Age, sex, and socioeconomic differences in multimorbidity measured in four ways: UK primary care cross-sectional analysis

Summary

This study found substantial variation in the prevalence of multimorbidity using four different published definitions of multimorbidity. Multimorbidity 2+ had the highest prevalence, followed by multimorbidity 3+ and multimorbidity 3+ from 3+, and in all these definitions prevalence was considerably higher with increasing age. The prevalence was lowest using the mental–physical multimorbidity definition, with a flatter age distribution and higher prevalence in younger to early middle-aged adults than using the multimorbidity 3+ and multimorbidity 3+ from 3+ definitions. Multimorbidity prevalence was higher in people living in more deprived areas, and for all definitions inequalities (the difference in prevalence between the most and least deprived groups for each definition) were largest in middle age. At the point of greatest difference, people in the most deprived IMD decile would have the same prevalence of multimorbidity 40–45 years younger using the mental–physical multimorbidity definition, 15–20 years younger using the multimorbidity 2+ definition, and 10–15 years younger using the multimorbidity 3+ and multimorbidity 3+ from 3+ definitions. Prevalence of multimorbidity was higher in females than males using all four definitions, although adjusted associations were weak for all but mental–physical multimorbidity.

Strengths and limitations

Strengths of this study include systematic analysis of multimorbidity prevalence rates using a large primary care population dataset. Multimorbidity prevalence calculations using each definition were based on counting 80 LTCs (compared with a median of 17 LTCs reported in the wider literature¹⁰), including 10 mental health conditions, and almost all the conditions recommended by a recent international Delphi consensus study.¹⁹ The study, however, has a number of limitations. The dataset marginally underrepresents people in the most deprived IMD decile (7.6% versus 10% of the population of England). A mitigating factor is the large population size, which provides improved accuracy in the estimation of variance between associations with IMD deciles and stratification by SEP. All conditions were counted as equivalent, with no weighting based on severity, impact on quality of life, or clinical outcomes. However, unweighted counts are appropriate when the purpose is to measure prevalence,¹⁹ and future research could usefully explore associations of different multimorbidity measures with patient outcomes. The study uses routinely collected data, and given that these data are not collected for research purposes, errors and biases can be introduced at the collection and cleaning stages because of issues such as underreporting, data-linkage problems, and misclassification bias.²³ However, because these data were collected under real-world conditions they maximise representativeness and generalisability of the population studied, and allow examination of a large population size.²³

Comparison with existing literature

Some existing literature examines different definitions of multimorbidity. Storeng et al¹¹ used patient self-report of 38 conditions in people aged 60–69 years in Norway to examine multimorbidity defined as the presence of ≥3 LTCs from ≥3 ICD-10 chapters, termed ‘complex multimorbidity’ (the same definition as multimorbidity 3+ from 3+ in the current study). Multimorbidity 3+ from 3+ was present in 47.8% of those aged 60–69 years, which is close to the 44.5% estimate in this study, although they found larger differences in prevalence between females and males. Multimorbidity 3+ from 3+ was strongly associated with the need for assistance with activities of daily living and moderately associated with mortality.¹¹

Kato et al¹² performed a population-based study in Japan examining multimorbidity 2+ and multimorbidity 3+ from 3+ (also termed ‘complex multimorbidity’) in 38 889 people who were both functionally independent and not receiving any nursing care when they completed a self-report questionnaire. Multimorbidity 2+ prevalence for people aged ≥65 years was 52.0%, which is lower than the estimates in this study (69.6% in those aged 60–69 years rising to 93.4% in those aged ≥80 years). Similarly, prevalence of multimorbidity 3+ from 3+ was lower in people aged ≥65 years; 19.5% in people aged ≥65 years compared with prevalence of 44.5% in those aged 60–69 years rising to 80.3% in those aged ≥80 years in the present study. These differences are likely to reflect the selection of healthier people in the Japanese study; however, significant associations were also observed between both multimorbidity 2+ and multimorbidity 3+ from 3+ with mortality.

Socioeconomic deprivation was significantly associated with multimorbidity in a Scottish study by Barnett et al,⁹ who reported prevalence rates of 11.0% in the most deprived area versus 5.9% in the least deprived area. Similarly, Payne et al¹³ performed a retrospective cohort study in Scotland and found that mental health morbidity was more prevalent in areas of deprivation and independently associated with increased rates of unplanned hospital admission. Hauswaldt et al²⁴ examined prevalence of multimorbidity 2+ and multimorbidity 3+ from 3+ in German general practices. They found that females were more likely to be multimorbid than males and the sex ratio remained stable across both definitions; however, they did not examine mental–physical multimorbidity, which in the current study was more strongly associated with being a female than the other definitions.

Implications for research and practice

There are several areas that require further research. Large studies examining the relationship between multimorbidity types with important outcomes (such as functional status and quality of life, unscheduled hospital admission, and death) are needed because different definitions may be appropriate to facilitate targeting of particular groups of patients for intervention. This might be particularly important for mental and physical health combinations where mental health inequalities are a large driver for the difference in multimorbidity prevalence rates between most and least deprived categories using that definition. Further exploration of problems experienced by people with each definition of multimorbidity is needed, including issues relating to access to and continuity of care, so that services and interventions can be better designed to meet the needs of people with all definitions of multimorbidity.²⁵

This work builds understanding of disparities in the prevalence of multimorbidity based on age, sex, and, most strikingly, SEP, using different definitions. A key recommendation from a recent systematic review of systematic reviews of the definition and measurement of multimorbidity is that researchers need to be explicit about the definition used and rationale for this choice, so that comparisons can be made across studies from different settings.²⁶ Using a cut-off of ≥2 LTCs will allow researchers to be consistent with the majority of existing research;^10,26 however, the current study shows that a markedly different population group is identified when using the mental–physical multimorbidity definition compared with this most common definition. This is important because clinical judgement is required to adapt care accordingly for people with multimorbidity where the patient experience can involve difficulties managing competing treatment demands, especially seen in people with coexisting mental and physical health LTCs (for example, the additional difficulties experienced by people with schizophrenia and cardiovascular disease and/or diabetes where the condition itself can affect the ability to engage in lifestyle changes, and treatment with antipsychotics additionally predispose to cardiovascular risk).²⁷ Therefore, alternative definitions of multimorbidity, such as mental–physical, might be used to redistribute allocation of resource to general practices in areas of higher deprivation, and within these practices, towards a markedly younger population than in areas of lower deprivation where the age distribution of mental–physical multimorbidity is very different. Therefore, GPs can promote bespoke clinical judgements and reach shared care goals about a person’s needs, preferences, and health priorities²⁸ for this group who are known to have worse clinical outcomes than those with physical-only multimorbidity.^13,14

People living in the most deprived areas experience a greater burden of multimorbidity across all definitions, with a consistent dose–response effect (Supplementary Figures S1–S4), and this is most marked for mental–physical multimorbidity. Therefore, it is essential that policy and funding decisions support recommendations to tackle the inverse care law²⁹ and coordinate services to target higher-need populations, providing care delivered by multidisciplinary teams in these communities, with integration of health and social care services, and a particular focus on delivering combined care for mental and physical health conditions.³⁰ Additionally, continued work is needed to support GPs with appropriate clinical decision-making tools and models of care to support them in managing individuals with multiple conditions.²⁸

In conclusion, this study finds that different definitions of multimorbidity have varying associations with age, sex, and SEP. Understanding which people in society have higher rates of different definitions of multimorbidity can help GPs and policymakers to plan provision of care. Establishment of international consensus over which multimorbidity definitions should be used, in both research and clinical contexts, will improve translation of research findings across studies and provide clinical benchmarking to aid identification of individuals who are more likely to require additional support.