeks compared to a control diet [3]. DASH diet constituents believed to contribute to the observed BP-lowering effect include calcium, magnesium, potassium, dietary fiber, and the reduced fat content of the diet [3, 4]. The DASH diet is also rich in vitamin C, another possible contributor to the observed BP effect [5]. Mechanistic studies have demonstrated a role of vitamin C in maintaining the normal production and biological activity of endothelium-derived nitric oxide which plays a role in vascular tone and reactivity [6, 7]. Thus, plasma ascorbic acid concentration should be investigated for its possible role in lowering or maintaining normal BP.
Numerous cross-sectional studies have observed highly significant inverse relationships between BP and circulating ascorbic acid concentration [8–18]. Almost all such studies have focused on populations that are middle-aged and older, and intervention research has typically focused on treatment of those with already elevated blood pressure. However, we hypothesized that an ascorbic acid association in a young normotensive population might provide clues to the primary prevention of hypertension. Examining this relationship in young adults is potentially important because maintaining healthy BP in healthy young adults may lead to a lower BP in older adults, and consequently a lower incidence of age-associated vascular events [2]. Therefore, we investigated this relationship among 18–21 year old Black and White women enrolled in the National Heart, Lung, and Blood Institute (NHLBI) Growth and Health Study. We hypothesized that plasma ascorbic acid concentration at the 10th annual follow-up visit would be inversely associated with BP, and inversely associated with change in BP during the previous year, in this population group.
Methods
Participants
In 1985, the NHLBI initiated the Growth and Health Study, a 10-year longitudinal multicenter study to investigate the development of obesity in Black and White girls during adolescence, along with its environmental, psychosocial, and cardiovascular disease risk factor correlates. Black and White girls, ages 8 to 11 years, were recruited from Richmond, CA, Cincinnati, OH, and Washington, DC areas. Institutional review board approval was obtained at all participating centers. The parents or guardians of participants gave informed consent for the children to participate. Girls were followed annually through ages 18 to 21 years, with a follow-up rate of 90% at the 10th annual follow-up visit. The sample design, recruitment and selection procedures used for the Growth and Health Study have been previously described [19]. For this investigation, plasma ascorbic acid samples were obtained only from girls in the Richmond, CA cohort at the 10th annual visit. The blood draw for plasma ascorbic acid was implemented midway through the annual data collection period and a total of 335 participants were seen in the clinic after plasma sample collection was initiated. Plasma samples were successfully obtained from 242 participants (72%), consisting of 155 Blacks and 87 Whites. The 93 who did not participate in the extra blood draw were either seen on a day when the ascorbic acid study staff was not present to take their blood, were pregnant, or refused the extra procedure.
Data collection
BP
BP measurements were obtained by trained examiners according to a standard protocol [20]. Participants were seated with feet resting flat on a surface and the right arm resting at heart level. Participants were seated for at least 5 minutes before BP measurements were begun. The appropriate cuff was selected from 5 cuff sizes and placed around the upper arm. Using a standard mercury sphygmomanometer (Baum Desktop model with V-Lok cuffs), three consecutive readings were taken using the same arm and waiting at least 30 seconds between readings. The second and third readings were averaged to determine the mean systolic BP, defined as the onset of the first two consecutive beats (first Korotkoff phase), and the mean diastolic BP, defined as the point at which the sound disappeared (fifth Korotkoff phase). BP was obtained at both the 9th and 10th annual visits.
Plasma ascorbic acid
Participants were instructed to fast for at least 12 hours before the blood draw. Plasma ascorbic acid was determined using the 2,4-dinitrophenylhydrazine method [21], which has been shown to correlate well with HPLC methods [22]. Plasma was stabilized with 10% metaphosphoric acid, frozen at -70°C within 4 hours of the collection, and analyzed within six months. Plasma ascorbic acid was assayed only at the 10th annual visit. Blood stored from earlier visits could not be used for assaying ascorbic acid because it had not been stabilized with metaphosphoric acid.
Anthropometry
At the 10th annual visit, participants were weighed using an electronic scale (SECA Alpha 770) in gowns without shoes. Height was measured using a custom portable stadiometer (Creative Health Products, Plymouth, MI). Participants wore socks and were positioned with heels together, toes apart at a 45 degree angle, and head in the Frankfort horizontal plane. Both weight and height were measured twice and repeated a third time if values differed by more than 0.3 kg and 0.5 cm, respectively. Body mass index (BMI) was calculated as kg/m2.
Socioeconomic and lifestyle variables
Information on socioeconomic and lifestyle variables was ascertained by questionnaire at the 10th annual visit. Smoking was assessed by asking how many days participants smoked in the past 30 days and how many cigarettes were smoked per day. The number of smoking days/month was then multiplied by the number of cigarettes/day to create a continuous variable, cigarettes smoked/month. Alcohol consumption was assessed in a similar fashion, with 1 drink being equivalent to 12 oz. (355 mL) of beer or 6 oz. (177 mL) of wine. The number of hours/week of television or videos watched was assessed as a proxy for physical inactivity. Pregnancy history and current contraceptive use was also obtained.
Dietary variables
Dietary information at the 10th annual visit was determined using 3-day dietary records, covering two consecutive weekdays and one weekend day. Participants used rulers, pictures, and thickness guides to measure and quantify the amount of food consumed. Dietary records were reviewed with a dietitian and analyzed for nutrient composition by the Cincinnati Dietary Center using the University of Minnesota Nutrition Coordinating Center database. The method used for estimating nutrient intake had been previously validated in this population [23]. All micronutrient intake estimates include amounts provided by supplements. Estimates of dietary sodium intake were from food only and no attempt was made to collect information on added dietary salt intake.
Statistical analyses
Unpaired two-tailed t-tests and Wilcoxon two-sample tests were used to compare baseline characteristics of Black and White study participants. Plasma ascorbic acid at year 10 was divided into quartiles, and least squares mean diastolic and systolic BP, adjusted for race, BMI, education, and intake of fat and sodium, were calculated for each quartile using analysis of covariance. Change in BP was calculated as the systolic and diastolic values at year 10 minus their respective values at year 9, and adjusted changes were calculated using analysis of covariance; year 9 BP was included as a covariate in the model. The relationships between plasma ascorbic acid and BP at the 10th annual visit, as well as between plasma ascorbic acid at year 10 and change in BP in the previous year, were also examined as continuous variables using multivariable linear regression models. The interaction of race and BMI with the independent variable was assessed using cross-product terms in the regression models. Annual household income and education were highly correlated. However, education explained more of the variance, and consequently education was used in the models. A number of other covariates were considered as potential confounders, including intake of total energy, potassium, calcium, dietary antioxidants, and fiber, pregnancy history, use of birth control pills, smoking, alcohol consumption, and number of hours/week of television or video watching. However, none was statistically significant and these variables were not included in the final models. Statistical analyses were conducted with SAS 9.1.
Results
Descriptive characteristics and comparisons of the total sample and by race are presented in Table 1. Mean diastolic BP, age, weight, BMI, energy intake, and plasma ascorbic acid concentrations did not differ significantly by race. Black women had higher mean systolic BP, watched more hours/week of television or videos, consumed more fat/day, and lived in households with lower incomes as compared to White women. Blacks also smoked significantly fewer cigarettes, drank less alcohol, and were more likely to have been pregnant (data not shown.) However, race did not significantly modify the relationship between plasma ascorbic acid and BP (interaction terms for systolic and diastolic BP were p = 0.42 and p = 0.47, respectively). Therefore, statistical models included all 242 subjects and were not stratified by race.
For comparison of BP in categories of plasma ascorbic acid, the plasma ascorbic acid distribution among participants at visit 10 was divided into fourths. Mean concentrations of ascorbic acid, by quartile, were as follows: Quartile 1: 0.59 mg/dL (SD 0.18 mg/dL); Quartile 2: 1.03 mg/dL (SD 0.10 mg/dL); Quartile 3: 1.36 mg/dL (SD 0.10 mg/dL); and Quartile 4: 1.83 mg/dL (SD 0.34 mg/dL). (Means in SI units: 33.51 μmol/L, 58.50 μmol/L, 77.25 μmol/L, 103.94 μmol/L for quartiles 1 through 4, respectively.)
In cross-sectional analyses, we examined BP across quartiles of plasma ascorbic acid at the 10th annual visit. There was a significant inverse linear trend in both systolic BP (Figure 1) and diastolic BP (Figure 2) across the quartiles of plasma ascorbic acid concentration (unadjusted p = 0.0001, respectively). In regression analysis using the quartiles as predictor variables, after adjustment for BMI, race, education, and dietary fat and sodium intake, these inverse linear trends remained significant for both systolic BP and diastolic BP, with substantial differences in BP across the quartiles. Persons in the upper one-fourth of the plasma ascorbic acid distribution had 4.66 mmHg lower systolic BP (95% CI 1.10 to 8.22 mmHg, p = 0.005) than those in the lower one-fourth of the plasma ascorbic acid distribution. For diastolic BP, persons in the upper one-fourth of the plasma ascorbic acid distribution had 6.04 mmHg lower diastolic BP (95% CI 2.70 to 9.38 mmHg, p = 0.0002) than those in the lower quartile of ascorbic acid. We also performed multiple regression analysis of ascorbic acid as a continuous variable, with BP as the dependent variable, plasma ascorbic acid as the primary predictive variable, and adjusting for BMI, race, education, dietary fat and sodium intake. Cross-sectionally, as plasma ascorbic acid concentration increased by 1 mg/dL (56.8 μmol/L), systolic BP decreased by 4.1 mmHg (95% CI -6.6 to -1.7 mmHg) and diastolic BP decreased by 4.0 mmHg (95% -6.4 to -1.7 mmHg).
We also examined the association between plasma ascorbic acid concentration at year 10 and change in BP between years 9 and 10. Change in both systolic BP and diastolic BP was inversely associated with plasma ascorbic acid concentration at year 10 (Figure 3) after adjustment for BMI, race, education, and dietary fat and sodium intake. Systolic BP increased by 1.40 mmHg (95% CI -0.76 to +3.57 mmHg) among those in the lowest quartile of the plasma ascorbic acid distribution, but decreased in persons in higher quartiles of plasma ascorbic acid (test for linear trend in change in BP across quartiles of year 10 ascorbic acid: p = 0.005). Diastolic BP increased overall, but the increase was less with increasing quartiles of plasma ascorbic acid. While diastolic blood pressure among persons in the lowest quartile of plasma ascorbic acid increased by 5.97 mmHg (95% CI 3.82 to 8.13 mmHg) from year 9 to year 10, those in the highest quartile of plasma vitamin C increased by only 0.23 mmHg (95% CI -1.90 to +2.36 mmHg) (test for linear trend: p < 0.0001). Control for weight change between years 9 and 10 made essentially no difference in these results (data not shown).
Discussion
We found plasma ascorbic acid concentration to be inversely associated with systolic and diastolic BP in young-adult Black and White women, independent of race, BMI, education, diet, and lifestyle factors. A 1 mg/dL (56.8 μmol/L) increase in plasma ascorbic acid levels was associated with 4.1 mmHg lower systolic blood pressure and 4.0 mmHg lower diastolic blood pressure. Plasma ascorbic acid levels in this cohort ranged from 0.22 to 3.13 mg/dL (12.5 to 177.8 μmol/L), indicating that a 1 mg/dL change in plasma ascorbic acid level is achievable in this young population.
Plasma ascorbic acid concentration was also inversely and significantly associated with change in BP during the previous year. It is particularly notable that there was very little increase in diastolic BP in persons in the highest quartile of ascorbic acid.
The magnitude of the decrease in systolic and diastolic blood pressure associated with plasma ascorbic acid is consistent with the range of values found in other cross-sectional studies [8–18]. A review by Ness [18] found that the blood pressure difference associated with a 50 μmol/L (0.88 mg/dL) difference in ascorbic acid concentration ranged from -2.6 to -9.4 mmHg for diastolic blood pressure, and from -3.6 to -17.8 mmHg for systolic blood pressure.
Intervention trials have been less consistent [24–37]. Many of the studies that failed to find a treatment effect have had design limitations such as no control group or no placebo control, short duration, small sample size, concomitant use of non-study dietary supplements containing vitamin C, and varying or inadequately described methods for measuring BP; or they were post-hoc analyses where change in BP was not a primary endpoint of the trial. On the other hand, some studies have found significant reductions in BP as a result of treatment with vitamin C [38–41].
The DASH study [3] is the major intervention trial of nutritional factors, and our results are comparable in magnitude to those of DASH. Among all participants in the DASH study, the DASH diet lowered mean systolic BP by 5.5 mmHg, and lowered mean diastolic BP by 3.0 mmHg. In the present study, the difference between the mean BP in the first and fourth quartiles of ascorbic acid concentration was 4.7 mmHg systolic, and 6.1 mmHg diastolic BP. This suggests the possibility that if the ascorbic acid concentration of those in the lower one-fourth of the distribution could be increased to the ascorbic acid concentration of those in the top one-fourth of the distribution, an effect comparable to that of the DASH diet could be achieved. The present study was not an intervention study and such an intervention effect is only a hypothesis, but one which would seem to merit follow-up.
The ranges of plasma ascorbic acid seen in our sample are very consistent with those found in the United States. We examined data from the National Health and Nutrition Examination Survey (NHANES) 2003–2004, among women in the same age group, 18–21 years. The mean plasma ascorbic acid concentrations in the four quartiles were 0.43 mg/dL, 0.84 mg/dL, 1.14 mg/dL, and 1.59 mg/dL (24.1, 47.8, 64.8, 90.1 μmol/L). (Block, unpublished data.) In our sample those means were 0.59, 1.03, 1.36 and 1.83 mg/dL. Thus, in the present sample the first three quartiles were similar although slightly higher than those seen in representative national data. The lower two quartiles represent ascorbic acid concentrations most likely obtained from fruits, vegetables and fortified foods such as cereals. A diet rich in fruits and vegetables can produce a concentration similar to that seen in the third quartile. The concentration in the fourth quartile represents a level in which supplements containing vitamin C have made a substantial contribution.
There is substantial biologic rationale for a causal role of ascorbic acid in maintaining normal BP. Numerous oxidative mechanisms appear to be involved in the pathogenesis of hypertension [6, 7, 42]. One well-studied oxidative stress biomarker is F2-isoprostane, a vasoactive product of lipid peroxidation [43]; we have shown in a randomized trial that supplementation with vitamin C, but not with vitamin E, significantly reduces F2-isoprostane [44]. Similarly inflammation, consistently associated with increased risk of cardiovascular disease, is associated with impaired endothelium-dependent vasodilation and hypertension [45]. Bautista found a progressive increase in blood pressure with increases in high-sensitivity C-reactive protein (hsCRP), a sensitive marker of inflammation [45]. We showed, in a randomized trial, that vitamin C but not vitamin E significantly lowered hsCRP, to an extent equivalent to that seen with statins [46]. Thus, vitamin C may have a beneficial effect on BP by mitigating the adverse effects of inflammation and oxidative stress. Specific functions of vitamin C have also been shown. These include effects on smooth muscle contractility of peripheral blood vessels and improvement of vasomotor dysfunction [47], prevention of nitric oxide inhibition of release of endothelium-derived relaxing factor [48], and prevention of free radical inhibition of prostacyclin synthetase. Ascorbic acid may also influence BP by maintaining the normal production and biological activity of nitric oxide through enhanced recycling of tetrahydrobiopterin, a cofactor that stabilizes and sustains the activity of endothelial nitric oxide synthase [49–52].
An important limitation of this study is the fact that the results depicted in Figures 1 and 2 are cross-sectional and therefore causality cannot be inferred. Also, the data represented in Figure 3 are limited by the fact that there were no plasma ascorbic acid measurements for the 9th annual visit, and therefore the association with change in BP, while longitudinal, is not truly prospective. In interpreting our findings it is important to consider the fact that dietary variables are often correlated with one another and may be correlated with lifestyle variables. Therefore, it is possible that plasma ascorbic acid concentration is simply a marker for another variable that influences BP. However, the association persisted even after controlling for BMI, race, education, and intake of fat, sodium and antioxidants. We also evaluated the effect of controlling for other potential confounders including smoking, alcohol consumption, television or video watching, and intake of total energy, calcium, and potassium, and none diminished the strength of the association.
Nevertheless, while we cannot confidently infer causality, our findings point to the important possibility that vitamin C may influence BP even among healthy young adults. This finding is of importance because lowering BP or attenuating increases in BP in young adults may lead to lower BP in older adults, which in turn may reduce the risk of age-associated vascular events. Therefore, our findings suggest that further study of the relationship between vitamin C and BP in this young-adult population is warranted.
Conclusion
This is the first study to report on the relationship between plasma ascorbic acid concentration and BP in a cohort of young, normotensive women, aged 18–21 years. Plasma ascorbic acid concentration was found to be inversely associated with BP and with change in BP over the previous year. These inverse relationships were observed in a sample where two-thirds of participants were Black, a population that suffers disproportionately from elevated BP and its sequelae. Lowering BP or attenuating increases in BP in healthy young adults may lead to lower BP in older adults and reduced risk of age-associated vascular events. This study suggests that vitamin C may be an important factor in BP regulation even among health young adults, and that further study is warranted.
Abbreviations
- BP:
-
blood pressurel CI: confidence interval
- DASH:
-
Dietary Approaches to Stop Hypertension
- NHLBI:
-
National Heart, Lung, and Blood Institute
- BMI:
-
body mass index
References
- 1.
Wang Y, Wang QJ: The prevalence of prehypertension and hypertension among US adults according to the new Joint National Committee Guidelines. Arch Intern Med. 2004, 164: 2126-2134. 10.1001/archinte.164.19.2126.
PubMed Article PubMed Central Google Scholar
- 2.
Chobanian AV, Bakris GL, Black HR, Cushman WC, Green LA, Izzo JL, Jones DW, Materson BJ, Oparil S, Wright JT, Roccella EJ: The Seventh report of the Joint National Committee on Prevention, Detection, Evaluation, and Treatment of High Blood Pressure: the JNC 7 report. JAMA. 2003, 289: 2560-2572. 10.1001/jama.289.19.2560.
CAS PubMed Article PubMed Central Google Scholar
- 3.
Appel LJ, Moore TJ, Obarzanek E, Vollmer WM, Svetkey LP, Sacks FM, Bray GA, Vogt TM, Cutler JA, Windhauser MM, Lin PH, Karanja N: A clinical trial of the effects of dietary patterns on blood pressure. DASH Collaborative Research Group. N Eng J Med. 1997, 336: 1117-1124. 10.1056/NEJM199704173361601.
CAS Article Google Scholar
- 4.
Miller ER, Erlinger TP, Young DR, John M, Charleston J, Rhodes D, Wasan SK, Appel LJ: Results of the diet, exercise, and weight loss intervention trial (DEW-IT). Hypertension. 2002, 40: 612-618. 10.1161/01.HYP.0000037217.96002.8E.
CAS PubMed Article PubMed Central Google Scholar
- 5.
Svetkey LP, Loria CM: Blood pressure effects of vitamin C: What's the key question?. Hypertension. 2002, 40: 789-791. 10.1161/01.HYP.0000038340.95407.43.
CAS PubMed Article PubMed Central Google Scholar
- 6.
Frei B: On the role of vitamin C and other antioxidants in atherogenesis and vascular dysfunction. Proc Soc Exp Biol Med. 1999, 222: 196-204. 10.1046/j.1525-1373.1999.d01-136.x.
CAS PubMed Article PubMed Central Google Scholar
- 7.
Duvall WL: Endothelial dysfunction and antioxidants. Mt Sinai J Med. 2005, 72 (2): 71-80.
PubMed PubMed Central Google Scholar
- 8.
Jacques PF: A cross-sectional study of vitamin C intake and blood pressure in the elderly. Int J Vitam Nutr Res. 1992, 62 (3): 252-255.
CAS PubMed PubMed Central Google Scholar
- 9.
Salonen JT, Salonen R, Ihanainen M, Parviainen M, Seppanen R, Kantola M, Seppanen K, Rauramaa R: Blood pressure, dietary fats, and antioxidants. Am J Clin Nutr. 1988, 48: 1226-1232.
CAS PubMed Article PubMed Central Google Scholar
- 10.
Riemersma RA, Oliver M, Elton RA, Alfthan G, Vartiainen E, Salo M, Rubba P, Mancini M, Georgi H, Vuilleumeir JP: Plasma antioxidants and coronary heart disease: vitamins C and E, and selenium. Eur J Clin Nutr. 1990, 44: 143-150.
CAS PubMed PubMed Central Google Scholar
- 11.
Koh ET, Stewart T: Interrelationship among the blood components and anthropometric measurements. Nutr Rep Int. 1978, 18: 539-549.
CAS Google Scholar
- 12.
Koh ET, Chi MS: Relationship of serum vitamin C and globulin fractions with anthropometric measurements in adults. Nutr Rep Int. 1980, 21: 537-549.
CAS Google Scholar
- 13.
Yoshioka M, Matsushita , Chuman Y: Inverse association of serum ascorbic acid level and blood pressure or rate of hypertension in male adults aged 30–39 years. Int J Vitam Nutr Res. 1984, 54 (4): 343-347.
CAS PubMed PubMed Central Google Scholar
- 14.
Choi ESK, Jacques PF, Dallal GE, Jacob RA: Correlation of blood pressure with plasma ascorbic acid. Nutr Res. 1991, 11: 1377-1382. 10.1016/S0271-5317(05)80470-1.
Article Google Scholar
- 15.
Moor de Burgos A, Wartanowicz M, Ziemlanski S: Blood vitamin and lipid levels in overweight and obese women. Eur J Clin Nutr. 1992, 46: 803-808.
CAS PubMed PubMed Central Google Scholar
- 16.
Moran JP, Cohen L, Greene JM, Xu G, Feldman EB, Hames CG, Feldman DS: Plasma ascorbic acid concentrations relate inversely to blood pressure in human subjects. Am J Clin Nutr. 1993, 57: 213-217.
CAS PubMed Article PubMed Central Google Scholar
- 17.
Toohey L, Harris MA, Allen KG, Melby CL: Plasma ascorbic acid concentrations are related to cardiovascular risk factors in African-Americans. J Nutr. 1996, 126: 121-128.
CAS PubMed Article PubMed Central Google Scholar
- 18.
Ness AR, Khaw K, Bingham S, Day NE: Vitamin C status and blood pressure. J Hypertens. 1996, 14: 503-508. 10.1097/00004872-199604000-00014.
CAS PubMed Article PubMed Central Google Scholar
- 19.
The National Heart, Lung, and Blood Institute Growth and Health Study Research Group: Obesity and cardiovascular disease risk factors in black and white girls: The NHLBI Growth and Health Study. Am J Public Health. 1992, 82: 1613-1620. 10.2105/AJPH.82.12.1613.
Article Google Scholar
- 20.
Task Force on Blood Pressure Control in Children: Report of the Second Task Force on Blood Pressure Control in Children. Pediatrics. 1987, 79: 1-25.
Google Scholar
- 21.
US Department of Health and Human Services UPHS, Centers for Disease Control, Clinical Chemistry Division: Laboratory procedures used by the clinical chemistry division, for the second national health and nutrition examination survey (NHANES II) 1976–1980. IV-analytical methods, vitamin C. 1979, Atlanta, GA: Centers for Disease Control
Google Scholar
- 22.
Sauberlich HE, Kretsch MJ, Taylor PC, Johnson HL, Skala JH: Ascorbic acid and erythorbic acid metabolism in nonpregnant women. Am J Clin Nutr. 1989, 50: 1039-1049.
CAS PubMed Article PubMed Central Google Scholar
- 23.
Crawford PB, Obarzanek E, Morrison J, Sabry ZI: Comparative advantage of 3-day food records over 24-hour recall and 5-day food frequency validated by observation of 9- and 10-year-old girls. J Am Diet Assoc. 1994, 94: 626-630. 10.1016/0002-8223(94)90158-9.
CAS PubMed Article PubMed Central Google Scholar
- 24.
Hajjar IM, George V, Sasse EA, Kochar MS: A randomized, double-blind, controlled trial of vitamin C in the management of hypertension and lipids. Am J Ther. 2002, 9: 289-293. 10.1097/00045391-200207000-00005.
PubMed Article PubMed Central Google Scholar
- 25.
Koh ET: Effect of vitamin C on blood parameters of hypertensive subjects. J Okla State Med Assoc. 1984, 77 (6): 177-182.
CAS PubMed PubMed Central Google Scholar
- 26.
Feldman EB, Gold S, Greene J, Moran J, Xu G, Shultz GG, Hames CG, Feldman DS: Ascorbic acid supplements and blood pressure: a four week pilot study. Ann N Y Acad Sci. 1992, 669: 342-344.
CAS PubMed Article PubMed Central Google Scholar
- 27.
Mostafa SE, Garner DD, Garrett L, Whaley RF, El-Sekate M, Kiker M: Beneficial effects of vitamin C on risk factors of cardiovascular diseases. J Egypt Public Health Assoc. 1989, 64: 123-133.
Google Scholar
- 28.
Osilesi O, Trout DL, Ogunwole JO, Glover EE: Blood pressure and plasma lipids during ascorbic acid supplementation in borderline hypertensive and normotensive adults. Nutr Res. 1991, 11: 405-412. 10.1016/S0271-5317(05)80002-8.
Article Google Scholar
- 29.
Lovat LB, Lu Y, Palmer AJ, Edwards R, Fletcher AE, Bulpitt CJ: Double-blind trial of vitamin C in elderly hypertensives. J Hum Hypertens. 1993, 7: 403-405.
CAS PubMed PubMed Central Google Scholar
- 30.
Galley HF, Thornton J, Howdle PD, Walker BE, Webster NR: Combination oral antioxidant supplementation reduces blood pressure. Clinical Science. 1997, 92: 361-365.
CAS PubMed Article PubMed Central Google Scholar
- 31.
Fotherby MD, Williams JC, Forster LA, Craner P, Ferns GA: Effects of vitamin C on ambulatory blood pressure and plasma lipids in older persons. J Hypertens. 2000, 18: 411-415. 10.1097/00004872-200018040-00009.
CAS PubMed Article PubMed Central Google Scholar
- 32.
Miller ER, Appel LJ, Levander OA, Levine DM: The effect of antioxidant vitamin supplementation on traditional cardiovascular risk factors. J Cardiovasc Risk. 1997, 4 (1): 19-24. 10.1097/00043798-199702000-00004.
PubMed Article PubMed Central Google Scholar
- 33.
Kim MK, Sasaki S, Sasazuki S, Okubo S, Hayashi M, Tsugane S: Lack of long-term effect of vitamin C supplementation on blood pressure. Hypertension. 2002, 40: 797-803. 10.1161/01.HYP.0000038339.67450.60.
CAS PubMed Article PubMed Central Google Scholar
- 34.
Ghosh SK, Ekpo EB, Shah IU, Girling AJ, Jenkins C, Sinclair AJ: A double-blind, placebo-controlled parallel trial of vitamin C treatment in elderly patients with hypertension. Gerontology. 1994, 40: 268-272.
CAS PubMed Article PubMed Central Google Scholar
- 35.
Mullan BA, Young IS, Fee H, McCance DR: Ascorbic acid reduces blood pressure and arterial stiffness in type 2 diabetes. Hypertension. 2002, 40: 804-809. 10.1161/01.HYP.0000039961.13718.00.
CAS PubMed Article PubMed Central Google Scholar
- 36.
Ward NC, Hodgson JM, Croft KD, Burke V, Beilin LJ, Puddey IB: The combination of vitamin C and grape-seed polyphenols increases blood pressure: a randomized, double-blind, placebo-controlled trial. J Hypertens. 2005, 23: 427-434. 10.1097/00004872-200502000-00026.
CAS PubMed Article PubMed Central Google Scholar
- 37.
Duffy SJ, Gokce N, Holbrook M, Huang A, Frei B, Keaney JF, Vita JA: Treatment of hypertension with ascorbic acid. Lancet. 1999, 354: 2048-2049. 10.1016/S0140-6736(99)04410-4.
CAS PubMed Article PubMed Central Google Scholar
- 38.
Rodrigo R, Prat H, Passalacqua W, Araya J, Bachler JP: Decrease in oxidative stress through supplementation of vitamins C and E is associated with a reduction in blood pressure in patients with essential hypertension. Clin Sci. 2008, 114: 625-634. 10.1042/CS20070343.
CAS Article Google Scholar
- 39.
Plantinga Y, Ghiadoni L, Magagna A, Giannarelli C, Franzoni F, Taddei S, Salvetti A: Supplementation with vitamins C and E improves arterial stiffness and endothelial function in essential hypertensive patients. Am J Hypertens. 2007, 20: 392-397. 10.1016/j.amjhyper.2006.09.021.
CAS PubMed Article PubMed Central Google Scholar
- 40.
Ward NC, Hodgson JM, Croft KD, Burke V, Bellin LJ, Puddey IB: The combination of vitamin C and grape-seed polyphenols increases blood pressure: a randomized, double-blind, placebo-controlled trial. J Hypertens. 2005, 23: 427-434. 10.1097/00004872-200502000-00026.
CAS PubMed Article PubMed Central Google Scholar
- 41.
Schutte AE, Huisman HW, Oosthuizen W, van Rooyen JM, Jerling JC: Cardiovascular effects of oral supplementation of vitamin C, E and folic acid in young healthy males. Int J Vitam Nutr Res. 2004, 74: 285-293. 10.1024/0300-9831.74.4.285.
CAS PubMed Article PubMed Central Google Scholar
- 42.
Delles C, Miller WH, Dominiczak AF: Targeting reactive oxygen species in hypertension. Antiox Redox Sign. 2008, 10: 1061-1077. 10.1089/ars.2007.2008.
CAS Article Google Scholar
- 43.
Hou X, Roberts LJ, Taber DF, Morrow JD, Kanai K, Gobeil F, Beauchamp MH, Bernier SG, Lepage G, Varma DR, Chemtob S: 2,3-Dinor-5,6-dihydro-15-F(2t)-isoprostane: a bioactive prostanoid metabolite. Am J Physiol Regul Integr Comp Physiol. 2001, 281: R391-R400.
CAS PubMed Article PubMed Central Google Scholar
- 44.
Block G, Jensen CD, Morrow JD, Holland N, Norkus EP, Milne GL, Hudes M, Dalvi TB, Crawford PB, Fung EB, Schumacher L, Harmatz P: The effect of vitamins C and E on biomarkers of oxidative stress depends on baseline level. Free Radical Bio Med. 2008, 45: 377-384. 10.1016/j.freeradbiomed.2008.04.005.
CAS Article Google Scholar
- 45.
Bautista LE: Inflammation, endothelial dysfunction, and the risk of high blood pressure: epidemiologic and biologic evidence. J Hum Hypertens. 2003, 17: 223-230. 10.1038/sj.jhh.1001537.
CAS PubMed Article PubMed Central Google Scholar
- 46.
Block G, Jensen CD, Dalvi TB, Norkus EP, Hudes M, Crawford PB, Holland N, Fung EB, Schumacher L, Harmatz P: Vitamin C treatment reduces elevated C-reactive protein. Free Radical Bio Med. 2008, doi:10.1016/j.freeradbiomed.2008.09.030,
Google Scholar
- 47.
Levine GN, Frei B, Koulouris SN, Gerhard MD, Keaney JF, Vita JA: Ascorbic acid reverses endothelial vasomotor dysfunction in patients with coronary artery disease. Circulation. 1996, 93: 1107-13.
CAS PubMed Article PubMed Central Google Scholar
- 48.
Solzbach U, Hornig B, Jeserich M, Just H: Vitamin C improves endothelial dysfunction of epicardial coronary arteries in hypertensive patients. Circulation. 1997, 96: 1513-9.
CAS PubMed Article PubMed Central Google Scholar
- 49.
Heller R, Werner-Felmayer G, Werner ER: Antioxidants and endothelial nitric oxide synthesis. Eur J Clin Pharmacol. 2006, 62: 21-28. 10.1007/s00228-005-0009-7.
CAS Article Google Scholar
- 50.
Heller R, Munscher-Paulig F, Grabner R, Till U: L-Ascorbic acid potentiates nitric oxide synthesis in endothelial cells. J Biol Chem. 1999, 274: 8254-8260. 10.1074/jbc.274.12.8254.
CAS PubMed Article PubMed Central Google Scholar
- 51.
Huang A, Vita JA, Venema RC, Keaney JF: Ascorbic acid enhances endothelial nitric-oxide synthase activity by increasing intracellular tetrahydrobiopterin. J Bio Chem. 2000, 275: 17399-17406. 10.1074/jbc.M002248200.
CAS Article Google Scholar
- 52.
Heller R, Unbehaun A, Schellenberg B, Mayer B, Werner-Felmayer G, Werner ER: L-ascorbic acid potentitates endothelial nitric oxide sythesis via a chemical stabilization of tetrahydrobiopterin. J Biol Chem. 2001, 276: 40-47. 10.1074/jbc.M004392200.
CAS PubMed Article PubMed Central Google Scholar
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Acknowledgements
The study was supported by grants NO-HC-55023-26 and UO1-HL48941-44 from the National Heart, Lung and Blood Institute, National Institutes of Health, Bethesda Maryland. Data collection and analysis was supported by National Institute of Environmental Health Sciences grant P30 ES01896.
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Competing interests
The authors declare that they have no competing interests.
Authors' contributions
GB and CDJ participated in data analysis and manuscript development. EPN conducted laboratory analyses and participated in manuscript editing. MH participated in data analysis and manuscript editing. PBC participated in the design of the study and manuscript editing. All authors have read and approved the final manuscript.
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Block, G., Jensen, C.D., Norkus, E.P. et al. Vitamin C in plasma is inversely related to blood pressure and change in blood pressure during the previous year in young Black and White women. Nutr J 7, 35 (2008). https://doi.org/10.1186/1475-2891-7-35
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DOI : https://doi.org/10.1186/1475-2891-7-35
Keywords
- Blood Pressure
- Ascorbic Acid
- Systolic Blood Pressure
- Diastolic Blood Pressure
- Healthy Young Adult
Is Vitamin C Good For Low Blood Pressure
Source: https://nutritionj.biomedcentral.com/articles/10.1186/1475-2891-7-35
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