Effect of Mediterranean diet versus prudent diet combined with physical activity on OSAS: a randomised trial

RESULTS

40 patients were randomised to the PD group (n=20) or MD group (n=20); all of them successfully completed this small, underpowered study. No side-effects of either treatment were reported.

During the selection of the study population, 837 patients were excluded based on the abovementioned exclusion criteria (109 patients had ischaemic heart disease, 78 patients had diabetes mellitus, 126 patients had thyroid disorders, 21 patients suffered from malignancies, 28 had undergone upper airway surgery, three were alcoholics, 11 were under therapy with sleeping pills, 43 were receiving antidepressant medication, 203 had a BMI <30.0 kg·m⁻², 70 were <18 yrs of age and 145 were >65 yrs of age). Another 23 patients refused to participate in the intervention programme (fig. 1).

Table 1 shows the characteristics of the two groups at baseline. Despite the randomisation, BMI was higher in the PD group compared with the MD group (mean±sd 37.9±4.6 versus 35.3±3.6 kg·m⁻²; p=0.04). There were no significant differences between the two intervention groups in the other baseline characteristics (p>0.05). In general, the patients studied were middle aged (48.9±12.7 yrs); the majority were males (85.0%), with moderate-to-severe OSAS (AHI >15 events·h⁻¹ and ESS score >10) and BMI 36.6±3.7 kg·m⁻².

After 6 months, patients in the MD group showed a greater adherence to the MD pattern than those in the PD group (table 2). More specifically, the change in MedDietScore was 12.7±4.9 in the MD group and 0.95±4.5 in the PD group (p<0.001). Apart from MedDietScore, patients in the MD group also improved their level of physical activity (metabolic equivalent task (MET) min·week⁻¹) more than those in the PD group (p<0.05). There was also a statistically significant difference between the two study groups regarding the changes in several anthropometric indices. Patients in the MD group showed a greater decrease in WC (-8.7±3.6 cm), WC/height ratio (-0.04±0.02 cm·m⁻¹) and WC/hip ratio (-0.04±0.03 cm·cm⁻¹) than those in the PD group (-5.7±3.8 cm, -0.03±0.02 cm·m⁻¹ and -0.02±0.02 cm·cm⁻¹, respectively; p<0.05), while there was no difference between the two groups regarding the change in NC and NC/height ratio (p>0.05). Body fat also decreased more in the MD group than in the PD group (-4.3±2.5 versus -2.6±1.7%; p<0.05). At the end of the intervention, although patients in the MD group had reduced their weight and BMI more than those in the PD group (-8.9±3.9 versus -7.2±4.2 kg and -3.2±1.5 versus -2.5±1.4 kg·m⁻², respectively), these changes did not reach statistical significance (p>0.05). There were no significant differences in the changes in sleep parameters between the two groups (p>0.05), except the AHI during REM sleep. AHI/REM improved significantly more in participants in the MD group than in those in the PD group. Specifically, AHI/REM decreased by 18.4±17.6 in the MD group and by 2.6±23.7 in the PD group (p<0.05). The observed difference in AHI/REM between the two groups was independent of the baseline value, as the statistical difference persisted after adjustment for the baseline level of AHI/REM abnormality (p=0.02). The change in AHI during REM sleep from the beginning until the end of treatment for each patient separately is shown in figure 2. AHI/REM reduction was fairly and negatively correlated with increased exercise scores and positively with decreased waist diameter between time-points (r= -0.503, p=0.001 and r=0.488, p=0.002, respectively). We also controlled the time spent in the supine position during REM sleep between baseline and 6-month PSGs and there was no statistical difference in the PD group (baseline: 5±9.1 min; 6 months: 13±17.1 min; p=0.09) and in the MD group (baseline: 5.5±12.6; 6 months: 7.3±8.7; p=0.6).

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Figure 2–

Individual values of apnoea–hypopnoea index (AHI) during rapid eye movement (REM) sleep before (closed circles) and after (open circles) 6 months in the prudent diet (PD) versus the Mediterranean diet (MD) group. Squares and solid lines represent mean values. ^#: p=0.6; ^¶: p=0.002.

DISCUSSION

This study investigated the effect of the MD, compared with that of a PD, on obese OSAS patients treated with CPAP while receiving counselling to increase their physical activity. Weight loss trials including both diet and exercise in their programme have the potential to deliver significant health benefits in terms of treating OSAS in the majority of patients with mild [12] and mild-to-moderate [13] OSAS. According to the findings of this study, the MD diet combined with physical activity for a 6-month period of time did not lead to a greater improvement in overall OSAS severity than the PD diet, despite better exercise programme compliance. Participants in the MD group demonstrated a greater decrease in WC, WC/height ratio and WC/hip ratio than the PD group. This means that individuals succeeded in decreasing their abdominal fat. It has been reported that abdominal fat, BMI and NC are significant clinical predictors of OSAS [26, 27]. NC has been suggested to be more predictive of OSAS than general obesity and the lack of impact on overall OSAS severity could be related to lack of significant difference in the change in NC [28]. The only sleep parameter with a remarkable reduction was AHI/REM in patients in the MD arm compared with those following a PD. The finding of AHI/REM was not a primary end-point and further studies are needed in order to clarify this point. This was independent of the baseline value of AHI/REM. This is an interesting finding, since REM sleep abnormalities are associated with decreased upper airway muscle activation [29, 30], impaired genioglossus reflex responsiveness to negative pressure [31] and reduced chemosensitivity [32]. All these factors are related to the severity of the syndrome [33]. Recent reports have also related an increased AHI/REM with the risk of developing significant systemic consequences. Mahmood et al. [34] recently reported that an increased prevalence of diabetes type II was related to this specific phenotype of OSAS. However, its clinical significance remains unclear, although compared with non-REM sleep, during REM sleep, there is an increase in the duration of apnoea episodes, which perhaps cause more severe desaturation events [35]. There is no evidence from previous weight loss trials using conventional diet programmes to support this finding. This significant difference in the change in AHI/REM between the treatment groups could be related to the notable difference in the change in relevant body circumference indices. It is possible that the MD, along with increased physical activity, could promote changes of relevant anthropometric determinants, such as waist size, and, finally, lead to a better outcome. However, more studies dealing with this specific research question are needed to clarify this point. It has been suggested that abdominal fat is a risk factor for OSAS in obese patients [36]. It is related to a reduction in pharyngeal lumen size due to fatty tissue within the airway or in its lateral walls, and a decrease in upper airway muscle protective force due to fatty deposits in the muscle. It has also been reported that abdominal fat is associated with reduced upper airway size secondary to the mass effect of the large abdomen on the chest wall and tracheal traction [37]. Moreover, an association between increased BMI and the development of hypoventilation is well recognised, as abdominal fat accumulation is known to impair diaphragmatic excursion and rib cage expansion [38]. Since the diaphragm is the main inspiratory muscle during REM sleep [39], abdominal obesity may mechanically affect the expansion of the diaphragm, probably by encroaching into the chest by the chest wall or diaphragm, or by impeding the descent of the diaphragm during forced inspiration [40]. While obesity alone does not account for the development of hypoventilation, it is possible that by decreasing abdominal fat, breathing would be improved during REM sleep. Therefore, it is likely that the patients in the MD group reduced AHI/REM more than those in the PD group because of the greater reduction in abdominal fat, via an improvement in the mechanical load associated with OSAS [41]. The greater decrease in body fat in the MD group, as estimated by the four-skinfold method, could also be considered to strengthen our results, since body fat measured in this way has been considered a significant predictor for OSAS [42]. The difference between the two treatment groups in the changes in the above anthropometric indices and in body fat could be attributed to the greater adherence to the prescribed diet and level of physical activity in the patients in the MD group. It has been shown that exercise training alone is not an adequate intervention strategy for most individuals with OSAS but may serve well as an adjunct treatment strategy in the conservative management of OSAS. The results could be attributed to the combination of greater adherence to the hypocaloric diet and exercise in the MD group. Additionally, several reports have shown that abdominal obesity is substantially reduced when combining the above lifestyle modifications [43–45].

Potential mechanisms linking MD adherence to better compliance with a weight loss dietary programme compared to the PD used in this study may include its lower energy density [46] and its relatively low glycaemic load [47]. These beneficial factors, along with its higher fibre [46] and water [48] content, lead to increased satiation and lower calorie intakes. Moreover, the MD is highly palatable, which can increase both tolerance and compliance among individuals following it [49].

Regarding physical activity, there was a higher adoption of counselling by patients in the MD group. This observation was independent of factors such as age (older age), sex (female sex), educational level (low educational level) [50] and smoking [51], which could interfere with the participants’ ability to become physically active. These factors did not differ between the two groups at baseline. Recently, it was suggested that an increment in physical activity in conjunction with a healthy diet would lead to optimum weight loss [52]. However, in the present study, no difference in weight loss was observed between the two groups.

A strength of the present study was that participants in both groups were 100% compliant with CPAP and, therefore, the differences in weight loss and dietary adherence between the groups could not be attributed to CPAP. As the patients knew that their compliance was being evaluated and represented one of the end-points of the study, this may have significantly increased their motivation. Moreover, the physician responsible for the patients encouraged and reminded them during the study of the health risks cause by not using CPAP. However, a limitation of the study was the small size of the sample studied. This could be attributed to the characteristics of the population, the rigorous exclusion criteria and the lack of willingness of 23 patients to participate. The duration of the study was also relatively short, given that it has been shown that weight regain is common after weight loss [53], and weight loss programmes should last ≥1 yr. However, it has been proposed that the MD pattern can protect against weight gain [54]. All these limitations could adversely affect the external validity of our study and the results should be viewed with great caution. Moreover, the clinical application of our data may be valid only for patients with similar characteristics to those in the population studied.

In conclusion, this randomised weight loss trial showed that the MD combined with physical activity for 6 months was effective in reducing AHI/REM without any statistically significant effect on other sleep parameters, compared with a PD, in obese adults with moderate-to-severe OSAS. However, in view of the beneficial role of the MD and physical activity, further studies with more patients and potentially longer intervention periods will be needed in order to clarify the role of MD in the therapeutic plan of these patients and to address the potential mechanisms.