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. 2018 Feb 20;18:271. doi: 10.1186/s12889-018-5172-8

Obesity and risk of respiratory tract infections: results of an infection-diary based cohort study

Livia Maccioni 1,#, Susanne Weber 2,#, Magdeldin Elgizouli 1, Anne-Sophie Stoehlker 1,2, Ilona Geist 1, Hans-Hartmut Peter 1, Werner Vach 2, Alexandra Nieters 1,
PMCID: PMC5819164  PMID: 29458350

Abstract

Background

Respiratory tract infections (RTIs) are a major morbidity factor contributing largely to health care costs and individual quality of life. The aim of the study was to test whether obesity (BMI ≥ 30 kg/m2) is one of the risk factors underlying frequent RTIs in the German adult population.

Methods

We recruited 1455 individuals between 18 to 70 years from a cross-sectional survey on airway infections in Germany and invited them to self-report in diaries incident RTIs experienced during three consecutive winter/spring seasons. RTIs reported in these 18 months and summary measures adding-up individual RTIs were the outcomes of interest.

Results

Compared to individuals with normal weight, obese individuals reported a consistently higher frequency of upper and lower RTIs and predominantly fell in the upper 10% group of a diary sumscore adding-up 10 different RTI symptoms over time. Obesity was associated both with lower RTIs (adjustedOR = 2.02, 95%CI = 1.36–3.00) and upper RTIs (adjustedOR = 1.55, 95%CI = 1.22–1.96). Adjusting for demographic and lifestyle variables did only marginally affect ORs. Stratified analyses suggested a stronger association for women and effect modifications by sports activity and dietary habits.

Conclusions

We confirm the association of obesity with infection burden and present evidence for putative interaction with sports activity and dietary patterns.

Electronic supplementary material

The online version of this article (10.1186/s12889-018-5172-8) contains supplementary material, which is available to authorized users.

Keywords: Obesity, Adult respiratory tract infections, Diary, Effect modification, Life style factors

Background

Frequent and severe respiratory tract infections (RTIs) constitute an important morbidity factor in our society and a considerable cost burden in terms of medical treatment and time of work-loss [1, 2]. RTIs are divided into upper RTIs (URTIs) including common cold, pharyngitis, otitis, sinusitis, laryngotracheitis, epiglottitis and lower RTIs (LRTIs) including bronchitis, pneumonia and bronchiolitis [3]. Individual exposure to infectious agents and host factors such as smoking [4, 5] and vitamin D status [6, 7] are believed to contribute to observed differences in RTI risk. In addition, the role of overweight (body mass index (BMI) = 25.0–29.9 kg/m2) and in particular obesity (BMI ≥ 30 kg/m2) in predisposition to RTIs is increasingly discussed [813]. This growing interest is driven by the rising number of overweight and obese individuals worldwide [14] and the emerging knowledge of notable immunological imbalances in association with obesity [15]. Most of the studies targeting adults explored the association of obesity with specific RTIs and their outcomes. Thus, obesity was associated with non-allergic rhinitis [8] and influenza like-illness [9]. Moreover, two population-based studies which investigated the role of obesity as risk factor for community acquired pneumonia (CAP) in the general population resulted in controversial findings [10, 11]. Two recent Danish population-based studies reported an excess of a large spectrum of RTIs including pneumonia among obese people [12, 13]. The overall aim of our study targeting the adult population in South Baden, Germany, is to identify risk factors for the susceptibility to RTIs. Here we present data on the role of obesity as contributing factor to a high RTI burden in the German society and explore effect modification by gender, sports activity and nutritional patterns.

Methods

Study population

Study participants (n = 1455) were recruited from the airway infection susceptibility (AWIS) cross sectional study querying RTI burden in an adult population in South-Baden, Germany [16]. The study protocol was approved by community officials and the Ethics Committee of the University of Freiburg (Ref. No. 258/11_120365). Based on the RTI history-score individuals of putative low, medium and high risk of future RTIs were invited to the actual sub-cohort. The RTI history score is summarizing information on the frequency and severity of RTIs and antibiotics use over the past two years, self-assessed RTI susceptibility, and occurrence of selected severe infections [16]. Study participants were requested to fill-in an additional questionnaire (baseline questionnaire) on lifestyle factors and co-morbidities and to complete monthly diaries registering the monthly occurrence and the duration (< 2 weeks, > 2 weeks) of RTIs, namely sinusitis, rhinitis, otitis media, pharyngitis/laryngitis, tonsillitis, influenza-like illness, bronchitis, pneumonia, pleurisy and other acute RTIs, from the beginning of November to the end of April of three seasons: 2012/13, 2013/14 and 2014/15. Furthermore, the intake of antibiotics, doctor visits, hospitalisation for RTIs and the impact of RTI symptoms on their daily activities were queried. Further recruitment details into the AWIS study and the present sub-cohort are presented under Additional files 1 and 2. Informed consent was obtained from all individual participants included in the study.

Outcome measures

In order to describe the association between obesity and RTIs, different outcome indicators were considered: outcomes at the level of each month [“any RTI”, “any URTI” (sinusitis, rhinitis, otitis media, pharyngitis/laryngitis and tonsillitis), “any LRTI” (bronchitis, pneumonia and pleurisy), “≥3 RTIs”, “any long lasting infection” (> 2 weeks)]; at the level of each winter season (“≥4 months with infections”, “≥3 long lasting infections”); and at the individual level (i.e. are defined once per individual and covering the overall study period). The ten specific RTI symptom categories were considered with the binary symptom indicators “infection reported” or “no infection reported” for each month. When counting the episodes for the outcome indicator “≥3 long lasting infections”, different infection symptoms were counted as separate episodes, even if they overlapped in time. However, within one symptom category at least one month without this specific infection was required to call it a new episode. We also calculated a monthly diary RTI score, averaging the ten RTI symptom categories with the coding “0” for “no infection reported”, “1” for “reported infection with duration < 2 weeks”, and “2” for “reported infection present with duration >2 weeks”. Missing values for individual infection items were treated as zero. If an individual RTI symptom was reported, but information on duration was missing, it was counted as “reported infection with duration < 2 weeks”. If all items were missing, no diary score was computed. The diary RTI score at the monthly level was expanded to a score at the seasonal level by averaging over the six months (November–April) of each season, and to an overall score at the individual level by averaging over all available months. The respective upper 10% of these diary scores within each month, season and overall served as additional outcome indicators.

Further variables considered in the study were age, gender, self-reported weight and height for BMI calculation (BMI was categorized as < 30 (non-obese), 25 ≤ BMI < 30 (overweight) and ≥30 (obese)), educational level, contact with children, comorbidities, removed immunological organs, smoking status, sports activity and dietary intake patterns. Details on these variables are described in the Additional file 1 and supplementary information on dietary intake patterns is presented in Additional file 3.

Statistical analysis

Statistical analysis was performed using Stata (version 14 STATSCorp, USA). Descriptive statistics: Monthly prevalences of individual RTI symptoms were computed by taking the average over all subjects available at each month and then averaging over all 18 months covered. Prevalences at the seasonal level were computed accordingly averaging over all three seasons covered. The corresponding confidence intervals (CIs) and p-values are based on a generalised linear model with identity link and binomial type variance together with robust variance estimates. The frequency of long lasting infections among all months with infections was analysed accordingly. However, due to the limited number of cases for tonsillitis and otitis media we determined the monthly frequency of long-lasting infections by pooling the data over all seasons and for pneumonia by pooling all indicated months.

Odds ratios (ORs) for outcome variables and adjustments

At the monthly level ORs were computed using a logistic regression model with a random intercept applied to the individual data for each month taking the 18 months as a categorical covariate into account in addition to the obesity status indicator. Due to its small prevalence, pleurisy was not considered as single outcome in these analyses. Outcomes at the seasonal level were analysed accordingly with the individual data for each winter season and taking into account the three seasons as a categorical covariate. Outcomes at the individual level were analysed using a logistic regression model. Results are ORs and 95% CIs. Adjusted ORs are based on including age groups and education as simultaneous categorical covariates. Furthermore, in order to study the stability of the obesity-RTI association with respect to potential confounders, ORs were adjusted by respective variables. Subjects with incomplete covariate data were excluded from multivariate analyses.

Subgroup analysis

Effect modification by a binary variable was assessed by fitting an overall model with the corresponding interactions parametrized so that we could directly read off the two subgroup-specific ORs. Effect modification by sports activity and nutrition patterns was explored among those representing the lower and upper third of respective scores.

Results

Characteristics of the study population

The study population comprised 1455 individuals (931 female and 524 male) with a median age of 51.08 years. Based on BMI calculated from self-reported weight and height, 2.1% of the population was underweight (BMI < 18.5 kg/m2), 54% had a normal weight (18.5 kg/m2 ≤ BMI < 25 kg/m2), 31.1% was overweight, and 12.8% was considered obese (Table 1). In women, the distribution was 2.8%, 60.21%, 25.0%, and 12.1% and in men 0.76%, 43.1%, 41.8%, and 14.3%, respectively. The study participants were mainly of medium and high educational level, non- or ex-smokers, moderately affected by selected co-morbidities and they reported rather infrequent contact to small children. Further information on the study population and completed diaries is reported in Table 1 and Additional file 4.

Table 1.

Characteristics of the study population

All (N = 1455): Male (N = 524): Female (N = 931):
Variable Category Absolute number Relative frequency (%) Absolute number Relative frequency (%) Absolute number Relative frequency (%) P-valued (gender)
BMI < 18.5 30 2.1 4 0.76 26 2.8 < 0.001
18.5–25 786 54.0 226 43.1 560 60.1
25–30 452 31.1 219 41.8 233 25.0
30–35 135 9.3 58 11.1 77 8.3
35–40 34 2.3 9 1.7 25 2.7
≥40 18 1.2 8 1.5 10 1.1
missing 0 0 0
Age (years) < 30 140 9.6 24 4.6 116 12.5 < 0.001
30–40 170 11.7 39 7.4 131 14.1
40–50 367 25.2 110 21.0 257 27.6
50–60 403 27.7 162 30.9 241 25.9
≥60 375 25.8 189 36.1 186 20.0
Educational level none 4 0.28 1 0.19 3 0.32 < 0.001
Hauptschulea 287 19.8 141 27.0 146 15.8
Realschule/Mittlere Reifeb 470 32.4 122 23.3 348 37.5
Abiturc 261 18.0 66 12.6 195 21.0
university degree 428 29.5 193 36.9 235 25.4
missing 5 1 4
Smoking status never 789 54.3 248 47.4 541 58.1 < 0.001
former smoker 461 10.0 190 39.0 271 9.1
current smoker 204 31.7 85 36.3 119 29.1
missing 1 1 0
Contact with children never 162 11.2 73 14.0 89 9.6 < 0.001
rarely 574 39.5 236 45.1 338 36.4
weekly 292 20.1 90 17.2 202 21.7
daily 424 29.2 124 23.7 300 32.3
missing 3 1 2
Co-morbidities:
 COPD/Lung emphysema yes 35 2.4 23 4.4 12 1.3 < 0.001
missing 10 3 7
 Asthma yes 89 6.2 32 6.1 57 6.2 1.000
missing 14 3 11
 Renal disease yes 16 1.1 9 1.7 7 0.76 0.116
missing 13 3 10
 Blood disease yes 21 1.5 7 1.4 14 1.5 1.000
missing 13 6 7
 Liver disease yes 55 3.8 27 5.2 28 3.0 0.046
missing 13 2 11
 Rheumatoid disease yes 52 3.6 14 2.7 38 4.1 0.187
missing 14 6 8
 Chronic intestinal disease yes 45 3.1 19 3.6 26 2.8 0.431
missing 11 3 8
 Diabetes mellitus yes 46 3.2 23 4.4 23 2.5 0.060
missing 13 4 9
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aSecondary general school, represents 9 years of school education; bIntermediate secondary school, represents 10 years of school education;cGeneral Higher Education Entrance Qualification, represents 12–13 years of school education; d the p-value for the gender difference is based on the Fisher’s exact test for comorbidities and on chi2 otherwise

Reported RTIs over 18 months covering three winter seasons

Missing rates of single items in the returned diaries were limited and ranged from 1.2% for rhinitis and pharyngitis/laryngitis to 2.6% for other acute respiratory infections. Study participants reported most frequently rhinitis (26.6%), followed by influenza-like illness (11.4%) and pharyngitis/laryngitis (10.5%), whereas pleurisy (0.10%) was rarely experienced. Any URTI (31.5%) was more frequent than any LRTI (7.9%). Apart from the LRTIs bronchitis, pneumonia and pleurisy, which more men than women reported, all other RTIs were more prevalent among women (Table 2). Seasonal patterns of reported infections show a February peak for two of the three assessed infection seasons (2012/13 and 2014/15, see Additional file 5). Respiratory infections with a high fraction of long duration were almost exclusively LRTIs, namely pneumonia (59%), followed by bronchitis (48.2%). Men were overrepresented among those with long-lasting RTIs (Table 2).

Table 2.

a) Prevalence of respiratory tract infections (RTIs) outcomes and b) frequency of long lasting RTIs

a)
All (N = 1455): Male (N = 524): Female (N = 931):
Outcome indicators Prevalence (%) 95% CI Prevalence (%) 95% CI Prevalence (%) 95% CI P-valuea (gender)
Monthly level:
 AnyRTI 36.3 (34.9;37.7) 35.1 (32.7;37.5) 37.0 (35.2;38.7) 0.223
 AnyURTI 31.5 (30.2;32.9) 29.9 (27.6;32.1) 32.4 (30.7;34.1) 0.077
 AnyLRTI 7.9 (7.1; 8.8) 9.0 (7.3;10.6) 7.4 (6.4; 8.3) 0.097
 Sinusitis 7.0 (6.2; 7.8) 5.3 (4.1; 6.5) 7.9 (6.9; 8.9) < 0.001
 Rhinitis 26.6 (25.4;27.9) 25.8 (23.7;27.9) 27.0 (25.4;28.6) 0.368
 Otitis media 0.94 (0.67; 1.21) 0.87 (0.49; 1.24) 0.98 (0.61; 1.35) 0.674
 Pharyngitis/Laryngitis 10.5 (9.6;11.3) 9.7 (8.2;11.2) 10.9 (9.8;11.9) 0.218
 Tonsillitis 1.9 (1.6; 2.3) 1.4 (0.8; 2.0) 2.2 (1.8; 2.7) 0.040
 Influenza-like illness 11.4 (10.6;12.1) 11.3 (10.1;12.6) 11.4 (10.4;12.4) 0.942
 Bronchitis 7.8 (7.0; 8.7) 8.9 (7.2;10.5) 7.3 (6.3; 8.2) 0.102
 Pneumonia 0.21 (0.11; 0.30) 0.26 (0.07; 0.45) 0.17 (0.08; 0.27) 0.433
 Pleurisy 0.10 (0.03; 0.17) 0.17 (0.00; 0.34) 0.06 (0.01; 0.11) 0.220
 Other acute resp. Infections 2.4 (2.0; 2.8) 1.9 (1.1; 2.7) 2.6 (2.1; 3.1) 0.137
  ≥ 3 RTIs 8.6 (7.8; 9.4) 8.1 (6.8; 9.4) 8.9 (7.9; 9.8) 0.362
 Long RTIs 13.0 (11.9;14.0) 12.7 (10.8;14.6) 13.1 (11.8;14.4) 0.737
 Upper 10% in diary score 10.0 (9.1;10.9) 10.0 (8.4;11.6) 10.0 (8.9;11.1) 0.992
Seasonal level:
  ≥ 4 months RTIs 19.3 (17.6;21.0) 18.6 (15.9;21.4) 19.6 (17.5;21.8) 0.566
  ≥ 3 long RTIs 9.2 (8.1;10.4) 9.9 (7.8;11.9) 8.9 (7.4;10.3) 0.445
 Upper 10% in diary score 10.2 (8.9;11.5) 10.7 (8.3;13.1) 9.9 (8.3;11.5) 0.602
Individual-level:
 Upper 10% in diary score 10.0 (8.4;11.5) 9.9 (7.4;12.5) 10.0 (8.1;11.9) 0.968
b)
All (N = 1455): Male (N = 524): Female (N = 931):
Frequencyb (%) 95% CI Frequencyb (%) 95% CI Frequencyb (%) 95% CI P-valuea (gender)
Outcome indicators
 Any long RTI 35.5 (33.4;37.6) 36.2 (32.4;39.9) 35.2 (32.7;37.7) 0.674
 Sinusitis 41.1 (36.7;45.5) 45.0 (35.4;54.6) 39.6 (34.8;44.5) 0.326
 Rhinitis 26.2 (24.0;28.4) 27.4 (23.4;31.4) 25.5 (22.9;28.1) 0.435
 Otitis media 32.6 (22.7;42.6) 36.7 (18.1;55.4) 31.1 (19.1;43.0) 0.616
 Pharyngitis/Laryngitis 27.8 (24.6;30.9) 32.6 (26.7;38.6) 25.5 (22.0;29.1) 0.043
 Tonsillitis 16.7 (11.7;21.8) 23.7 (12.3;35.2) 14.4 (8.9;20.0) 0.153
 Influenza-like illness 26.0 (23.1;28.8) 28.8 (23.8;33.7) 24.5 (21.1;28.0) 0.175
 Bronchitis 48.2 (44.5;51.9) 48.3 (41.7;54.9) 48.1 (44.0;52.2) 0.965
 Pneumonia 59.0 (42.0;75.9) 66.7 (44.4;88.9) 52.4 (29.4;75.4) 0.382
 Other acute resp. infections 46.5 (39.7;53.3) 55.8 (42.5;69.0) 42.9 (35.5;50.4) 0.097
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athe p-value for the gender difference is based on the Fisher’s exact test for comorbidities and on chi2 otherwise

bfor all months in which a respective infection was reported

Association between obesity and reported RTIs

Compared to normal weight individuals, overweight and obese people consistently had a higher prevalence (Table 3) for the single RTIs, URTIs, LRTIs, as well as the other outcome parameters we looked at with other acute infections and pneumonia as the exceptions. For pneumonia, only obese subjects had a higher prevalence. The overweight group was typically falling in between the groups with normal weight and obesity (Table 3). The strongest association was seen for pneumonia and bronchitis, and accordingly, any LRTI was more strongly associated with obesity than any URTI. Long-lasting RTIs, frequent RTIs and high diary scores were also more strongly associated with obesity than the individual symptoms. Adjustments by age and education did only marginally change these estimates. Among subjects with an infection, long lasting infections were again associated with obesity, reaching significance for any RTI, rhinitis, pharyngitis/laryngitis, influenza-like illness, and bronchitis (Table 3).

Table 3.

a) Associations of obesity with RTIs and b) with long lasting RTIs

a)
Prevalence (%) (Obese vs non-obese) (Obese vs non-obese)
Outcome indicators BMI < 25 (N = 816) Overweight (N = 452) Obese (N = 187) Crude OR 95% CI Adjusteda OR 95% CI
Monthly level:
 Any RTI 33.2 39.0 43.5 1.48 (1.18; 1.85) 1.49 (1.18; 1.87)
 Any URTI 28.9 33.6 38.4 1.48 (1.17; 1.87) 1.55 (1.22; 1.96)
 Any LRTI 6.0 9.8 12.1 2.54 (1.69; 3.80) 2.02 (1.36; 3.00)
 Sinusitis 5.7 7.9 10.6 1.99 (1.29; 3.08) 2.12 (1.36; 3.31)
 Rhinitis 24.2 28.4 32.8 1.43 (1.13; 1.80) 1.53 (1.21; 1.94)
 Otitis media 0.68 1.18 1.49 2.22 (0.90; 5.47) 2.31 (0.95; 5.63)
 Pharyngitis/Laryngitis 9.3 11.3 13.5 1.69 (1.23; 2.33) 1.70 (1.23; 2.36)
 Tonsillitis 1.7 2.3 2.1 1.36 (0.67; 2.79) 1.56 (0.77; 3.16)
 Influenza-like illness 9.8 12.7 15.2 1.58 (1.23; 2.03) 1.58 (1.23; 2.03)
 Bronchitis 5.9 9.8 11.7 2.38 (1.58; 3.59) 1.89 (1.26; 2.83)
 Pneumonia 0.19 0.13 0.45 6.06 (1.35;27.21) 6.01 (1.30;27.90)
 Other acute resp. infections 2.1 2.9 2.0 0.80 (0.41; 1.57) 0.73 (0.37; 1.43)
  ≥ 3 RTIs 6.8 10.2 12.8 2.15 (1.52; 3.03) 2.12 (1.50; 3.00)
 Long RTIs 9.9 15.4 20.4 2.41 (1.72; 3.39) 2.14 (1.52; 3.02)
 Upper 10% in diaryscore 7.5 12.2 15.7 2.21 (1.57; 3.12) 2.09 (1.48; 2.96)
Seasonal level:
  ≥ 4 months RTIs 15.5 22.4 28.4 2.69 (1.62; 4.45) 2.54 (1.53; 4.21)
  ≥ 3 long RTIs 6.7 11.0 17.4 3.13 (2.01; 4.88) 2.81 (1.79; 4.40)
 Upper 10% in diary score 6.3 13.4 19.2 4.85 (2.53; 9.32) 3.95 (2.08; 7.51)
Individual level:
 Upper 10% in diary score 6.0 13.7 18.2 2.32 (1.52; 3.52) 1.97 (1.28; 3.04)
b)
Frequencyb (%) (Obese vs non-obese) (Obese vs non-obese)
Outcome indicators BMI < 25 (N = 816) Overweight (N = 452) Obese (N = 187) Crude OR 95% CI Adjusteda OR 95% CI
Any long RTIs 29.9 39.1 46.6 2.24 (1.64; 3.05) 1.93 (1.42; 2.63)
Sinusitis 35.9 44.3 41.8 1.77 (0.94; 3.31) 1.51 (0.80; 2.86)
Rhinitis 22.1 28.1 35.6 1.84 (1.29; 2.62) 1.71 (1.20; 2.44)
Otitis media 31.1 34.1 36.9 4.12 (0.38;45.18) 2.87 (0.26;31.54)
Pharyngitis/Laryngitis 21.9 31.8 37.4 2.42 (1.48; 3.97) 2.15 (1.32; 3.51)
Tonsillitis 16.2 14.7 22.5 3.21 (0.64;16.15) 2.98 (0.59;15.05)
Influenza-like illness 21.6 28.2 34.4 2.13 (1.34; 3.38) 1.86 (1.18; 2.94)
Bronchitis 44.0 47.5 59.8 2.08 (1.33; 3.24) 2.06 (1.32; 3.23)
Pneumonia 52.4 57.1 72.7 4.18 (0.25;81.73) 3.40 (0.17;68.52)
Other acute resp. infections 44.6 47.6 53.3 2.42 (0.58;10.14) 2.09 (0.51; 8.56)
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aadjusted by age (continuous) and educational status (three categories)

bfor all months in which a respective infection was reported

Robustness of associations to confounding

For a better understanding of the robustness of the relationship between RTI burden and obesity, the effect of adjusting for putative confounders was explored (Additional file 6). The studied demographic and lifestyle variables (age, gender, education level, smoking status, contact to children, asthma, sports activity, dietary patterns and previous removal of immune organs) did only marginally affect ORs. However, adjustment for asthma, chronic obstructive pulmonary disease (COPD) or a summary score covering all queried co-morbidities weakened the relationship between obesity and all outcomes considerably. Adjustment for vitamin D levels among those for which serum was available (n = 508), had only a slight effect on the magnitude of the association between obesity and RTI outcomes.

Effect modification by gender, sports activity and nutritional pattern

The association between obesity and RTI outcomes was more prominent for women than for men and reached statistical significance only for the former (Table 4). For most outcomes this interaction was not significant, with the individual level diary score as an exception. When looking at sports activity, for most outcomes the association with obesity was confined to those physically more active and not seen for those reporting little sports activity (Table 5). For all outcomes the association was less pronounced in the latter group (compare the ratios of ORs in Table 5), a difference that reached significance for all outcomes except those with low prevalence. Typically the prevalence of an outcome was only increased in the small group of people with obesity and higher sports activity whereas all other groups presented rather similar patterns. Similarly, the prevalence of outcomes was increased among people with obesity and a more favourable nutritional pattern, but comparable among the other groups (Table 6). The interaction reaches significance for the majority of outcomes.

Table 4.

Association of obesity with RTIs in females and males

Male (N = 524) Female (N = 931)
Prevalence (%) Prevalence (%)
Outcome indicators Approach Non-obese (N = 449) Obese (N = 75) OR 95% CI Non-obese (N = 819) Obese (N = 112) OR 95% CI OR male/OR female P-value
Monthly level:
 Any RTI crude 34.4 39.3 1.24 (0.86; 1.79) 35.7 45.9 1.66 (1.24; 2.22) 0.75 0.221
adjusteda 1.23 (0.86; 1.78) 1.67 (1.25; 2.23) 0.74 0.196
 Any URTI crude 29.2 33.9 1.18 (0.80; 1.73) 31.2 41.1 1.72 (1.27; 2.31) 0.69 0.129
adjusteda 1.22 (0.84; 1.79) 1.79 (1.33; 2.41) 0.68 0.121
 Any LRTI crude 8.5 11.7 1.97 (1.02; 3.78) 6.7 12.1 2.92 (1.75; 4.87) 0.67 0.351
adjusteda 1.47 (0.78; 2.80) 2.43 (1.47; 4.03) 0.60 0.225
 Sinusitis crude 4.8 8.1 1.51 (0.69; 3.29) 7.3 12.1 2.36 (1.38; 4.01) 0.64 0.353
adjusteda 1.55 (0.71; 3.40) 2.48 (1.45; 4.25) 0.63 0.331
 Rhinitis crude 25.3 29.3 1.10 (0.76; 1.61) 25.9 35.0 1.68 (1.25; 2.26) 0.66 0.089
adjusteda 1.19 (0.82; 1.73) 1.79 (1.33; 2.40) 0.66 0.091
 Otitis media crude 0.85 0.92 0.60 (0.11; 3.19) 0.86 1.81 3.89 (1.34;11.24) 0.15 0.066
adjusteda 0.62 (0.12; 3.20) 4.20 (1.47;12.02) 0.15 0.054
 Pharyngitis/Laryngitis crude 9.4 11.4 1.54 (0.91; 2.61) 10.3 14.8 1.82 (1.22; 2.73) 0.84 0.616
adjusteda 1.50 (0.88; 2.55) 1.84 (1.22; 2.77) 0.81 0.542
 Tonsillitis crude 1.49 0.79 0.56 (0.12; 2.55) 2.11 2.93 1.82 (0.83; 4.00) 0.31 0.177
adjusteda 0.66 (0.15; 2.98) 1.99 (0.90; 4.37) 0.33 0.205
 Influenza-like illness crude 10.8 14.6 1.35 (0.90; 2.03) 10.8 15.4 1.73 (1.26; 2.38) 0.78 0.347
adjusteda 1.38 (0.92; 2.07) 1.72 (1.25; 2.36) 0.81 0.406
 Bronchitis crude 8.5 11.3 1.77 (0.91; 3.46) 6.6 11.9 2.83 (1.69; 4.76) 0.63 0.277
adjusteda 1.32 (0.68; 2.55) 2.35 (1.41; 3.92) 0.56 0.172
 Pneumonia crude 0.24 0.40 2.30 (0.22;23.53) 0.13 0.46 10.94 (1.47;81.47) 0.21 0.316
adjusteda 2.62 (0.24;28.13) 9.92 (1.34;73.33) 0.26 0.391
 Other acute resp. infections crude 2.12 0.59 0.15 (0.03; 0.76) 2.55 2.90 1.29 (0.62; 2.72) 0.11 0.018
adjusteda 0.13 (0.03; 0.68) 1.18 (0.56; 2.50) 0.11 0.017
  ≥ 3 RTIs crude 7.6 10.7 1.44 (0.81; 2.58) 8.2 13.9 2.68 (1.74; 4.13) 0.54 0.093
adjusteda 1.37 (0.77; 2.45) 2.70 (1.75; 4.15) 0.51 0.066
 Long RTIs crude 11.9 18.0 2.05 (1.18; 3.59) 11.9 21.8 2.69 (1.74; 4.15) 0.76 0.454
adjusteda 1.72 (0.98; 2.99) 2.47 (1.60; 3.81) 0.69 0.309
 Upper 10% in diary score crude 9.4 13.9 1.49 (0.84; 2.65) 9.1 16.7 2.78 (1.81; 4.27) 0.54 0.089
adjusteda 1.35 (0.76; 2.39) 2.69 (1.75; 4.14) 0.50 0.057
Seasonal level:
  ≥ 4 months RTIs crude 17.6 25.0 2.26 (1.00; 5.09) 18.1 30.3 2.99 (1.58; 5.66) 0.76 0.592
adjusteda 1.99 (0.88; 4.46) 2.94 (1.56; 5.56) 0.68 0.450
  ≥ 3 long RTIs crude 8.2 15.8 2.57 (1.24; 5.34) 8.3 18.3 3.51 (2.02; 6.09) 0.73 0.502
adjusteda 2.24 (1.07; 4.70) 3.20 (1.83; 5.60) 0.70 0.449
 Upper 10% in diary score crude 9.7 16.8 2.45 (0.82; 7.31) 8.4 20.6 7.13 (3.15;16.12) 0.34 0.124
adjusteda 1.89 (0.64; 5.57) 5.95 (2.67;13.26) 0.32 0.093
Individual level:
 Upper 10% in diary score crude 9.8 10.7 1.10 (0.50; 2.44) 8.2 23.2 3.39 (2.05; 5.62) 0.32 0.019
adjusteda 0.90 (0.40; 2.03) 2.95 (1.76; 4.95) 0.31 0.015
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aadjusted by age (continuous) and educational status (three categories)

Table 5.

Effect modification by sports activity

Less active (lower third, N = 485) High active (upper third, N = 488)
Prevalence (%) Prevalence (%)
Outcome indicators Approach Non-obese (N = 379) Obese (N = 106) OR 95% CI Non-obese (N = 454) Obese (N = 34) OR 95% CI OR less/OR more active P-value
Monthly level:
 Any RTI crude 37.9 38.8 0.98 (0.72; 1.35) 33.7 51.6 2.56 (1.54; 4.26) 0.38 0.002
adjusteda 1.00 (0.73; 1.37) 2.58 (1.56; 4.27) 0.39 0.002
 Any URTI crude 32.0 33.8 1.03 (0.75; 1.42) 29.2 46.7 2.63 (1.56; 4.43) 0.39 0.003
adjusteda 1.08 (0.78; 1.49) 2.70 (1.61; 4.52) 0.40 0.003
 Any LRTI crude 10.3 10.3 1.19 (0.67; 2.13) 6.1 14.6 5.17 (2.14;12.49) 0.23 0.006
 Sinusitis adjusteda 0.94 (0.53; 1.67) 4.31 (1.82;10.21) 0.22 0.004
crude 6.9 9.3 1.36 (0.72; 2.58) 6.1 15.1 4.35 (1.70;11.13) 0.31 0.045
adjusteda 1.42 (0.75; 2.70) 4.16 (1.62;10.69) 0.34 0.063
 Rhinitis crude 27.1 29.0 1.02 (0.74; 1.41) 24.2 39.3 2.46 (1.47; 4.09) 0.42 0.004
adjusteda 1.09 (0.79; 1.50) 2.52 (1.52; 4.16) 0.43 0.005
 Otitis media crude 0.84 0.71 1.03 (0.28; 3.75) 0.84 1.60 1.69 (0.28;10.22) 0.61 0.659
adjusteda 0.97 (0.27; 3.45) 1.80 (0.32;10.02) 0.54 0.570
 Pharyngitis/Laryngitis crude 10.1 10.4 1.15 (0.73; 1.81) 10.2 22.8 3.98 (2.03; 7.80) 0.29 0.003
adjusteda 1.14 (0.72; 1.80) 3.85 (1.96; 7.57) 0.30 0.003
 Tonsillitis crude 1.9 1.8 1.07 (0.37; 3.13) 2.1 3.9 4.25 (1.24;14.61) 0.25 0.098
adjusteda 1.28 (0.45; 3.60) 5.33 (1.56;18.15) 0.24 0.079
 Influenza-like illness crude 12.0 13.6 1.08 (0.77; 1.52) 10.4 22.6 3.45 (2.08; 5.75) 0.31 < 0.001
adjusteda 1.08 (0.77; 1.52) 3.46 (2.08; 5.75) 0.31 < 0.001
 Bronchitis crude 10.3 10.0 1.09 (0.60; 1.97) 6.0 14.2 4.78 (1.94;11.78) 0.23 0.007
adjusteda 0.86 (0.48; 1.54) 3.93 (1.62; 9.51) 0.22 0.005
 Pneumonia crude 0.18 0.43 5.07 (0.64;40.15) 0.18 0.95 27.64 (1.02;751.94) 0.18 0.372
adjusteda 5.02 (0.56;44.91) 19.80 (0.95;410.73) 0.25 0.449
 Other acute resp. infections crude 3.1 1.8 0.48 (0.18; 1.32) 1.9 2.2 1.53 (0.37; 6.41) 0.31 0.196
adjusteda 0.44 (0.16; 1.21) 1.33 (0.32; 5.46) 0.33 0.214
  ≥ 3 RTIs crude 9.0 10.6 1.26 (0.78; 2.05) 7.5 19.9 5.57 (2.73;11.34) 0.23 < 0.001
adjusteda 1.20 (0.74; 1.94) 5.07 (2.50;10.27) 0.24 < 0.001
 Long RTIs crude 14.9 16.5 1.19 (0.73; 1.93) 10.4 26.4 5.37 (2.53;11.40) 0.22 0.001
adjusteda 1.07 (0.66; 1.75) 4.91 (2.31;10.43) 0.22 < 0.001
 Upper 10% in diary score crude 11.1 13.3 1.21 (0.74; 1.96) 8.2 21.9 5.53 (2.65;11.52) 0.22 < 0.001
adjusteda 1.13 (0.70; 1.84) 5.10 (2.45;10.61) 0.22 < 0.001
Seasonal level:
  ≥ 4 months RTIs crude 21.1 24.3 1.32 (0.66; 2.64) 14.8 32.8 6.27 (2.07;18.95) 0.21 0.019
adjusteda 1.30 (0.65; 2.61) 5.86 (1.94;17.69) 0.22 0.023
  ≥ 3 long RTIs crude 10.2 13.2 1.59 (0.82; 3.12) 7.6 26.0 7.54 (2.88;19.69) 0.21 0.009
adjusteda 1.35 (0.69; 2.65) 6.59 (2.53;17.16) 0.20 0.007
 Upper 10% in diary score crude 10.9 14.5 1.63 (0.64; 4.16) 7.1 33.7 39.36 (8.94;173.29) 0.04 < 0.001
adjusteda 1.27 (0.50; 3.23) 31.05 (7.52;128.22) 0.04 < 0.001
Individual level:
 Upper 10% in diary score crude 12.1 13.2 1.10 (0.58; 2.09) 6.6 35.3 7.71 (3.48;17.07) 0.14 < 0.001
adjusteda 0.94 (0.49; 1.81) 7.00 (3.12;15.75) 0.13 < 0.001
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aadjusted by age (continuous) and educational status (three categories)

Table 6.

Effect modification by nutritional status

More unfavourable nutrition (lower third, N = 379) More favourable nutrition (upper third, N = 530)
Prevalence (%) Prevalence (%)
Outcome indicators Approach Non-obese (N = 325) Obese (N = 54) OR 95% CI Non-obese (N = 467) Obese (N = 63) OR 95% CI OR unfavourable/OR favourable nutrition P-value
Monthly level:
 Any RTI crude 34.8 37.4 1.10 (0.72; 1.68) 35.8 49.3 1.99 (1.34; 2.94) 0.55 0.045
adjusteda 1.13 (0.74; 1.74) 2.02 (1.36; 2.99) 0.56 0.049
 Any URTI crude 30.0 32.9 1.13 (0.73; 1.77) 31.0 43.8 2.01 (1.34; 3.01) 0.57 0.064
adjusteda 1.22 (0.78; 1.91) 2.10 (1.40; 3.14) 0.58 0.075
 Any LRTI crude 7.5 8.4 1.75 (0.79; 3.85) 8.0 14.5 3.13 (1.58; 6.19) 0.56 0.274
adjusteda 1.22 (0.56; 2.67) 2.43 (1.24; 4.74) 0.50 0.187
 Sinusitis crude 5.9 7.7 1.54 (0.64; 3.67) 7.2 14.2 2.40 (1.14; 5.04) 0.64 0.443
adjusteda 1.55 (0.64; 3.75) 2.33 (1.09; 4.94) 0.67 0.491
 Rhinitis crude 26.7 28.3 1.04 (0.67; 1.62) 25.5 37.5 1.99 (1.33; 2.97) 0.52 0.034
adjusteda 1.17 (0.75; 1.82) 2.14 (1.43; 3.19) 0.55 0.044
 Otitis media crude 1.35 0.60 0.46 (0.06; 3.43) 0.82 1.16 1.73 (0.36; 8.27) 0.27 0.312
adjusteda 0.61 (0.08; 4.63) 2.17 (0.48; 9.84) 0.28 0.320
 Pharyngitis/Laryngitis crude 8.6 8.5 1.10 (0.58; 2.09) 10.3 18.3 2.80 (1.65; 4.77) 0.39 0.028
adjusteda 1.08 (0.57; 2.06) 2.79 (1.63; 4.76) 0.39 0.025
 Tonsillitis crude 2.25 0.46 0.14 (0.02; 1.04) 1.72 2.09 1.63 (0.47; 5.66) 0.09 0.042
adjusteda 0.19 (0.03; 1.40) 1.99 (0.57; 6.95) 0.10 0.050
 Influenza-like illness crude 11.9 13.9 1.22 (0.77; 1.95) 10.4 20.3 2.43 (1.60; 3.70) 0.50 0.032
adjusteda 1.23 (0.77; 1.98) 2.42 (1.58; 3.71) 0.51 0.035
 Bronchitis crude 7.5 8.4 1.77 (0.80; 3.94) 7.9 13.8 2.71 (1.34; 5.45) 0.65 0.434
adjusteda 1.23 (0.55; 2.70) 2.09 (1.05; 4.17) 0.58 0.312
 Pneumonia crude 0.06 0.00 1.00 (.;.) 0.25 0.99 14.92 (1.10;202.01) 0.07 0.042
adjusteda 1.00 (.;.) 7.30 (0.89;59.69) 0.14 0.064
 Other acute resp. infections crude 2.5 1.4 0.73 (0.19; 2.75) 2.1 3.3 1.38 (0.46; 4.13) 0.53 0.464
adjusteda 0.64 (0.17; 2.43) 1.22 (0.41; 3.61) 0.52 0.456
  ≥ 3 RTIs crude 8.6 7.9 1.01 (0.51; 2.00) 8.0 17.3 3.72 (2.11; 6.55) 0.27 0.004
adjusteda 1.01 (0.51; 2.00) 3.53 (2.00; 6.25) 0.29 0.005
 Long RTIs crude 11.4 14.8 1.77 (0.89; 3.50) 12.0 26.4 3.87 (2.12; 7.05) 0.46 0.091
adjusteda 1.50 (0.76; 2.99) 3.31 (1.81; 6.05) 0.46 0.088
 Upper 10% in diary score crude 9.6 9.9 1.26 (0.64; 2.47) 9.3 21.3 3.58 (2.01; 6.36) 0.35 0.021
adjusteda 1.14 (0.58; 2.24) 3.24 (1.82; 5.78) 0.35 0.020
Seasonal level:
  ≥ 4 months RTIs crude 18.5 19.8 1.11 (0.41; 3.05) 18.1 38.5 6.31 (2.59;15.41) 0.18 0.012
adjusteda 1.10 (0.40; 3.02) 5.82 (2.39;14.18) 0.19 0.014
  ≥ 3 long RTIs crude 8.0 10.7 1.64 (0.63; 4.32) 8.8 24.5 5.52 (2.55;11.95) 0.30 0.052
adjusteda 1.38 (0.51; 3.73) 4.72 (2.15;10.34) 0.29 0.053
 Upper 10% in diary score crude 9.5 9.1 0.89 (0.18; 4.36) 8.9 28.7 14.73 (4.41;49.21) 0.06 0.006
adjusteda 0.61 (0.12; 3.02) 10.65 (3.41;33.28) 0.06 0.004
Individual level:
 Upper 10% in diary score crude 9.5 9.3 0.97 (0.36; 2.61) 8.3 25.4 3.74 (1.94; 7.19) 0.26 0.026
adjusteda 0.77 (0.28; 2.10) 3.12 (1.58; 6.15) 0.25 0.022
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aadjusted by age (continuous) and educational status (three categories)

Discussion

RTIs constitute an important morbidity factor considering the high health care costs, the time lost from work, and the impaired quality of life among those recurrently affected [1, 2, 17]. Obesity belongs to one of the host risk factors for RTI and has possibly an emerging role due to the dramatically increasing prevalence of obesity worldwide. In the present study, we report on the association of obesity with individual RTIs as well as with a diary score summarising different incident RTI symptoms over a period of 18 months. Our investigation could demonstrate an association between obesity and RTIs confirming previous findings on influenza-like illness [9], bronchitis [18] and pneumonia [10, 12]. We also saw an association between obesity and rhinitis, sinusitis and pharyngitis/laryngitis. An elevated risk for sinusitis among obese was also reported in a population-based cohort of Danish women [13]. None of the two Danish population-based studies [12, 13] used ORs of monthly prevalence, but hazard ratios (HRs), as they could identify events on a daily basis. The HR of 1.6 [12] for the association with RTIs and the HR of 1.48 [13] for the association with URTIs are, however, of similar magnitude to the risk estimates which we observed. Mechanistically, excess adiposity might weigh down host defence as several mouse as well as human studies have suggested [19, 20]. The here observed associations were more prominent for LRTIs compared to URTIs, but evident for both, and more pronounced when considering long lasting or frequent RTIs compared to single symptoms. Based on the infection diary data, we generated a RTI diary score summing-up all ten symptoms and allowing to average per month, per whole season or over the whole period of three years. Considering the upper ten percentile of the distribution of such scores as an outcome, associations were typically stronger than when considering single symptoms, and interactions were more pronounced. Moreover, the results of the seasonal score were very similar or even stronger than those of the three-years score, arguing for the adequacy to query six months infectious events in future studies to identify the infection-prone sub-group of the population.

Lifestyle habits seem to contribute to an individual’s risk for RTI. Among them, cigarette smoking has been reported as a major environmental risk factor for recurrent and severe RTIs [4, 5]. Frequent contact to small children [21, 22], vitamin D deficiency [23, 24], and lack of physical activity [25, 26] constitute other exposures associated with heightened RTI risks. Moreover, higher levels of education were associated with a lower risk of CAP [27]. Based on those previous findings we investigated their role as possible confounders. The association between obesity and RTIs remained nearly unchanged after adjustment for age, gender, educational status, contact to children, smoking status, sports activity and nutrition scores, suggesting that the association is not markedly confounded by the effects of these factors on both BMI and the risk of infections. Also additional adjustment by measured serum vitamin D in a subgroup for which measurements were available did not change the risk estimates considerably. This supports arguments that the observed associations between obesity and RTI burden are due to physiological differences in the immune responsiveness between obese and non-obese individuals rather than lifestyle differences. In addition, some chronic diseases, foremost asthma and COPD, are associated with both an increased risk of RTIs and obesity [2832]. Considering these associations we investigated the effect of asthma, COPD and a co-morbidity score – summarizing the other chronic conditions – on the relationship between obesity and individual RTIs and the RTI diary score. Adjusting for these conditions individually and even more so in a combined fashion resulted in a considerable attenuation of the association between obesity and considered RTI outcomes. Hence part of the association between infections and obesity might be explainable by associations of co-morbidities with both.

We see a gender difference in the observed associations with more noticeable findings for women. A significantly increased risk for combined RTIs was also restricted to women in a Danish blood donor cohort [12]. Several lines of research support this notion: Szabova et al. and Ilavska et al. reported gender-dependent effects of obesity on the immune system [33, 34]. The effect of BMI on a variety of immune parameters including those with relevance for immune defence was much more apparent in women than in men [34]. NK cells (CD3-/CD16+/CD56+), represent first-line cells for the clearing of virus-infected cells. Reduced levels of these cells reported for obese women, but not for respective men, might underlie the gender effect seen in our study.

We also investigated a potential effect modification by sports activity and nutrition. Interestingly, an association between obesity and RTIs was evident only for those obese individuals who reported a higher level of sports activity. Thus, only the group of obese people who engaged in more intensive sports activity reported RTIs more frequently whereas obese people with low sports activity and non-obese with low or high sports activity showed comparable lower prevalences for most outcomes. We hypothesize that oxidative stress induced by vigorous aerobic as well as anaerobic sports activity is exacerbated in people with obesity, but not in normal weight individuals. Evidence supporting this has been previously published [35]. An imbalanced oxidative stress status may have negative consequences on mounting an appropriate immune response towards respiratory pathogens. Excessive reactive oxygen species (ROS) was shown to hinder T cell responses to viral infection [36] and ROS accumulation was detected in autophagy-deficient effector T cells rendering them incapable of controlling viral infections [37].

A similar surprising result was found when studying the effect modification by dietary patterns. Here we queried the participants’ dietary habits and classified them as adhering to a more favourable or more unfavourable dietary pattern according to Winkler et al. [38]. Aware of the limitations of a one-time assessment of a habitual diet, we found a more pronounced relationship between obesity and infections among obese people who reported an apparent healthier diet. Thus, again only the group of obese individuals who presumably eat a healthier diet showed an increased risk of RTIs. The question arises as to whether misreporting of dietary habits among these individuals with and without RTIs may explain the puzzle. One can imagine that obese individuals may have an increased perception of RTI related symptoms experiencing the contradiction between living a healthy lifestyle and being affected by excess weight and frequent infections. On the other hand the inconspicuous results from the non-obese population with respect to favourable and unfavourable diet pattern would somewhat argue against this explanation. Alternatively, among the group of people with obesity a genetically defined subgroup may exist predisposing to both, excess body weight and proneness to infections.

Strengths and limitations

As strengths of our study we count 1) its sample size, allowing for the analysis of effect modification, 2) its prospective design involving 18 months infection diaries for the exploration of the relationship between BMI and subsequent RTI frequency and severity, 3) the comprehensive information on lifestyle and co-morbidities allowing to study the interplay of such factors on their effect on infections, and 4) the wide range of outcome indicators considered. The uniformity of the results with respect to these outcomes also suggests that in the field of airway infection morbidity, studies may be comparable despite the fact that they often concentrate on different RTI outcomes. In line with the majority of epidemiological studies in this area of research, our study suffers from some limitations, including the reliance on self-reported outcomes and exposure data with the risk of misclassification. However, we found - for instance - a good agreement between BMI derived from self-reported weight and height data and BMI calculated from measured values available for a sub-cohort (n = 508). Moreover, differential misclassification which would substantially bias the relationship between obesity and RTIs is rather unexpected in this setting. The disproportional selection of women into the study may negatively impact the generalizability of some of our results.

Conclusions

In conclusion, in this prospective cohort of adults we found obese overrepresented among those reporting frequent and long-lasting RTIs. In line with previous epidemiological studies as well as basic research data we observed a stronger effect of obesity on infection risk for women compared to men. The interesting interaction with sports activity and presumed nutrition awaits follow-up investigations in subsequent studies that ideally shall provide improved measurements of the entire spectrum of physical activity and dietary habits.

Additional files

Additional file 1: (20.8KB, docx)

Details into the AWIS study and the sub-cohort. (DOCX 20 kb)

Additional file 2: (27.2KB, docx)

Flow diagram describing the study population. (DOCX 27 kb)

Additional file 3: (112.4KB, docx)

Development of the nutrition score to assess more favourable and unfavourable dietary pattern. (DOCX 112 kb)

Additional file 4: (14.2KB, docx)

Distribution of the number of diaries and months available per subject. (DOCX 14 kb)

Additional file 5: (62KB, docx)

Seasonal prevalence patterns for each symptom indicator. (DOCX 61 kb)

Additional file 6: (39.9KB, docx)

Association of obesity with RTIs adjusted by age, gender, education level, smoking, contact to children, asthma, COPD, Co-morbidity, physical activity, nutrition, removed organs and vitamin Da. (DOCX 39 kb)

Acknowledgements

We would like to thank the study participants for supporting the AWIS study. We are grateful to Anika-Kerstin Biegner, Hildegard Vingerhoet, and Beate Strauss for their help in setting-up the study.

Funding

German Federal Ministry of Education and Research (BMBF 01EO1303) and DZIF, German Center for Infection Research.

Availability of data and materials

The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.

Authors´ contributions

AN designed the study. IG recruited study participants and HHP contributed to the medical examination. SW prepared and analysed the data. WV supervised the data analysis and the revision of the manuscript. Interpretation of the data was performed by AN, WV, LM and SW. Manuscript was draft by LM, SW and AN. ME, ASS and HHP contributed to revisions to the final manuscript. All authors coordinated the study and critically revised the article. All authors read and approved the final manuscript.

Abbreviations

95%CI

95% confidence interval

AWIS

Airwayinfection susceptibility

BMI

Body mass index

CAP

Community acquired pneumonia

COPD

Chronic obstructive pulmonary disease

HRs

Hazard ratios

LRTI

Lower RTI

ORs

Odds ratios

ROS

Reactive oxygen species

RTI

Respiratory tract infection

URTI

Upper RTI

Ethics approval and consent to participate

The study protocol was approved by community officials and the Ethics Committee of the University of Freiburg (Ref. No. 258/11_120365). Written informed consent was obtained from all individual participants included in the study.

Consent for publication

No individual details or images are included in the present study. Consent to publish in not required.

Competing interests

The authors declare that they have no competing interests.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Footnotes

Electronic supplementary material

The online version of this article (10.1186/s12889-018-5172-8) contains supplementary material, which is available to authorized users.

Contributor Information

Livia Maccioni, Email: livia.maccioni@uniklinik-freiburg.de.

Susanne Weber, Email: sweber@imbi.uni-freiburg.de.

Magdeldin Elgizouli, Email: magdeldin.elgizouli@uniklinik-freiburg.de.

Anne-Sophie Stoehlker, Email: stoehlker@imbi.uni-freiburg.de.

Ilona Geist, Email: ilona.geist@uniklinik-freiburg.de.

Hans-Hartmut Peter, Email: hans-hartmut.peter@uniklinik-freiburg.de.

Werner Vach, Email: wv@imbi.uni-freiburg.de.

Alexandra Nieters, Phone: +4976127078150, Email: alexandra.nieters@uniklinik-freiburg.de.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Additional file 1: (20.8KB, docx)

Details into the AWIS study and the sub-cohort. (DOCX 20 kb)

Additional file 2: (27.2KB, docx)

Flow diagram describing the study population. (DOCX 27 kb)

Additional file 3: (112.4KB, docx)

Development of the nutrition score to assess more favourable and unfavourable dietary pattern. (DOCX 112 kb)

Additional file 4: (14.2KB, docx)

Distribution of the number of diaries and months available per subject. (DOCX 14 kb)

Additional file 5: (62KB, docx)

Seasonal prevalence patterns for each symptom indicator. (DOCX 61 kb)

Additional file 6: (39.9KB, docx)

Association of obesity with RTIs adjusted by age, gender, education level, smoking, contact to children, asthma, COPD, Co-morbidity, physical activity, nutrition, removed organs and vitamin Da. (DOCX 39 kb)

Data Availability Statement

The datasets used and/or analysed during the current study are available from the corresponding author on reasonable request.

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