Nowadays consumers are increasingly concerned about the quality and safety of many products of industrialized countries, in particular the use of artificial sweeteners, flavorings, colorings, preservatives and dietary supplements. General apprehension also exists regarding the possible long-term health effects of the raw materials and technologies used for the packaging, sterilization and distribution of foods. Many non-nutritive sweeteners have been used in foods and beverages to allow people to enjoy the sweet taste without consuming sugar-associated calories. One of these sweeteners is aspartame. This sweetener is incorporated into a number of foodstuffs (drinks, desserts, sweets, etc.) and in table sweeteners, under different brand names and into some 600 medicines.1 Its sweetening power is 180–200 times greater than that of sucrose.2 Because it contains no calories, aspartame is considered a boon to health-conscious individuals everywhere; a recent observation indicated that aspartame is slowly making its way into ordinary products used every day, which do not carry any indication as being for people on diets or diabetic patients. Aspartame in dry products is fairly stable even at high temperatures. However, in solution, its stability is a function of time, temperature, pH and available moisture. Aspartame is most stable between pH values of 3 and 5, even with increasing temperature.3 However, it breaks down and loses its sweetness in normal cooking or baking. Thus its use is limited to a table-top sweetener (Equal®TM – The NutraSweet Co., Deerfield, IL) and as NutraSweet in dry foods, soft drinks, and frozen foods like ice cream. It is slightly soluble in water (about 1.0% at 25°C), sparingly soluble in alcohol and insoluble in fats and oils. Being a peptide, it is amphoteric and is metabolized extensively to release its constituent amino acids and methanol.3 Upon ingestion, this artificial sweetener is immediately absorbed from the lumen and metabolized by gut esterases and peptidases to phenylalanine, aspartic acid and methanol. Orally ingested aspartame components are immediately absorbed from the lumen and reach the portal blood in a manner similar to that of amino acids arising from dietary protein or polysaccharides.4,5 Their concentrations are found increased in the blood stream.6 This sweetener and its metabolic breakdown products (phenylalanine, aspartic acid and methanol) have been a matter of extensive investigation for more than 20 years, including experimental animal studies. Ten per cent of aspartame consists of methanol. Methanol is a toxicant that causes systemic toxicity.7 The primary metabolic fate of methanol is the direct oxidation to formaldehyde and then into formate. The severity of clinical findings in methanol intoxication correlated better with formate levels.8 Methanol is gradually released in the small intestine when the methyl group of aspartame encounters the enzyme chymotrypsin,4 but methanol is more readily generated by the body (thus becoming even more dangerous) when it is heated above 30°C before being ingested. This occurs when soft drinks are left out in the sun or foods containing aspartame are heated. Methanol breaks down into formaldehyde and formic acid in the body. Formaldehyde is an embalming fluid, as a preservative in vaccines and a deadly neurotoxin. Formic acid causes cells to become too acidic, thereby producing metabolic acidosis. Acidosis damages cellular health by causing enzymes to stop functioning. Oxidative stress arises from the imbalance between pro-oxidants and antioxidants in favor of the former, leading to the generation of oxidative damage.9 Generation of free radicals is an integral feature of normal cellular functions, in contrast, excessive generation and/or inadequate removal of free radical results in destructive and irreversible damage to the cell.10 A stressor is a stimulus that is either internal or external, which activates the hypothalamic pituitary adrenal axis and the sympathetic nervous system resulting in a physiological change11 Corticotropin-releasing hormone is released during stress and stimulates the release of adrenocorticotropic hormone,12 which in turn releases corticosterone from the adrenal cortex. Elevation in the corticosterone level accelerates the generation of free radicals13 and alters the normal homeostasis of organ.14

Cytokines belong to the family of signaling molecules. They are released by specific cells of the immune system. Cytokines are small glycoprotein chemical structures that act in a paracrine and endocrine fashion as soluble signals between cells and play a pivotal role in the immune response. They are the hormonal messengers responsible for most of the biological effects in the immune system, such as cell-mediated immunity and humoral immunity. T lymphocytes are a major source of cytokines. Immune cells produce mediators of inflammatory and immune reactions called cytokines. These low-molecular weight glycoproteins in small concentrations are indispensable for normal functioning of the immune system. Their excessive secretion, however, leads to immune cell dysfunctions. Inflammatory cytokines may be produced by mononuclear cells of the immune system in response to numerous agents, such as microorganisms and their products (e.g., lipopolysaccharide – LPS)15,16 as well as some xenobiotics.17 It is postulated that xenobiotics can influence the concentrations of inflammatory cytokines through oxidative stress mechanisms.18–20 The experimental and epidemiological data currently available to evaluate the above toxigenic risks of aspartame are insufficient and often unreliable, due to the inadequate planning and conduct of previous experiments. Recently from previous studies on aspartame and its metabolite, altering the oxidative status of the cells was investigated. Oral aspartame (75mg/kgbody weight/day) consumption causes oxidative stress in brain21 and its (40mg/kgbw/day) consumption caused oxidative stress in brain,22 liver and kidney,23 and also in immune organs.24 This inadequacy, combined with the general limited knowledge about the safety/potential toxigenic effects of substances widely present in the industrialized diet, motivated the design of the current study. However, little is known about the effects of aspartame on cytokine expression. The detailed mechanisms of the effects of aspartame on cytokines are still unclear; therefore, the present study aimed at clarifying whether longer time of aspartame consumption has any effect on cytokine expression in serum of Wistar albino rats.

Data are expressed as mean±standard deviation (SD). All data were analyzed with the SPSS for windows statistical package (version 20.0, SPSS Institute Inc., Cary, North Carolina, USA). Statistical significance between the different groups was determined by one-way analysis of variance (ANOVA). When the groups showed significant difference, then Tukey's multiple comparison tests were followed and the significance level was fixed at p<0.05.

A homeostatic balance exists between the formation of free oxygen radicals and their removal by endogenous scavenging antioxidants.44 In this study, the folate-deficient diet-fed animals were used to mimic the human methanol metabolism. However, the folate-deficient diet-fed animals did not show any significant changes in the parameters studied and remained similar to controls animals. The increase in corticosterone level indicates that aspartame may act as a chemical stressor. Changes in membrane disruptions, as by increased lipid peroxidation and nitric oxide, indicate free radical production,45 which is a potent source of oxidative injury.46 Increased corticosterone along with free radical production can lead to suppression of immune system and can alter the release of cytokines. Cytokines are glycosylated polypeptides that are secreted and influence the action of immune cells.47 Cytokines, the chemical messengers between immune cells, play crucial roles in immune response.48 Cytokines are released to the location of inflammation induced by pathogens or tissue damage and facilitate the arrival of neutrophils, monocytes and other cells involved in antigen clearance and healing the tissue.49,50 Leukocyte mobilization into the blood stream in response to cytokines is well documented.51,52 The local production of these molecules coordinates the function of innate and adaptive immune cells. T cell population responses to antigens extensively after immunization.53,54

Oxidative stress refers to a disturbance in the balance between the production of reactive oxygen species (ROS) and antioxidant defences;55 abnormally high levels of free radicals and the simultaneous decline of antioxidant defence mechanisms can damage cellular lipids, proteins or DNA inhibiting their normal function. The three primary scavenging enzymes involved in detoxifying the free radicals in mammalian systems are SOD, CAT and GPx.56 SOD dismutases the highly reactive superoxide anion to the less reactive species H2O2.57 CAT and GPx efficiently react with H2O2 to form water and molecular oxygen.58,59 GSH has a multifactorial role in antioxidant defence. It is a direct scavenger of free radicals as well as a co-substrate for peroxide detoxification by glutathione peroxides.60 Ascorbic acid, well known as a potent water-soluble antioxidant, effectively intercept oxidants in the aqueous phase before they attack and cause detectable oxidative damage.61 Cytokines belong to the signaling molecules and have an important task in cellular communication. They are critical for the development and function of innate and adaptive immune responses. On the basis of their pattern of cytokine synthesis, CD4+ Th (helper) cells were originally classified into Th1 and Th2 lymphocytes,62 which are involved in cellular and humoral immune responses, respectively.63 The cytokines produced are known as Th1-type cytokines and Th2-type cytokines. Type 1 helper T cells are characterized by the production of Th1-type cytokines (IL-2, TNF-α and IFN-γ,) Th1 cells are involved in cell-mediated immunity.64 Type 2 helper T cells are characterized by the production of Th2-type cytokines (IL-4). Th2 cells are thought to play a role in humoral immune responses.65 Cytokines like IL-4 generally stimulate the production of antibodies. Improved understanding of Th1 and Th2 differentiation will improve our overall understanding of the immune system. The plasma release of both Th1-type and Th2-type cytokines unbalance the immunity. Leukocyte mobilization into the blood stream in response to cytokines is well documented.51,52 It has been shown that IL-4 is an essential differentiation factor for Th2 cells.66 Oxidative stress might induce IL-4 production by mast cells and basophils and direct the Th2 cell differentiation.67 IL-4 may be considered as a pro-oxidative cytokine that can increase the oxidative potential of target cells.68 IL-4 induced the generation of ROS such as superoxide anion and hydrogen peroxide.69 This imbalance between oxidants and antioxidants favors skewing of the Th2 immune response while suppressing Th1 differentiation.70 The results of present study seem to suggest that the aspartame metabolite methanol or formaldehyde may be involved in inducing oxidative stress in serum and in changes of cytokine secretion where Th1 cytokines are down-regulated and Th2 cytokines are up-regulated, which may alter cell and humoral immunity. This report is strengthened by previous published studies by Parthasarathy et al.,71 where methanol intoxication alters immune function.

The results of the present study clearly point out that increasing corticosterone levels indicate that aspartame acts as a chemical stressor and that aspartame metabolite could accelerate lipid peroxidation leading to an increase in oxidative stress and altered cytokine secretion. It suggests that the dysregulation of cytokines is the result of an imbalance in Th1 and Th2 cells and can have important implications during the development of immune responses which may alter immune function. Aspartame metabolites methanol or formaldehyde may be the causative factors behind the changes observed. More insight is needed to elucidate the precise molecular mechanisms involved in these changes.