Introduction
Current scientific evidence indicates that oxidative stress is directly involved in the onset and development of chronic, non-communicable diseases such as cardiovascular disease, rheumatoid arthritis, and some neurodegenerative diseases like Alzheimer's and Parkinson’s (Luc & Fruchart 1991, Darlington et al. 2001, Pulido et al. 2005, Sharma et al. 2008). The oxidative stress involved in the pathogenesis of these diseases is a consequence of the increased production of free radicals (FR) and the inability of the human body’s antioxidant systems to counteract the negative effects (Rao et al. 2011) leading to tissue damage, a product of the oxidative alteration of macromolecules such as lipids and DNA (Diplock et al. 1998).
These antioxidants systems are made up of both endogenous molecules in the body such as superoxide dismutase and glutathione reductase enzymes, bilirubin and uric acid (Sen et al. 2010), and substances of exogenous origin present in foods such as vitamins, minerals, and polyphenols (Diplock et al. 1998). Together, these substances are the defense mechanisms against FR attacks.
Among the different antioxidants of exogenous origin is vitamin A. This vitamin was first labeled as a suppressor of the effect of linoleic acid on the oxidation processes (Monaghan et al. 1932). Currently, vitamin A and carotenoids are known for their antioxidant activity based on their ability to interact with radicals and prevent lipid peroxidation of the cell (Palace et al. 1999). Ascorbic acid is both a reducing agent that loses an electron to generate a relatively stable radical (Gil 2010) and a regenerator of vitamin E that after oxidation produces tocopherol (Jayachandran et al. 1996). Tocopherol is a primary lipophilic antioxidant that inactivates peroxyl radicals through the direct transfer of a hydrogen atom (Niki 2014) and protects tissue lipids from the damage produced by free radicals (Febles et al. 2009).
Various studies suggest that increased consumption of fruits and vegetables reduces the risk of oxidative stress-related diseases, attributing this benefit to the high content of antioxidant compounds in these foods (Steinmetz et al. 1996, Knekt et al. 2002). Moreover, an increase in the consumption of foods rich in antioxidants such as vitamins and polyphenols increases the total antioxidant capacity (TAC) (Vieira et al. 2012) and reflects the joint action of the various individual antioxidants in plasma (Ghiselli et al. 2000).
While recognizing the importance of antioxidant compounds of exogenous origin and their function against the harmful effects of FR, the objective of this study is to determine whether taking vitamins A, C, and E is associated with antioxidant levels in a group of individuals over fifty.
Materials and methods
Population
The population of this study was 118 adults over the age of 50 (108 women and ten men) and all participate named Healthy and Active Individuals of the Departmental Institute of Recreation and Sports Seniors Program (DIRS) located in Usme, in the city of Bogotá, Colombia. The data of the participant were obtained in the initial phases of the "Effects of the Consumption of Hybrid Palm Oil and Extra Virgin Olive Oil on Emerging and Traditional Cardiovascular Risk Factors” study (Mozzon et al. 2013, Lucci et al. 2016). This study was conducted in compliance with the guidelines of the Declaration of Helsinki. The institutional ethics committee of the Universidad Pontificia Javeriana in Bogotá approved all of the procedures involving human subjects (Law No. 11, 21-06- 2011).
Consumption Evaluation
To determine the consumption of vitamins A, C, and E, each of the study participants had two 24-hour recalls and a food frequency recall obtained from the previously mentioned research study in which all the participants partook.
For this study, we analyzed the 24-hour recalls, which were obtained on the same day that blood was drawn from the participants to be subsequently evaluated for plasma antioxidant capacity.
Food intake information was obtained from each participant’s 24-hour recall sheet and vitamin A and C consumption was determined using food composition tables from the Nutritional Care Center in Medellin, Colombia and the Colombian Institute of Family Welfare. Vitamin A was reported in retinol equivalents and vitamin C in mg. Vitamin E was also reported in mg; however, its analysis considered the reported values in the USDA National Nutrient Data Base for Standard Reference, bearing in mind that the values in this database, for the same food, was similar (90-110 %) to the energy and nutrient supply values reported in the Medellin Nutritional Care Center’s food composition table.
Plasma antioxidant capacity
Blood samples from each study participant were obtained on an empty stomach to determine the antioxidant capacity and the plasma concentration of phenols. These procedures were performed as a part of the previously mentioned research study in which each of the participants participated.
The methods used to obtain antioxidant levels were ORAC (Oxygen radicalabsorbance capacity) (Cao et al. 1995) and TEAC (Trolox Equivalent Antioxidant Capacity) (Miller et al. 1993). Plasma phenol quantification was achieved employing the Folin-Ciocalteu (Singleton et al. 1965) methodology.
Using the data obtained in the initial phases of the "Effects of the Consumption of Hybrid Palm Oil and Extra Virgin Olive Oil on Emerging and Traditional Cardiovascular Risk Factors” study, we obtained the antioxidant capacity values by TEAC for 118 participants. Using ORAC, we obtained values for 114 participants and quantified phenols for 117 individuals (Ojeda et al. 2016).
Statistic analysis
The tabulation of information was completed using Excel 2007. The statistical program IBM SPSS Statistics 21 was used to analyze the variables of vitamin A, C, and E antioxidant levels and the concentration of phenols in plasma.
Normal distribution was checked using the Kolmogorov-Smirnov test. Correlation analysis was performed using the Spearman test for variables that did not meet the assumptions of normality and the Pearson test when both variables had a normal distribution. The value of p<0.05 was considered statistically significant.
Results
Quantitative analysis of vitamin consumption
In the end, 118 24-hour recalls were evaluated. According to the results, the average consumption of both vitamin A and C met the recommendations stipulated in the Dietary Reference Intakes (DRI) tables for both men and women. However, in neither group did the consumption of vitamin E reach the minimum recommended levels.
Antioxidant capabilities and plasma phenols quantification
Table 1 shows the means for the different measurement techniques used to gauge antioxidant capacity and quantify plasma concentrations of phenols. Note that 118 results were obtained using the TEAC method, 114 using ORAC, and 117 with RCF.
Vitamin consumption and antioxidant capacity using the TEAC method
Table 2 shows a positive correlation between the consumption of vitamin A, C, and E and the antioxidant capacity of plasma measured using the TEAC method. However, the value of p for the three tests was greater than 0.05; these results are not statistically significant.
Vitamin consumption and antioxidant capacity using the ORAC method
Table 3 shows a positive correlation between the consumption of vitamin A and C and antioxidant capacity measured using the ORAC method. A negative correlation is evidenced by the consumption of vitamin E. However, none of the results displayed was statistically significant.
Vitamin consumption and quantification of phenolic content
According to the results presented in Table 4, there is a positive correlation between the consumption of vitamin A and E and the quantification of phenols in plasma measured by RFC. However, the p-value for both tests was >0.05 yielding statistically non-significant results. As for vitamin C, there was no correlation observed with plasma concentration of phenol levels.
Discussion
Currently, efforts to understand the ability of free radicals to directly influence the development of different pathological processes, especially those related to chronic, non-communicable diseases such as cardiovascular disease and neurodegenerative diseases, have targeted a specific line of research aimed at finding mechanisms that protect the body from oxidative damage (Luc & Fruchart 1991, Gale et al. 2001).
Epidemiological studies suggest that increased consumption of antioxidant- rich foods, such as fruits and vegetables, directly and positively influences plasma antioxidant capacity, while recognizing that this concept comprises the synergistic action of all antioxidants in body fluids, whether endogenous or exogenous (Wang et al. 2012, Kolomvotsou et al. 2012).
Using the ORAC method in young and senior adults, experimental studies have determined that increasing the consumption of fruits and vegetables to 5-10 servings per day for 15 days, positively influences the levels of antioxidant capacity (Cao et al. 1998). These results show that by eating certain foods, the body benefits from additional antioxidants of exogenous origin.
The results obtained in this study found that the average intake of vitamin E in seniors over 50 years do not meet the recommendations stipulated in the DRI, for both men and women. A negative correlation was found between the intake of vitamin E relative and the plasma antioxidant capacity measured by the ORAC method. This result is comparable to a previous study by Wang et al (2012) that also reported a negative correlation when analyzing antioxidant capacity versus Vitamin E consumption, and notably, a strong association between plasma a-tocopherol levels and the antioxidant capacity of plasma. The previous underscores not only the importance of consuming a nutrient, but also the importance of complying with
the recommendation (Recommended Dietary Albwance: 15mg vitamin E/day) to achieve optimal metabolism. On the other hand, the interaction between different antioxidants contained in food or diet must also be considered. At the time of consumption, a synergy may or may not exist thus influencing the effect of vitamin C on alpha- tocopherol (vitamin E) absorption (Pineda et al. 1999).
Using the TEAC method, we found a statistically non-significant positive correlation between the consumption of a-Tocopherol and antioxidant levels. This result is consistent with a study by Talegawkar et al (2009) that found no significant association between the two. However, the mentioned study stresses that large intakes of vitamin E increased performance in antioxidant capacity; this behavior was observed in individuals in the study group averaging a consumption of 285mg/d of a-Tocoferol.
The low correlation reported between antioxidant capacity levels and the consumption of vitamin E could be attributed to an inadequate intake of this nutrient, which was lower than the recommended amounts according to age and sex; this leads to a long-term impairment in antioxidant capacity.
A very low correlation was observed between vitamin C consumption and the levels of antioxidant capacity obtained both by TEAC and ORAC. This result is contrary to what is stated in a study by Talegawkar et al (2009) in which higher levels of antioxidant capacity were observed as the consumption of vitamin C increased (Talegawkar et al. 2009).
However, previous studies show that the increase in antioxidant capacity after consuming strawberries and spinach is attributed only in 8-14% to vitamin C content in these foods. Therefore, it is various phenolic compounds that are primarily responsible for the increased plasma antioxidant capacity and not vitamin C (Cao et al. 1998).
With regard to vitamin A, a positive correlation was observed between the consumption of this nutrient and the antioxidant capacity measured by TEAC and ORAC. However, none of the results were statistically significant. This result differs from the findings of an earlier study by Meydani et al (1994) that reported an increased antioxidant capacity in elderly women after receiving ^-carotene supplements. It’s worth noting that the present study evaluated the antioxidant capacity based on the intake of vitamin A product of a daily diet and not accompanied by supplements as in the aforementioned study.
Lastly, we observed a non-statistically significant positive correlation between vitamin A and E and the results obtained using the RFC methodology. Additionally, the null relationship between these results and the levels of vitamin C consumed. This finding is easily explained by the nature of the method used. This methodology is exclusively for the measurement of phenolic compounds, which are essential in determining antioxidant capacity; however, none of the nutrients analyzed are substances of phenolic nature (Miniati 2007).
The intake of vitamin A, C, and E did not show a statistically significant correlation with regard to the levels of plasma antioxidant capacity as observed in the present study. This result is consistent with previous studies as published by Pellegrini et al. in 2000 in which it was concluded that after eating tomatoes, a food high in lycopene, the antioxidant capacity of plasma of these individuals was not affected. Likewise in another study, Li L et al. (2010) concluded that after giving lutein supplementation to healthy adults between 50 and 70 years, these showed no change in markers of antioxidant activity and lipid peroxidation, indicating that increase of antioxidant concentrations in a healthful diet does not affect the levels of plasma antioxidant capacity in normal healthy subjects when the amounts of antioxidants already are adequate. These helps support the claim that intake levels not directly related to the levels of antioxidant capacity in healthy adults.
We can conclude that quantifying intake is perhaps not an adequate predictor of levels of plasma antioxidant capacity; this does not however mean that it has no influence. It is important to emphasize that existing literature reports a positive relationship between the antioxidant capacity and plasma levels of nutrients (Wang et al. 2012, Meydani et al. 1994) as well as between their intake and their plasma concentration levels (Mitmesser et al. 2000). Thus, the consumption is an adequate predictor of nutrient serum levels, which, in turn, are a reflection of the antioxidant capacity of plasma, when the vitamins (A, E and C) are measured directly in plasma.