Ascorbic Acid to Coronary Artery Calcium

Relation of Ascorbic Acid to Coronary Artery Calcium

The Coronary Artery Risk Development in Young Adults Study

1. Joel A. Simon1,2,
2. Maureen A. Murtaugh3,
3. Myron D. Gross4,
4. Catherine M. Loria5,
5. Stephen B. Hulley2 and
6. David R. Jacobs Jr.4,6

 

Abstract

Ascorbic acid is an antioxidant nutrient possibly related to the development of atherosclerosis. To examine the relation between ascorbic acid and coronary artery calcium, an indicator of subclinical coronary disease, the authors analyzed data from 2,637 African-American and White men and women aged 18–30 years at baseline who were enrolled in the Coronary Artery Risk Development in Young Adults (CARDIA) Study (1985–2001). Participants completed diet histories at enrollment and year 7, and plasma ascorbic acid levels were obtained at year 10. Coronary artery computed tomography was performed at year 15. The authors calculated odds ratios in four biologically relevant plasma ascorbic acid categories, adjusting for possible confounding variables. When compared with men with high plasma ascorbic acid levels, men with low levels to marginally low levels had an increased prevalence of coronary artery calcium (multivariate odds ratio = 2.68, 95% confidence interval: 1.31, 5.48). Among women, the association was attenuated and nonsignificant (multivariate odds ratio = 1.50, 95% confidence interval: 0.58, 3.85). Ascorbic acid intakes from diet alone and diet plus supplements were not associated with coronary artery calcium. Low to marginally low plasma ascorbic acid levels were associated with a higher prevalence of coronary artery calcium among men but not among women.

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DISCUSSION

Overall, our study produced mixed findings. The main positive finding was that low to marginally low plasma ascorbic acid levels (measured at year 10) were associated with an approximately threefold higher prevalence of coronary artery calcium (ascertained at year 15) among men independently of other cardiovascular disease risk factors, including smoking. We did not, however, observe a similar relation among women, perhaps because fewer women had coronary artery calcium, thereby limiting our statistical power to detect such an association. We also cannot exclude the possibility that our findings resulted from chance or residual confounding. The findings among men concur with findings from cross-sectional and longitudinal analyses of participants in the Second National Health and Nutrition Examination Survey (NHANES II) (7, 15). Simon et al. (15) reported previously that NHANES II participants with low to marginally low serum ascorbic acid levels had an increased prevalence of self-reported coronary heart disease. In the NHANES II Mortality Study, which followed participants for a mean of 14 years, Simon et al. (7) found a trend toward increased cardiovascular disease mortality among individuals with low to marginally low serum ascorbic acid levels. Similar to our current findings, those from the NHANES II Mortality Study did not reflect a relation between dietary intake of ascorbic acid and cardiovascular disease endpoints (7).

                 

Our current findings are also consistent with results from some observational studies that also reported low blood ascorbic acid levels to be a risk factor for coronary heart disease (3–5, 8, 16, 17). Not all observational studies have reported such an association (6, 18), and the few randomized trials examining the effect of vitamin C supplementation on coronary heart disease endpoints, typically in combination with other antioxidants, have produced inconsistent results, ranging from decreased risk to no effect to increased risk (19–22). Specifically determining whether marginal vitamin C deficiency is a factor in the development of atherosclerotic coronary disease would be of considerable public health importance, since blood levels consistent with marginal deficiency are prevalent in the population (7) and readily modifiable.

                 

Conclusions based on our findings are qualified by limitations in the study design. We collected information on plasma levels of ascorbic acid 5 years before the coronary artery calcium measurement, but we do not have coronary artery calcium scores before year 15. Therefore, we cannot be certain that differences in plasma ascorbic acid preceded the development of coronary artery calcium since we cannot exclude the possibility that subclinical coronary disease lowered plasma ascorbic acid levels. The concern about the direction of causality is underscored in part because we were unable to find an association between dietary ascorbic acid intake (measured at baseline and year 7) and coronary artery calcium; that is, since blood levels of ascorbic acid are generally correlated with intake, a similar association between lower ascorbic acid intakes and coronary artery calcium would have been expected.

                 

There are several potential explanations for these findings. Because the dietary assessments were performed at baseline and year 7 and plasma ascorbic acid levels were assayed at year 10, we cannot exclude the possibility that dietary and supplement use changed during the intervening period, although we did find a weak, albeit statistically significant, correlation between dietary ascorbic acid intake and plasma ascorbic acid levels (r = 0.14; p < 0.0001). It is also possible that the dietary assessments were not sufficiently accurate or precise to permit the detection of the association. Prospective studies that examined dietary intake of ascorbic acid as a predictor of cardiovascular disease have produced contradictory results. An analysis of data from the First National Health and Nutrition Examination Survey Epidemiologic Follow-up Study found that individuals with the highest intakes of ascorbic acid had 25–50 percent lower cardiovascular disease mortality (23). Dietary ascorbic acid intake was also associated with a lower risk of coronary heart disease death among Finnish women (24) and a group of 747 noninstitutionalized elderly Massachusetts residents (25). The Nurses’ Health Study (26), the Health Professionals Follow-up Study (27), and others (28, 29), however, found no significant association between ascorbic acid intake and risk of coronary heart disease.

                 

Ascorbic acid may reduce the risk of cardiovascular disease by a number of mechanisms. Antioxidant status has been hypothesized to be an important factor in atherogenesis, and ascorbic acid is a highly effective water-soluble antioxidant capable of inhibiting lipid peroxidation (30, 31). In some studies, ascorbic acid blood levels and dietary intake have been associated with increased levels of high density lipoprotein cholesterol and decreased levels of total cholesterol (1, 32, 33). The inverse relation between plasma ascorbic acid levels and coronary artery calcium that we observed, however, was independent of cholesterol levels. Ascorbic acid promotes endothelial prostacyclin production (34), improves endothelium-dependent vasodilation (2), and is essential for vascular collagen formation, all factors that may be associated with cardiovascular disease risk. Despite the potential for ascorbic acid to lower the risk for cardiovascular disease, recent clinical trials using antioxidant cocktails that contain ascorbic acid have failed to lower cardiovascular disease risk (19–22). We are unaware, however, of clinical trials using ascorbic acid supplementation specifically among individuals with low to marginally low blood levels, our postulated high-risk group.

                 

In addition to the limitations discussed, we were also limited by having only a single measurement of plasma ascorbic acid, which may not reflect long-term plasma concentrations optimally. However, plasma ascorbic acid levels reflect at least the previous several months of dietary intake, even during periods of seasonal variation (35), and are strongly correlated with leukocyte ascorbic acid levels, an indicator of tissue ascorbic acid levels (36, 37). We cannot exclude the possibility that our findings were affected by residual confounding (especially from smoking) or that plasma ascorbic acid levels were simply a healthy diet or lifestyle marker. The association of low plasma ascorbic acid levels with higher prevalence of coronary artery calcium among men was, however, independent of the effects of other lifestyle-related variables, such as education and exercise.

                 

In conclusion, we found that low to marginally low plasma ascorbic acid levels were independently associated with a higher prevalence of coronary artery calcium in young adult men but not in young adult women. Because we cannot exclude chance or residual confounding as an explanation of our findings, our results need to be confirmed by other investigators.

 

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    Abstract/FREE Full ============================================================ Read the complete article here.

Looks like the same U-shaped curves of mortality vs total cholesterol applies to half a million Korean men, too. Look at how cancer goes up at the lower TC levels, and how low CHD is compared to all the other causes of death. A full-text pdf file is available.

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Which Cholesterol Level Is Related to the Lowest Mortality in Population with Low Mean Cholesterol Level: A 6.4-Year Follow-up Study of 482,472 Korean Men

Yun-Mi Song1, Joohon Sung2 and Joung Soon Kim3

1 Department of Family Medicine, SungKyunKwan University School of Medicine Suwon, Korea
2 Department of Preventive Medicine, College of Medicine, Seoul National University Seoul Korea
3 Department of Epidemiology, Graduate School of Public Health, Seoul National University Seoul, Korea
Received June 1, 1998.
Accepted December 16, 1998.

Abstract

To evaluate the relation between low cholesterol level and mortality, the authors followed 482,472 Korean men aged 30–65 years from 1990 to 1996 after a baseline health examination. The mean cholesterol level of the men was 189.1 mg/100 ml at the baseline measurement. There were 7,894 deaths during the follow-up period. A low cholesterol level (>165 mg/100 ml) was associated with increased risk of total mortality, even after eliminating deaths that occurred in the first 5 years of follow-up. The risk of death from coronary heart disease increased significantly in men with the highest cholesterol level (≥252 mg/100 ml). There were various relations between cholesterol level and cancer mortality by site. Mortality from liver and colon cancer was significantly associated with a very low cholesterol level (>135 mg/100 ml) without any evidence of a preclinical cholesterol-lowering effect. With lengthening follow-up, the significant relation between a very low cholesterol level (>135 mg/100 ml) and mortality from stomach and esophageal cancer disappeared. The cholesterol level related with the lowest mortality ranged from 211 to 251 mg/100 ml, which was higher than the mean cholesterol level of study subjects. Am J Epidemiol 2000; 151:739–47.

emphasis added by bd
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Read the full article here.

Deaths Due to Coronary Heart Disease in the Elderly

In a study published in the American Journal of Epidemiology, seven scientists concluded from the data that ...

" even a small increase in DTR is associated with a substantial increase in the deaths due to CHD."

In english that means that global warming has helped to significantly reduce the coronary heart disease death rate of the worlds elderly.

Read the complete study here.

The Dirty Little Secret of the Diet-Heart Hypothesis

I constantly keep my eye out for 'Credible Evidence' related especially to my own health issues which you should be able to tell if you have read this or any of the posts on this blog, is coronary artery disease.

I have just discovered Stephan Guyenet's blog Whole Health Source. In particular a recent post titled "The Dirty Little Secret of the Diet-Heart Hypothesis" was especially interesting to me and is well presented. I recommend you read it.

I will certainly be digesting more of what Stephan posts on his blog.

Graveline on "Behavior Change"

Another one of the good guys whom I have read and learned a lot from. I really suggest you get and read his book. I have.
"Statin Drugs - Side Effects and The Misguided War on Cholesterol".
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Low Cholesterol and Behavioral Change

Among the side effects reported from statin drug use have been a broad complex of emotional and behavioral symptoms. Case reports by anxious patients, concerned family members of caregivers have included aggressiveness, hostility, irritability, paranoia, road rage type outbursts, homicidal ideation, severe depression resistant to most therapies and as a natural follow-on to depression, a number of suicides have been reported where family members assert vehemently that, “It was the statin that did it.”

Dolichol inhibition is suspected as a major contributor to such behavioral change because of its established role in neuropeptide formation, where it orchestrates the processes of peptide strand formation in the endoplasmic reticulum and Golgi apparatus.

Imagine, every thought, sensation or emotion we have ever had, dependant upon the make-up of this protein linkage, comparable to popcorn on a string, where everything depends upon what protein and what position it has. There is no doubt about this important role of dolichols. Nor is there any doubt about dolichol inhibition with statin drug use. Just as cholesterol synthesis is inhibited by reductase inhibitors of the mevalonate pathway, so must dolichols (and CoQ10) for their formation depends upon the integrity of this same pathway. The finding of emotional and behavioral consequences of statin drug use should come as no surprise for dysfunction of dolichol managed pathways seems all but inevitable.

Additionally, that low cholesterol plays an important role in cognition and behavior independent of glial cell inhibition, is now well known to exist via the seleno-protein pathway. When disrupted this pathway leads to cognitive dysfunction as well as myopathy.

Now we find a study on the American Journal of Epidemiology by Zhang, Muldoon and others (yes, the same Muldoon having reported 100% cognitive dysfunction among statin users) reporting on the association of low serum cholesterol with negative mood, decrements of cognitive function and various types of aggressive behavior in adolescent children.

This association is not minor and was based upon detailed and well-controlled studies of a large population group and, surprisingly, existed only for the non-African-American segment of the group studied. When all the possible confounding factors were accounted for, the tendency for violence and aggressiveness persisted among Caucasian children and adolescents.

The authors report an across the board correlation of low cholesterol with many other studies including those with conduct disorders, violent behavior, criminals and psychiatric patients and even controlled dietary studies of non-human primates, reflecting on a species correlation. The result is a strong positive correlation between low cholesterol and aggressiveness.

So, if a surprisingly large segment of our society is already aggression prone because of low serum cholesterol, can you imagine the effect of wide scale use of statins to lower the cholesterols even more?

Duane Graveline MD MPH
Former USAF Flight Surgeon
Former NASA Astronaut
Retired Family Doctor