Data sources

For this study Q fever notification data was obtained from the RIVM and extracted by gender (1407 men, 906 women), and age, with date of symptom onset between 1 January 2009 and 31 December 2009. Seasonal influenza is not a notifiable disease but influenza A(H1N1)pdm09 virus became notifiable from 29 April 2009. The RIVM's notification criteria changed on 15 August when only laboratory-confirmed cases admitted to a hospital or deceased required notification. Inconsistent notification for influenza A(H1N1)pdm09 made direct comparison with Q fever notification data impractical. Therefore, the Dutch Sentinel General Practice Network for influenza-like-illness (ILI) from NIVEL Netherlands Institute for Health Services Research, was used for A(H1N1)pdm09. This network of General Practitioners (GPs) covers a sample of ∼0·8% of the Dutch population that is nationally representative by distribution of age, gender, region and population density [Reference Heijnen10]. To obtain a 12-month period for both diseases, ILI symptoms from 27 April 2009 (the week of the first notified case) until 26 April 2010 were extracted by gender (1219 men, 1508 women), and age. Based upon the surveillance laboratory testing, raw ILI incidence data were considered to be 24% influenza positive [Reference Dijkstra11], which is within a range of previous influenza seasons [Reference Dijkstra12].

Composite health measure

The DALY is a composite health measure that represents one lost year of healthy life between the current health status and that of an ideal health situation. The DALY methodology is used by the World Health Organization (WHO) in its Global Burden of Disease (GBD) project [Reference Murray, Lopez and Jamison13] and also in the BCoDE project of ECDC. The DALY combines illness mortality, measured in terms of years lost due to premature death (YLL), and morbidity, the number of years lost due to disability (YLD).

The BCoDE project methodology, which was used for this paper, attributes DALYs of an infectious disease to the year the acute infection occurs. This allows for the attribution of long-term sequelae, which may generate a higher number of DALYs, to the causative infection rather than only the initial acute illness [Reference Wielders4]. We used 2009 Dutch life expectancy to calculate the YLL to increase comparability with other studies in The Netherlands [Reference Wielders4, 14]. The total YLL is the sum of the number of fatal cases (f) in 5-year age groups (j) multiplied by the remaining life expectancy (l) at the age of death over all health outcomes (i) with mortality [Reference Kretzschmar5]:

$${\rm YLL} = \sum\nolimits_i {\sum\nolimits_j {\,f_{ij}}} \times l_j. $$

The total YLD is the sum of the number of cases (n) in all age groups (j) multiplied by the duration of the health outcome (d) and by a disability weight (w) over all health outcomes (i). A disability weight represents the magnitude of disability of a health outcome and is between 0 and 1, representing perfect health and death, respectively [Reference Murray and Acharya15].

$${\rm YLD} = \sum\nolimits_i {\sum\nolimits_j {n_{ij}}} \times d_{ij} \times w_{ij}. $$

Total DALY count provides a measure of how a population is affected while DALYs/1000 symptomatic cases provides a measure of how a symptomatic individual is affected. DALY estimates in our study do not incorporate time or age discounting [Reference Murray and Acharya15].

Outcome tree

An outcome tree is a visual representation of the disease progression from infection, through health outcomes to an end state; recovery, death or disability for the remaining life expectancy (Fig. 1). To attribute long-term sequelae to a pathogen there must be a quantifiable, evidence-based causal relationship between infection and sequelae or, if lacking, consensus of disease experts. The total probability of entering a health outcome from a previous health outcome is the transition rate between the two health outcomes. Health outcomes are not mutually exclusive but each health outcome can have multiple, mutually exclusive health states, which take different severities of the health outcome into account. The health outcomes for Q fever and A(H1N1)pdm09 are taken from the published literature (Table 1). An extensive description of transition parameters and derivation are available in the Supplementary online material.

Fig. 1. Outcome trees for (a) Q fever and (b) influenza A(H1N1)pdm09. * Severe health state is included because acute Q fever has higher pneumonia hospitalization rate than influenza. † Severe health state has a duration of 10 years while mild has only a duration of 1·5 years. ‡ Severe health states include patients that develop acute respiratory distress syndrome (ARDS), pneumonia, otitis media and sepsis, and visit a General Practitioner. § Of the severe cases a proportion will develop complications and risk permanent disability.

Table 1. Health outcome transition rates and mortality rates for Q fever and influenza A(H1N1)pdm09

* Only one point estimate was found in the literature. To reduce artificial certainty a distribution range was taken between 90% and 110% values of the point estimate.

Adjustment for underreporting

Notified incidence data does not catch all cases and requires adjustment to account for asymptomatic infections, misdiagnosed cases or diagnosed cases not reported. Van der Hoek et al. published a study comparing serological incidence and notified cases of Q fever during the A(H1N1)pdm09 outbreak. They found that there were 12·6 times [95% confidence interval (CI) 6–26] more infected cases than notified cases [Reference van der Hoek16]. For the multiplication factor for A(H1N1)pdm09 we used the range 4·42–5·59 (ILI cases visiting a GP varied from 17·9% to 22·6%) [Reference Friesema17].

Uncertainty in parameter estimates

Uncertainty was incorporated into the model to account for uncertainty surrounding model parameters pertaining to transition probabilities and underreporting. Variability of the clinical presentation of the disease was not addressed as calculations measure how a population is affected. Depending on available information on parameter estimates either a uniform distribution or a programme evaluation and review technique (PERT) distribution was used [Reference Kerzner18]. A PERT distribution, frequently used in risk assessment, is defined by a minimum, a maximum and a mode value [Reference Clark19]. With a single estimate from the literature, uncertainty was incorporated by using a PERT distribution with the single estimate as the mode and its 90% and 110% as the minimum and maximum, respectively. With two estimates a uniform distribution was used. With three estimates a PERT distribution was used with the lowest estimate as the minimum, the highest as the maximum and the remaining as the mode.

Model parameters

To calculate DALYs the model requires not only information regarding the transition from one health outcome to the next (Table 1) but also information about the duration and disability weight of each health outcome of Q fever and A(H1N1)pdm09 (Table 2). The models used disability weights taken from the WHO GBD study if available, otherwise from Stouthard et al. [Reference Stouthard20], with the exception of permanent disability after sepsis [Reference Korosec Jagodic, Jagodic and Podbregar21]. Detailed information is included in the Supplementary online material.

Table 2. Disability weights and durations for Q fever and influenza A(H1N1)pdm09

* Stouthard et al. assumed a single infection per year and the disability weight represents the disability of a single, yearly infection.

For some outcomes no disability weights were available in the literature. In such instances proxy disability weights were used if the health outcomes were assumed to be similar in severity. In instances where health outcomes were more severe than proxy health outcomes, health states were used. Acute Q fever has no disability weight but is comparable to, although more severe than, an acute influenza infection for which there is a disability weight. The percentage of Q fever acute illness presenting with pneumonia is higher (61·5% [Reference Dijkstra22]) than for A(H1N1)pdm09 (34·3% of hospitalized cases (2·2% of symptomatic) [Reference van ‘t Klooster23]). The acute Q fever health outcome is comprised of a mild health state, using the seasonal influenza disability weight, and a severe health state, using a pneumonia disability weight for the additional proportion (61·5%) developing pneumonia. Clinical literature provided durations for the health outcomes of Q fever and seasonal influenza (Table 2). For Q fever's post-infectious fatigue syndrome, the proxy disability weight for ‘major depression, mild episode’ was used [Reference Stouthard20], although this is likely to be an under-estimation. A study of 85 patients with chronic fatigue syndrome [Reference Myers and Wilks24] showed a higher disability than the proxy disability weight when measured with a standardized instrument. For symptomatic chronic Q fever endocarditis, where death is frequently due to congestive heart failure [Reference Rubinovitch and Pittet25], the disability weight for ‘congestive heart failure’ was used [Reference Gami26]. For symptomatic chronic Q fever vascular infection no information regarding duration or disability was available so proxy parameters from symptomatic chronic Q fever endocarditis, a similar health state, were used.

There are disability weights available for influenza acute illness [Reference Stouthard20], deafness from otitis media [Reference Murray, Lopez and Jamison13] and permanent disability due to sepsis [Reference Korosec Jagodic, Jagodic and Podbregar21]. However, for permanent disability due to acute respiratory distress syndrome (ARDS), a disability weight for ‘mild-moderate COPD’ was used [Reference Stouthard20].

Scenarios

The literature provided conclusive information for most parameters of the models but to answer certain questions additional scenarios were required. For the Q fever baseline scenario, using parameters from Tables 1 and 2, the parameter values are well documented except for the transition rate from asymptomatic cases developing chronic Q fever. For the Q fever baseline scenario we assumed, in the absence of evidence to the contrary, that the transition rate is the same rate as the rate for symptomatic cases developing chronic Q fever. It is plausible that the rate for asymptomatic cases is lower than that of symptomatic cases so for Q fever scenario 2 we assumed that chronic Q fever from asymptomatic cases does not occur. In the literature a larger under-ascertainment multiplication factor was reported from a cohort of high-risk patients screened for Q fever. In Q fever scenario 3 we used this larger multiplication factor observed by Kampschreur et al. in the centre of an outbreak catchment area [Reference Kampschreur27].

For A(H1N1)pdm09 a baseline scenario was calculated using parameters from Tables 1 and 2 with mortality estimates divided equally between the genders as reported by Wijngaard et al. [Reference Wijngaard28]. Mortality is a large contributor to the total DALY estimate and A(H1N1)pdm09 affected younger age groups more than seasonal influenza in previous years. For A(H1N1)pdm09 scenario 2 the mortality age distribution for seasonal influenza replaced the A(H1N1)pdm09 distribution although the number of cases did not change [Reference Wijngaard28]. For A(H1N1)pdm09 scenario 3 the reported average case-fatality rate from the USA, Denmark, The Netherlands, New Zealand and England was used to observe how the baseline scenario compared to observed data [Reference Dawood29].

Software

The models were implemented in Microsoft Excel 2003 (Microsoft Corp., USA). Uncertainty was incorporated into the model using @Risk (Palisade Corp., USA). For all scenarios 10 000 simulations were performed using a random seed. Outcomes are reported as means of the posterior distribution and 95% error bounds were taken.