INTRODUCTION
Obesity is defined as a chronic multifactorial disease characterized by abnormal or excessive fat accumulation that represents a risk to health1,2.
Genetic and behavioral aspects are the main etiological factors.
Obesity is known to be a risk factor for cardiovascular diseases (CVD)3,4, the main cause of death worldwide, caused mainly by atherosclerosis. Atherosclerosis involves the deposition of cholesterol and other lipids on arterial walls, followed by inflammation and fibrosis, which increase arterial wall thickness and protrude into the vessel lumen, thus affecting normal irrigation. Studies suggest that periodontitis may influence the development of atherosclerosis5,6. In addition, studies report that obese individuals with periodontal disease may have an increased risk of cardiovascular events7. The biological plausibility is that both conditions lead to prothrombotic and proinflammatory conditions8. Some animal studies have evaluated the correlation between periodontal disease and obesity regarding atherosclerotic events, reporting diverse results9,10 This study aims to evaluate aortic wall thickness, taken as an indicator of atherosclerosis, in rats exposed to induced periodontal disease (PD) and/or obesity (OB). We intend to contribute to assessing periodontal disease as an additional risk factor for the development of atherosclerosis.
MATERIALS AND METHODS
Study design and ethical considerations
This is a secondary analysis of a blinded, randomized, controlled animal model study11. The Animal Research Reporting In Vivo Experiments (ARRIVE) guidelines were followed12. The research protocol was approved by the Animal Research Ethics Committee of the Hospital de Clínicas de Porto Alegre, Brazil (protocol number 110051 at 26/04/2011). Fig. 1 shows the study flowchart.
Animals
We used sixty male 60-day-old Wistar rats, weighing approximately 350g each. Animals were housed in groups of 4-5 under a 12-hour light/dark cycle at room temperature (22°C ± 2°C) with free access to water and the assigned diet. Two animals were lost during the experimental period, (one from Group CT and one from Group OB), for reasons unrelated to the protocol, as confirmed in the necropsies.
Randomization and allocation to groups
All animals were weighed and arranged in ascending order according to weight. Based on the distribution of this weight, rats were stratified into tertiles and randomized into 4 experimental groups, as follows:
Control (CT): received standardized rat chow diet and water.
Periodontal Disease (PD): exposed to ligature-induced periodontal disease in the upper right 2nd molar, with the same diet as CT.
Obesity (OB): obesity induction using a high-fat hypercaloric cafeteria diet (CAF).
Obesity and Periodontal Disease (OB+PD): exposed to obesity and periodontal disease induction, as described in Groups OB and PD.
Cafeteria diet-induced obesity
The CAF diet, used to induce obesity in rats, was composed of 55% carbohydrates, 20% lipids, 20% protein and 5% other constituents (sodium, calcium, vitamins, preservatives and minerals, among others). This high-calory diet included condensed milk, soda, sandwich cookies, wafer, sausage, cheese and ham snacks, provided at libitum following the criteria of Sampey et al.13 The control group animals were fed with standard chow. Water was available ad libitum for all groups. The CAF diet model is able to raise body weight and glucose levels, and to cause hyperlipidemia13. All foods were replaced daily to ensure freshness.
Body weight and Lee index assessments
Animals were weighed on an electronic scale. The Lee index method14 was applied for rapid, accurate measurement of obesity in the groups fed on the cafeteria diet. The Lee index was calculated by dividing the cubic root of the body weight in grams by the naso-anal length in centimeters and multiplying by ten.
Periodontal disease model
At week 12, after groups under CAF diet had acquired obesity, periodontal disease was induced by placing a silk ligature on the maxillary right second molar, under general anesthesia with inhaled 5V% isoflurane (Isoforine™ Cristalia, SP, Brazil) vaporized in 100% oxygen by facemask. All anesthetic procedures were performed by a veterinarian. The contralateral molar was used as intra-group control.
Specimen preparation
Animals were euthanized by decapitation 30 days after placing the ligature. Maxillaries were removed, sectioned, and de-fleshed in 9% sodium hypochlorite for 2 hours. The aortic arteries were carefully removed, washed abundantly with saline solution and fixed with 10% buffered formalin for histological processing.
Alveolar bone loss morphometric analysis
Morphometric analysis was performed using standard digital photographs. Pictures were taken using a 6.1-megapixel digital camera (Nikon™ Coolpix, Ayutthaya, Thailand) attached to a tripod and equipped with 100 mm macro-lenses with minimal focal distance. Specimens were fixed to an endodontic ruler, parallel to the ground. Photographs were taken of the buccal and palatal aspects of right and left hemimaxillae.
Linear distances were measured from the cemento enamel junction to the bone crest, using Adobe Photoshop™ CS4 software (Adobe Systems Inc., San Jose, CA, USA). An external researcher kept track of the groups to ensure that the examiner was blinded to them. Five measurements were taken on each surface of the second molar, both buccally and palatally (two on the distal root, two on the mesial root and one on the furcation). The measurements in pixels were converted into millimeters using the markings of the endodontic ruler to which the hemimaxillae were attached as reference.
Histometric analysis of aortas
The aortas were sectioned into four parts and embedded in paraffin, and 3 mm sections were cut for hematoxylin and eosin staining. Microphotographs were taken at 100x magnification. The aortic wall (including intima and media) was measured (mm) by means of ImageJ software. The thickest point of each section was selected for measurement. The examiner was blinded to group allocation during histometric analysis.
The examiner was calibrated before starting the histometric analysis. Twenty percent of the aorta slides were selected randomly and the examiner measured them twice, with a one-week interval between measurements. Their means were compared using Pearson's correlation coefficient. The absence of a statistically significant difference between means was considered an indication of reproducibility. The intra-class correlation coefficient was 0.61.
Statistical analysis
For each evaluated parameter, normality was tested by Shapiro-Wilk test, and the appropriate statistical test was selected according to this assumption. Mean and standard deviation (SD) of body weight and Lee index were compared by Repeated Measurements one-way ANOVA followed by Bonferroni. Alveolar bone loss did not have symmetric distribution, therefore the data was evaluated by Kruskall Wallis followed by Dunn multiple comparison test and expressed in median and interquartile range. Aortic wall thickness was analyzed by one-way ANOVA, followed by Bonferroni's multiple comparison test. The level of significance was set at 0.05.
RESULTS
Obesity parameters
Body weight increased in all experimental groups (Fig 2). As from week 10, body weight was significantly higher in Groups OB and OB+PD than in Groups CT and PD.
Until week 12, the Lee index increased significantly in Groups OB and OB+PD (Fig 3). In addition, a significant interaction among groups and between time and groups (P<0.01) for this index was demonstrated by Repeated Measurements ANOVA.
Alveolar bone loss
As expected, alveolar bone loss was significantly higher in groups with induction ligatures (PD and OB+PD) than in groups without induction (Fig. 4). Interestingly, bone loss was 18% higher in Group OB+PD than in Group PD. (p<0.001).
Aortic wall thickness
Table 1 shows aortic wall thickness values. CAF diet induced significant increases, independently of the presence of periodontal disease. Statistically significant differences were found between OB and CT (p=0.036), OB+PD and PD (p=0.004), and OB and PD (p=0.001). No statistically significant difference was observed between CT and PD or between OB and OB+PD.
DISCUSSION
The present study evaluated aorta wall thickness and its relation to obesity and/or periodontal disease in Wistar rats. The rationale for such a study is that the inflammatory response of periodontal disease could be an additional factor in the pathogenesis of cardiovascular diseases, triggering atherosclerosis. The results demonstrated that obesity was able to increase aorta wall thickness; however, periodontal disease was not an additional modifier of wall thickness.
Cardiovascular diseases (CVD) have high morbidity and mortality rates worldwide1. It has been well established that atherosclerosis is the main factor in CVD etiopathogenesis. It is important to evaluate possible risk factors in addition to the established ones, and to ascertain whether they may worsen these health conditions. This would be helpful for establishing preventive and therapeutic strategies.
Atherosclerosis involves inflammatory responses which have been related to other inflammatory conditions such as periodontal disease and cardiovascular risk factors, including obesity, smoking, sedentary lifestyle, dyslipidemia and diabetes15, all of which could increase the inflammatory burden and change the arterial endothelial function, which is the first stage of atherosclerosis. It has also been suggested that overweight and obesity may be associated with periodontal disease16. However, the exact biological process underlying this relationship has not yet been established.
Clinical studies using true outcomes such as myocardial infarction or even death are scarce and subject to ethical restraints. Animal studies are thus warranted. This study used Wistar rats, which are widely used in both periodontal and cardiovascular studies. The experiment induced obesity by feeding rats on cafeteria diet, which mimics the western diet, with high carbohydrate and fat intake. This diet has been used in a previous study.13 This kind of model has also been used in the study of pathogenesis of periodontitis and its association with metabolic abnormalities 1718.
In the first 12 weeks, before ligature placement, Groups OB and OB+PD were fed cafeteria diet, which led to obesity131718. Body weight and Lee index values were used as methods to infer obesity. At baseline, the rats weighed approximately 350g, with no statistically significant difference among groups. Body weight increased in all groups; however, as from week 10, the rats which received CAF diet had statistically significant higher body than Groups CT and PD. Additionally, the Lee index increased significantly in groups fed on cafeteria diet. Even though studies suggest that periodontitis may stimulate obesity by secretion of proinflammatory cytokines18, no significant differences were observed between OB and OB+ PD with regard to body weight or Lee index in our study. Two parameters - body weight and Lee index - both showed that obesity occurred in the groups fed on CAF diet, thereby enabling the objectives of comparing how obesity and/or periodontal disease relates to potential negative cardiovascular outcomes.
Periodontal disease induction was effective, as shown by the mean values for alveolar bone loss which were considerably higher in the groups in which ligature was placed. Furthermore, alveolar bone loss was higher in Group OB+PD than in PD groups. These results corroborate previous findings reported by Verzeletti et al.18. These data suggested that in the presence of ligature, obesity acted as a synergistic factor in bone loss of inflammatory origin. A possible explanation for this synergism is that the continuous release of cytokines derived from the subclinical chronic inflammation which is characteristic of obesity may exacerbate other local inflammatory responses such as periodontal disease19.
Aortic walls were thicker in Groups OB and OB+PD than in Groups CT and PD. This supports the concept that obesity increases aorta wall thickness, thereby increasing the chances of CVD. Induction of obesity by hypercaloric and hyperlipidic diet in Wistar rats produces major metabolic alterations, such as an increase in triglycerides. For this reason, the use of this model was suggested to investigate endothelial dysfunction20, which is one of the factors which impact the pathogenesis of atherosclerosis. Our measurement method proved to be effective to show an increase in aortic thickness of the rats which received the CAF diet. Similarly, other authors also observed increased aortic wall thickness in rats exposed to a high-fat content diet different from CAF.21.
In our model, periodontal disease did not modify the effect of obesity by either increasing or decreasing aortic wall thickness. There are several possible explanations for this, some of which would be worthwhile studying further. Firstly, the ligature was placed on only one tooth, which may produce a low inflammatory challenge compared to extensive periodontal disease. Secondly, aortic wall thickness is extremely variable but was only measured at one point. Nevertheless, the supporting literature is sufficient to warrant further studies of the relationship between periodontal diseases and CVD, in order to better guide preventive and therapeutic strategies. Furthermore, it should be highlighted that periodontal and cardiovascular diseases share risk factors, and should both be considered in the development of health policies.
In conclusion, obesity altered aortic wall thickness in Wistar rats. However, the presence of periodontal disease did not affect aortic wall thickness under the conditions of the present study.