The impact of multimorbidity patterns on health-related quality of life in the general population: results of the Belgian Health Interview Survey

Data from the BHIS 2018 were used [22]. BHIS is a cross-sectional household survey that includes a representative sample of the Belgian population through multistage stratified sampling, involving a geographical stratification, a selection of clusters within each stratum, a selection of households within each cluster, and a selection of individuals within each household. In 2018, 11,611 individuals were interviewed with a response rate of 57% at the household level. Data collection were undertaken using face-to-face interviews (to obtain socio-demographic information) and supplemented with a self-administered questionnaire (to obtain HRQoL data). Details on methodology of the BHIS can be found elsewhere [23].

Prevalence of chronic diseases was self-reported, based on the following question: ‘Have you had one of the following disease or condition in the past 12 months?’. Participants indicated on a list of 38 diseases whether they had suffered from a certain disease with the responses ‘yes’ or ‘no’. The list also included chronic conditions (e.g. hypertension), consequences of chronic disease (e.g. hip fracture), and acute diseases with chronic consequences (e.g. stroke). The 38 chronic conditions were mapped into 23 chronic diseases or disease groups because many conditions are affecting the same body system. The mapping was based on the ICD-10 and a multimorbidity questionnaire (Table 1) [24, 25].

To date, consensus on the definition of multimorbidity is still lacking. The definition of ≥ 2 chronic diseases is under discussion, especially when highly prevalent conditions (e.g. hypertension) are included because these may result in high prevalence rates even if there is a lesser impact on patients’ symptoms, functional status, and HRQoL [26]. This study therefore used both cut-off values of ≥ 2 and ≥ 3 concurrent diseases to define multimorbidity.

HRQoL was measured using the EQ-5D-5L, the most widely used preference-based instrument for measuring HRQoL [21] and recommended by Belgian guidelines for economic evaluations in health care [27]. The EQ-5D-5L includes a descriptive system consisting of five dimensions: mobility, self-care, usual activities, pain/discomfort, and anxiety/depression. Each dimension has five response categories (no problems, slight problems, moderate problems, severe problems, and extreme problems/unable to), from which a single index value or utility score can be calculated ranging between 0 (death) and 1 (perfect health). Negative values can also be generated for health states perceived worse than death. Converting the dimension scores into a single index value requires a country-specific algorithm based on population-level preferences for different health states. In Belgium, however, such an algorithm is so far only available for the EQ-5D-3L encompassing only three answering possibilities [28]. A cross-walk function was therefore used to map the EQ-5D-5L health states to EQ-5D-3L health states, resulting in index values ranging from − 0.158 to 1 [29, 30]. The EQ-VAS, measuring respondents’ self-rated health on a 0–100 scale, was not included in the BHIS 2018.

The following socio-demographic data were used: age (15 to 101 years), sex (male, female), educational attainment (no diploma, lower education, lower secondary education, higher secondary education, post-secondary education, higher education, doctoral degree), civil status (single, married or legally cohabiting, widow(er), divorced), and region (Brussels, Flanders, Wallonia). Socio-economic status was based on the highest level of education of the household and classified into low (lower secondary education or less), intermediate (higher secondary education), and high (higher education). Only participants who completed the EQ-5D-5L were included.

Statistics were undertaken using IBM SPSS statistical software (version 26.0). The design effects of the survey were taken into account to deal with the complex design of the BHIS [23], resulting in representativeness for the total population, at national, regional, and provincial level.

A contingency table in matrix form was constructed to determine patterns of combinations of diseases. To increase robustness, only combinations occurring ≥ 2.5% (arbitrary cut-off) in the population were considered here.

We fitted linear mixed models to analyze two-way and three-way interaction effects (i.e. effect modifications) of disease combinations on HRQoL. The EQ-5D-5L index score was the dependent variable in all models. The individual diseases were included as fixed effects. Each model also contained a two-way or three-way interaction term plus all underlying interactions for the dyad and triad combinations, respectively. The following design effects of the survey were taken into account: clustering at household level as random effect (random intercept for household), regional stratification as fixed factor, and survey weights as weighting. Normality of the residuals was assessed by Q-Q plot. We relied on the central limit theorem, given our large sample size. Significance of the interaction between two comorbidities indicates that the effect of one comorbidity is different in the presence or absence of the other comorbidity. A negative interaction (i.e. synergistic effect) shows that the combined effect of two comorbidities was associated with an estimated mean decrease in HRQoL that is higher (stronger/more pronounced) than expected based on the additive effect of the comorbidities separately. Conversely, a positive interaction (i.e. antagonistic effect) indicates that the combined effect of two comorbidities was associated with an estimated mean decrease in HRQoL that is less than expected based on the additive effect of each of them individually. It is important to highlight that effect modification is bidirectional meaning that each disease simultaneously influences, and is influenced by, the other disease. Estimated marginal mean HRQoL scores for each disease combination were calculated from the final model. The regression models were not adjusted for several covariates (e.g. age, sex, educational attainment), because the aim was not to find the model with the most ideal goodness-of-fit, but rather to depict the actual situation. P-values have not been adjusted for multiplicity. Statistical significance was set at P < 0.05, trends towards significance (P < 0.1) were also presented.

The EQ-5D-5L was completed by 85% of participants (n = 7,509). Descriptive statistics are outlined in Table 2. The mean age was 48.6 years, and slightly more than half were women (51.6%). About half of the participants had a high socioeconomic status (50.8%), whilst 16.8% had a low socioeconomic status. Approximately 30% had no chronic disease and 23.4% had one chronic disease. Multimorbidity occurred in 46.7% (≥ 2 conditions) and 29.7% (≥ 3 conditions) of the participants. Multimorbidity was more prevalent in women and increased with age and lower socioeconomic status. Females, older persons, and persons with lower socioeconomic status had lower HRQoL. Moreover, HRQoL decreased considerably with the presence of multiple chronic diseases. Participants with ≥ 3 chronic diseases (0.65) reported a considerably lower HRQoL score compared to participants with two chronic diseases (0.79) or with one chronic disease (0.85). Participants without chronic disease reported the highest HRQoL score (0.90).

The three most common chronic diseases were dorsopathies (31.4%), hypertension/high cholesterol (28.6%), and arthropathies (22%) (Table 3). On the other hand, stroke and hip fracture had a prevalence lower than 1%. HRQoL scores varied between diseases. The highest HRQoL score was reported in persons with allergy (0.75), followed by hypertension/high cholesterol (0.73), and thyroid problems (0.71). The lowest HRQoL score was reported in persons with depression (0.53), followed by stroke (0.54), and chronic fatigue (0.58).

The prevalence matrix generated 41 dyad combinations with a prevalence ≥ 2.5% (Online Appendix 1). The most prevalent dyads were arthropathies + dorsopathies (14.6%), hypertension/high cholesterol + dorsopathies (12.8%), and hypertension/high cholesterol + arthropathies (11.8%). Figure 1 and Fig. 2 summarize the interaction effects and estimated mean HRQoL scores for the 41 dyads respectively.

The highest HRQoL score was reported in persons with allergy + respiratory disease (0.69) and hypertension/high cholesterol + allergy (0.69). The lowest HRQoL score was reported in persons with depression + arthropathies (0.44) and depression + genitourinary problems (0.44).

Based on our data, effect modification was observed for a minority of combinations (14 out of 41 pairs) and showed a mixed pattern: some interactions were negative/synergistic, some interactions were positive/antagonistic. The condition appearing the most frequently in significant disease pair interactions was dorsopathies, followed by respiratory disease and arthropathies.

The majority of disease pairs (9 out of 14 pairs) showed negative/synergistic interactions. The strongest negative/synergistic associations were found for dorsopathies + respiratory disease (P < 0.01), hypertension/high cholesterol + neurological disorder (P < 0.01), arthropathies + thyroid problems (P < 0.01), and genitourinary problems + respiratory disease (P < 0.01). The estimated mean decrease in HRQoL is also stronger in the presence of the following coexisting conditions: arthropathies + respiratory disease (P < 0.05), dorsopathies + cardiovascular disorder (P < 0.05), dorsopathies + thyroid problems (P < 0.05), hypertension/high cholesterol + depression (P < 0.1), and dorsopathies + genitourinary problems (P < 0.1).

The strongest positive/antagonistic association was observed for respiratory disease + allergy (P < 0.01). The estimated mean decrease in HRQoL is also smaller in the presence of the following coexisting conditions: depression + dorsopathies (P < 0.05), arthropathies + dorsopathies (P < 0.1), chronic fatigue + neurological disorder (P < 0.1), depression + chronic fatigue (P < 0.1).

Thirteen triad combinations with a prevalence ≥ 2.5% were observed. The most frequent triad combinations were hypertension/high cholesterol + arthropathies + dorsopathies (8.1%), hypertension/high cholesterol + genitourinary problems + dorsopathies (5.1%), and dorsopathies + arthropathies + genitourinary problems (4.9%). Figure 3 and Fig. 4 summarize the interaction effects and estimated mean HRQoL scores for the thirteen triads respectively.

The highest HRQoL score was reported in persons with allergy + hypertension/high cholesterol + dorsopathies (0.62). The lowest HRQoL score was reported in persons with depression + genitourinary problems + dorsopathies (0.37).

Recently, an EQ-5D-5L value set for Belgium has been developed [48]. As such, we performed a sensitivity analysis to assess the impact of the new value set on results and conclusions. The analysis showed that results systematically differed according to the value set used. The EQ-5D-5L value set produces higher values overall and across all conditions included. These results are not unexpected because similar findings were found in other countries (e.g. England, The Netherlands, Spain) with higher utility values for the EQ-5D-5L value set compared to the crosswalk value set [49‐51]. In addition, the new value set generates 12 additional significant interaction effects for dyad disease combinations (Online Appendix 2). In detail, four significant positive/antagonistic interactions have disappeared, 16 significant negative/synergistic interactions have been added. Moreover, mainly disease combinations with depression and chronic fatigue changed from positive/antagonistic interactions to negative/synergistic interactions, with stronger significance levels. In general, only disease combinations that fall within the same disease classification system (i.e. allergy + respiratory disease, hypertension/high cholesterol + cardiovascular disease) have an antagonistic relationship. As such, we can conclude that there will always be an synergistic/negative HRQoL effect, making multimorbidity even more important than initially thought. Possible reasons for the observed differences may be attributed to changes in for example population demographics, preferences over time, descriptive system of the EQ-5D, and valuation method used [49, 51]. The magnitude of differences between value sets may however have important implications for decision-making as they can greatly impact estimates (e.g. QALYs) of health economic evaluations.

This study has several major strengths. A first strength is that the BHIS data is based on a large, representative sample of the general population which strengthens external validity. A second strength is the availability of a Belgian value set for the EQ-5D-3L because guidelines recommend country-specific value sets to estimate HRQoL more precisely within a country. Another strength is the large sample of morbidity across 38 long-term conditions, which allowed the assessment of interaction effects of coexisting conditions with low prevalence often not detectable in smaller studies [31, 52]. Nevertheless, grouping the 38 diseases into 23 disease groups may have masked potential interactions between diseases within larger disease groups, however, if synergistic or antagonistic effects were present, it is also expected to detect them across disease groups [17].

Some limitations should be considered. A first limitation is that the presence of chronic diseases was based on self-reports. Accurate self-reports require sufficient knowledge of participants to report on medical conditions. This is challenging because patients are often confused to distinguish between symptoms and the actual disease, and because some diseases are very subjective (e.g. chronic fatigue) [53]. In addition, it is possible that people indicate that they have several diseases because these conditions share homogeneous symptoms and common aetiology. Another important concern when using self-reports, especially over a 12-month time period, is recall bias [54]. Self-reports are not as valid and reliable as medical records because respondents may underestimate/overestimate the prevalence of medical conditions and risk behaviours [55‐59]. However, several studies found a high concordance between self-reports and medical records when measuring the prevalence of multimorbidity [60‐64]. As well, self-reported data are the most appropriate alternative in the absence of objective diagnoses. Another limitation is the non-exhaustive list of chronic diseases included in the BHIS. This implies missing other important diseases such as Alzheimer's disease, which has previously been found to greatly impact HRQoL [65, 66]. Besides, a minority of mental or psychiatric conditions were included in the list. Furthermore, despite our relatively large sample size, some diseases were underrepresented, which might produce bias and decreasing statistical power. Another limitation is that disease duration has not been taken into account. Studies found worse HRQoL in specific diseases with longer disease duration, whilst other studies showed that longer disease duration was associated with better HRQoL [67]. Another limitation is that the EQ-5D-5L covers relatively few dimensions of HRQoL that are disease-specific. The EQ-5D may therefore be insensitive to health problems (e.g. nausea, sleep disturbance) experienced by specific diseases [68]. Moreover, this study aimed for representativeness, hence the regression models were not corrected for several covariates (e.g. age, sex, educational attainment). A final limitation is the sampling procedure in the BHIS which can imply selection bias.