Introduction
The socioeconomic differences in morbidity and mortality, in particular across educational levels, have been widening in high-income countries for decades [1–8]. A wealth of research has linked socioeconomic inequality to reduced population health [2, 9–11]. Wilkinson’s (1996) influential work first demonstrated that it is not necessarily the wealthiest countries with the most healthy populations, but countries with the smallest income differences within society [9, 10]. More unequal societies show shorter life expectancy and higher prevalence rates of obesity, HIV infections, and mental illness, among others [9, 12–23]. Further, social disparities in multimorbidity are inversely related to educational achievement [24, 25]. Recently, high-income countries have seen increased income inequality [2]. In Europe, one out of four adults is now at risk of poverty or social exclusion [2, 26, 27]. Moreover, the fallout from the COVID-19 pandemic has particularly affected the socioeconomic low-income groups with chronic conditions such as heart diseases, diabetes, and chronic obstructive pulmonary disease (COPD) [28].
Along with increased income inequality [2], the disease burden of chronic conditions and multimorbidity is increasing [29, 30]. Consequently, the expenditures also increase worldwide along with ageing populations [31–40]. These expenditures have earlier been shown to account for up to 80 per cent of healthcare costs [41–44]; and to be positively correlated with multimorbidity and socioeconomic factors [45]. To control the growing cost of healthcare, decision-makers require access to reliable, real-world evidence of disease and treatment patterns [46, 47]. Real-world evidence of disease prevalence is essential for estimating the burden of disease, cost of illness, and budget impact on new health technologies [48, 49]. Thus, the World Health Organization (WHO) has long recommended improvement in data surveillance of chronic diseases [37]; and other studies have criticised and recommended additional methodological improvements measuring disease burden [50–53]. Hvidberg et al. (2016, 2019) earlier replied to these calls [54–58]. While most prevalence studies usually included a single or a limited number of chronic conditions [44, 59–66], Hvidberg et al. (2019) encompassed the full-sized disease burden of chronic conditions based on uniform methodology physician-reported conditions covering the whole adult population of Denmark [56, 57]. Besides the completeness, the advantages of this single-study approach were reliable, and comparable prevalence rates were estimated across conditions which often cannot be achieved in other studies caused by biases from comparing different, heterogenic data [54]. The study comprised 199 chronic conditions and found that a record high of two-thirds of the population had at least one chronic condition [56]. However, while sex and age characteristics were identified, the studies did not investigate the socioeconomic inequalities across the conditions. Comparable knowledge about socioeconomic differences within and between chronic conditions would, for example, support decision-makers or healthcare professionals’ evidence according to service needs and treatment potentials for future prioritisation and socially differential clinical treatments, as socioeconomic larger disparities could indicate treatment potentials or patient needs [24, 67–72]. This has long been used to inform and target populations within the treatment of health behaviours like smoking, exercise, obesity etc. [67], but less so within chronic diseases, although numerous studies have identified disparities within single diseases [25, 56]. Thus, comparable estimates of socioeconomic disparities across a long range of chronic conditions could provide new insights and practical usefulness and move future prioritisation and socially differentiated treatment forward.
The present study estimates the national prevalence rates of socioeconomic inequalities regarding educational levels, income, and socioeconomic position of 199 chronic conditions of the whole adult Danish population. The study provides an off-the-shelf catalogue and a comparative overview of socioeconomic inequalities across chronic conditions for healthcare professionals, decision-makers, researchers, and clinicians to use, for example, in practical treatment, targeting low-income patients of interest. We also want to provide concrete information for future prioritisation for specific chronic conditions based on the identified socioeconomic differences and size of prevalence. To the best of the authors’ knowledge, the present study is the first and most comprehensive, independent register-based attempt to estimate socioeconomic inequalities associated with the disease burden of a whole nationwide population using a comparable, uniform methodology.
Methods
Population
The nationwide study population comprised 4,555,439 Danish residents aged 16 years or older, alive on 1 January 2013. Hereof, 45.2% were 16–44 years old, 45.9% were 45–74 years old, and 8.9% were 75 years or older. The population had a mean age of 46.7, and 49.2% were men.
The registers
Seven registers from Statistics Denmark were employed in the current study (Table 1). The registers have been recorded for public administration, for example, for claims and management, surveillance, tax, and control functions by government officials at the individual level [73].
[Figure omitted. See PDF.]
The Population’s Education Register (PER) [74] and The Income Statistics Register (ISR) [75] were used for identifying socioeconomic disparities regarding educational achievements, income level, and socioeconomic position. The Danish National Patient Register (NPR) [76], the Danish Psychiatric Central Research Register [77], The National Health Service Register (NHSR) [78] and The National Prescription Register (TNPR) [79] contained information on physician-reported ICD-10 hospital diagnoses, prescriptions, and general practice services. These data were used to identify the 199 chronic conditions by clinical recommendation [54, 55, 58]. Finally, sex, birth date, and other information originated from the Danish Civil Registration System [80]. The registers were linked together by the unique personal identification number assigned to every person [81]. The employed registers and quality are described elsewhere [54–56].
Socioeconomic measures
Three measures of socioeconomic disparities were used: educational achievements, personal income, and socioeconomic position in society. All three variables were derived from Statistics Denmark PER and ISR registers (coming variable names are in brackets) for the year 2012 on 31 December. Education was measured as the highest archived education based on the International Standard Classification of Education, ISCED2011 (AUDD). Educational achievements were divided into five levels: 1. no education or training, 2. student, 3. shorter, 4. middle, and 5. higher education. Please note that students, who did not have any other achieved education, were classified separately using the information of their socioeconomic position (SOCIO02), into category 2 (student). This was done as students are usually younger, healthier, and thus have different health conditions than people with no education. Income was measured as personal income (DKR) after tax (DISPON_NY). Income was divided into quartiles to better allow for international, relative comparisons and reported as means. Finally, the socioeconomic position was measured based on standard classification (SOCIO02) into the following seven categories: 1. Retired, age, 2. Retirement, early retirement (health), 3. Sick leave/leave, 4. Unemployed/social benefits, 5. Unemployed minimum six months, 7. In training/study, 8. Employed, and 9. Others not in the workforce.
Defining ’chronic condition’
A detailed description of the phases and methods used to define the 199 chronic conditions are provided elsewhere [54, 55, 58]. In summary, we defined a ’chronic condition’ according to the definition if the ’…condition had lasted or was expected to last twelve or more months and resulted in functional limitations and/or the need for functional limitations and/or the need for ongoing medical care’ [56, 82–84]. A clinical expert panel identified the ICD-10 diagnosis considered ’chronic’ based on the above definition [55]. The experts aggregated the ICD-10 diagnoses to 199 conditions, where several conditions included subgroups of different ICD-10 diagnoses; thus, some defined conditions contained several different conditions within related disease groups. Subsequently, all ICD-10 diseases considered chronic by definition included the full-population burden of chronic conditions [55, 56].
The data algorithms identifying the chronic conditions in registers
Several chronic conditions do not last for a lifetime, although they last longer than the defined 12 months. The differing ’chronicity’ of the identified chronic conditions were divided into four groups of severity depending on how long they were expected to last [55]:
* Category I: Stationary to progressive chronic conditions (no time limit equals inclusion time going back from the time of interest for as long as valid data were available. In the current study, this starting point was defined by the introduction of the ICD-10 diagnosis coding in Denmark in 1994);
* Category II: Stationary to diminishing chronic conditions (10 years from register inclusion time to the time of interest);
* Category III: Diminishing chronic conditions (5 years from register inclusion time to the time of interest); and
* Category IV: Borderline chronic conditions (2 years from register inclusion time to the time of interest).
Adapted from Hvidberg et al. (2016, 2019) [55, 56].
This approach was developed to handle a well-known challenge of register research: if a condition is only identified once, for example, 10 or 25 years earlier, can researchers then be sure that the patient still suffers from this condition at present. Thus, to address this, all 199 chronic conditions were allocated into one of the four chronicity categories by medical experts. The allocation was based on a clinical judgment of how long the different chronic conditions with the best possible clinical certainty would still suffer from the condition from the time of interest, 1 January 2013. This new approach can also be used at different times of interest and as a proxy for severity.
An algorithm was employed based on the clinicians’ definitions and allocation of the 199 chronic conditions and related ICD-10 codes into one of the four categories. However, 35 chronic conditions were not judged by the medical experts to be appropriately representative using exclusively ICD-10 diagnosis. Thus, 35 more complex disease algorithms were suggested and employed using multiple registers, including medicine, hospital treatments, and general practice services. Furthermore, details of the 199 distinctive definitions, the medical experts and panel process, the allocation of conditions into the four categories, and the detailed algorithms for replication can be found in references [55, 58].
Statistical analysis
Disease prevalence rates were calculated per thousand subjects, i.e., the number of conditions identified, divided by the total population (N = 4,555,439) multiplied by 1000. Hence, prevalence rates were calculated from a specific point in time, 1 January 2013, thus comprising conditions dating back from this point of time-based on the four inclusion time periods. Disease prevalence within educational levels, sex, or age were calculated as the number of conditions within the socioeconomic variable of interest, divided by the total of the socioeconomic variables, multiplied by 1000 (Tables 2 and 3 and S1 Table in S1 File). Ratios were calculated by dividing no educational achievement with high educational achievement prevalence rates. Per cent proportions within the diseases were calculated for levels of education, income quartiles, and socioeconomic position (Table 4, S1 and S2 Tables in S1 File) as the number of patients for each level of the socioeconomic variable of interest, divided by the total number of patients within the disease, multiplied by 100. Finally, nine multiple binary logistic regression models were carried out to control for potential confounding and residual correlations of the crude estimates (Table 5). This was done for the two key socioeconomic measures, educational levels, and income, hence one binary model for each of the five education levels and the income quartiles. All regression models included the 199 chronic conditions, gender and age as predictors.
[Figure omitted. See PDF.]
[Figure omitted. See PDF.]
[Figure omitted. See PDF.]
[Figure omitted. See PDF.]
Compliance with ethical standards
Declaration and approval to conduct the study were obtained from the Danish Data Protection Agency and the Secretariat for Research Processing Records, Data and Development Support, Region Zealand (REG-142-2021). No informed consent was required. Statistics Denmark anonymized all register-data before the data were made available on their server.
The conditions were ranked according to their proportion of patients with no educational achievement. The higher ranking, the higher proportion of patients with no educational achievement within the disease. Direct standardisation of age and sex from the national average of age and sex on 1 January 2013 was included to identify differences free of primary effects [85, 86].
In summary, the prevalence rates for the disease groups and chronic conditions were stratified and presented by educational levels, sex and age (Tables 2 and 3 and S1 Table in S1 File), education levels, income quartiles (Table 4 and S2 Table in S1 File), and socioeconomic positions (S3 Table in S1 File). A ratio between disease prevalence for no and high educational levels was calculated to identify inequalities within and between conditions (Tables 2 and 3, S1, S2 and S4 Table in S1 File). Ranked conditions were used to identify clusters and groups of conditions with the lowest educational levels (Table 4 and S2 Table in S1 File). Moreover, mean and ratios were presented for chronic conditions (Table 2) and income (Table 4) with standard deviations. Standardised prevalence estimates are presented in brackets where applicable. Finally, to provide the reader with an overview of highlights, the analysis and commenting will be focussed on all the 14 overall disease groups of the 199 chronic conditions, 29 specific common conditions including overweight, regularly measured in the National Population Health Surveys every four years [87] among others; and the 50 specific chronic conditions with the highest proportions of patients with no educational achievement. However, readers can still look up other estimates of the total 199 presented chronic conditions within the tables.
Data analysis and management were carried out using SAS 9.4 at Statistics Denmark’s research servers. Means and standard deviations were calculated using SAS “proc means”, frequencies were calculated based on the “proc tabulate” function, and logistic regression was calculated using the SAS “proc logistic” function.
Results
The following descriptions provide an overview of the 14 overall disease groups, on the 29 most common conditions as well as overweight, and the 50 conditions with the highest proportion of patients with no educational achievement.
Table 2 shows the prevalence of the 14 overall disease groups and five common medicines associated with educational achievement, sex, and age groups for patients with no educational achievement. The prevalence of having one or more chronic conditions for patients with no educational achievement was 768 per thousand compared to 601.3 for patients with higher educational achievement. This is equivalent to an overall educational ratio of 1.3, i.e., indicating that patients with no educational achievement are 1.3 times more likely to have a chronic condition than people with high educational achievement. Women with no educational achievement had a higher prevalence (272.6 per thousand) of one or more chronic conditions than males with no educational achievement (188.2 per thousand). Increasing age for patients with no educational achievement also increased the risk of having one or more chronic conditions, ranging from 582.0 (age 16–44), 819.5 (age 45–74) to 954.6 per thousand for 75+ years old. The largest overall educational differences were found among patients using antipsychotic medicine with a ratio of 4.3. Other large differences were found for disease group F (mental and behavioural disorders; ratio 2.5), disease group E (endocrine, nutritional and metabolic diseases; ratio 2.4), disease group I (diseases of the circulatory system; ratio 2.1), and disease group K (diseases of the digestive system; ratio 2.1).
Table 3 provides the prevalence for 29 common, highly prevalent diseases and overweight (see S1 and S4 Tables in S1 File for all conditions) by no and high educational achievement, sex, and age groups for people with no education (see S1 and S4 Tables in S1 File for all 199 conditions). The collective conditions account for a total disease burden of 563 per thousand having one or more chronic conditions. The highest educational differences are found among mental conditions like schizophrenia (ratio 5.9), hyperkinetic disorders (ratio 5.2), dementia (ratio 4.9), but also osteoporosis (ratio 3.9), type 2 diabetes (ratio 3.8), COPD (ratio 3.3), and heart conditions and stroke (ratios ranging from 2.3–3.1). The lowest educational differences are found in respiratory allergy (ratio 0.8), asthma (ratio 0.7), and type 1 diabetes (ratio 1.1) and rheumatoid arthritis (ratio 1.1). The sex and age trends indicate a higher disease prevalence among women and increasing prevalence with increasing age, except for type 1 diabetes, schizophrenia, and hyperkinetic disorders. Moreover, schizophrenia, hyperkinetic disorders, and type 1 diabetes also showed decreasing prevalence rates with increasing age, contrary to the general trend of most other conditions.
Table 4 displays the prevalence (per cent within conditions) of the five educational levels, income quartiles, and the mean income for all the 199 chronic conditions. However, the following exclusively comments on the 50 conditions with the highest proportion of patients with no educational achievement ordered in ICD-10 overall disease groups (S2 Table in S1 File comprising only the 50 conditions sorted). Mental conditions (F) had the overall highest proportion of patients with no educational achievement with 15 conditions out of the 50 conditions. This included eight conditions in the top 10 of conditions with the highest proportion of patients with no educational achievement: mental retardation (F70-F79), disorders of psychological development (F80-F89), schizophrenia (F20), dementia (F00, G30, and other disease codes for dementia), emotionally unstable personality disorder (F603), mental and behavioural disorders due to psychoactive substance use (F11-F19), organic, incl. symptomatic, mental disorders (F04-F09), and schizotypal and delusional disorders (F21-F29). Diseases of the respiratory system (J) had the overall second-highest proportion of patients with no educational achievement with one condition in the top 10 and three conditions in the top 50: Bronchitis (F40-42), Emphysema (J43), and COPD (J44, J96, J13-J18). Diseases of the circulatory system (I) had the overall third-highest proportion of patients with no educational achievement. This included 12 conditions: atherosclerosis (I70), other peripheral vascular diseases (I73), sequelae of cerebrovascular disease (I69), aortic and mitral valve disease (I05, I06, I134, I135), heart failure (I11, I13, I13.2, I142, I142.6, I142.7, I142.9, I150, I150.1, I150.9), chronic ischaemic heart disease (I25), stroke (I60, I61, I63-64, Z501), acute myocardial infarction (I21-I22), ischaemic heart diseases (I20-I25), atrioventricular and left bundle branch block (I44), AMI complex/other (I23-I24), pulmonary heart disease and diseases of pulmonary circulation (I26-I28), and atrial fibrillation and flutter (I48). Diseases of the nervous system (G) had the overall fourth highest proportion of patients with no educational achievement and included four conditions: cerebral palsy and other paralytic syndromes (G80–G83), Parkinson’s disease (G20, G21, G22, F02.3), epilepsy (G40–G41), and systemic atrophies primarily affecting the central nervous system (G10–G14, G30–G32). Chronic viral hepatitis (B18) was ranked number five. Cancers (C) and In situ and benign neoplasms (D) had the overall sixth highest proportion of patients with no educational achievement. This included three conditions: other anaemias (D64), malignant neoplasms of bronchus and lung (C43), and aplastic and other anaemias (D60-D63). Diseases of the eye and ear (H) had the seventh highest proportion of patients with no educational achievement. This included four conditions: presbycusis (H911), disease of the eye lens (H25-H28), blindness and partial sight (H54), and other retinal disorders (H35). Diseases of the musculoskeletal system and connective tissue (M) had the eighth highest proportion of patients with no educational achievement and comprised four conditions: coxarthrosis (M16), rheumatism (M790), osteoporosis in disease classified elsewhere (M82), and polyarthrotis (M15). Finally, chronic renal failure (N18) and type 2 diabetes (E11) had the ninth and tenth highest proportion of patients with no educational achievement. Notably, the above-mentioned specific conditions do overlap in ranks and can therefore not be entirely categorised into ten discrete groups, although this broadly reflects the groups’ average ranks. Income inequalities across the conditions broadly follow those of education, although differences exist. Readers are encouraged to explore this further for conditions of interest. The differences in the disease prevalence for people with no educational achievement within diseases ranged from 17.8–80.3 per cent. Hereof, many chronic conditions occurred between 30 and 40 per cent (Fig 1). In total, 153 conditions of the 199 chronic conditions had more patients with no education than the national average of 29.0. An extract of Table 4 with solely the 50 chronic conditions sorted by the highest proportion of patients with no educational achievement can be found in S2 Table in S1 File. The table also includes the ratio between prevalence for high and no educational levels and per cent proportions of high and low levels of education. Finally, an overview of the socioeconomic positions can be found in S3 Table in S1 File.
[Figure omitted. See PDF.]
The dashed line is the national average of 29.0 per cent.
Table 5 presents an off the shelf catalogue of odds ratios (OR) from nine logistic regression models between the five educational levels and the income quartiles and all the 199 chronic conditions, gender and age to control for potential confounding and residual correlations of the crude estimates. However, the following exclusively comments the regression model for no educational achievement vs high educational achievement and overall tendencies for the conditions based on their disease groups. Overall, Mental and behavioural disorders (F) and Diseases of the musculoskeletal system and connective tissue (M) have the highest level of social disparity. For the mental conditions, significant, high OR ranging from 2.1.-6.0 (excluding mental retardation) for conditions like mental and behavioural disorders due to psychoactive substance use, schizophrenia, post-traumatic stress disorder, emotionally unstable personality disorder, and hyperkinetic disorders (ADHD). For musculoskeletal diseases, significant high OR ranging from 1.7–4.0 were found for conditions like fibromyalgia, rheumatism unspecified, myalgia, shoulder lesions, and spinal osteochondrosis. Interesting, significant decreasing OR were found for a common condition, rheumatoid arthritis (OR = 0.7) and enthesopathies of lower limb (OR = 0.5). For Diseases of the nervous system (G) and Diseases of the eye and ear (H), some high significant OR were found within the range of 1.7–2.8 for specific conditions like corneal scars and opacities, epilepsy, mononeuropathies of upper limb, cerebral palsy and other paralytic syndromes, and other disease of the inner ear. Diseases of the circulatory system (I), Diseases of the respiratory system (J), and Disease of the digestive system (K) displayed higher significant OR of 1.6–1.9 for chronic conditions like ventral hernia, ulcers, atherosclerosis, bronchitis, emphysema, and chronic obstructive disease (COPD). Particularly disease groups I and H relatively many had high, significant, decreasing OR ranging from 0.5–0.7, indicating significant correlation with higher educational achievement. Disease group (B), and endocrine disorders (E) show high significant OR for patients with Chronic viral hepatitis with odds ratio at 3.7 and diabetes type 2 with odds ratio at 1.9. Finally, Cancers (C) was the disease group with the lowest OR and highest number of decreasing OR, i.e., cancers displayed the reversed social disparity as patients with high educational achievement have higher risk of getting e.g., malignant neoplasm of skin, other malignant neoplasms of skin, malignant neoplasms of breast, and malignant neoplasm of prostate.
Discussion
From present findings, the overall disease prevalence is 768 per thousand for people with no educational achievement compared to 601.3 for people with higher education (ratio 1.3), which suggests that overall people with no educational achievement have a 30 per cent higher disease burden. Among patients with no educational achievement, women had higher disease prevalence than men, and the prevalence increased with age for most conditions, although variations were found across conditions. These results are comparable to those of other studies, which also find a higher disease burden for patients with no educational achievement, and a higher prevalence of women among patients with no educational achievement [24, 45]. Across disease groups, the largest educational differences were found within disease group F–Mental and behavioural disorders (ratio 2.5), E–Endocrine, nutritional and metabolic diseases (ratio 2.4), I–Diseases of the circulate system (ratio 2.1), and K–Diseases of the digestive system (ratio 2.1). Among specific chronic conditions, schizophrenia had the largest educational differences (ratio 5.9) followed by hyperkinetic disorders (ratio 5.2), dementia (ratio 4.9), osteoporosis (ratio 3.9), type 2 diabetes (ratio 3.8), COPD (ratio 3.3), heart conditions and stroke (ratios ranging from 2.3–3.1). The logistic regression estimates enable readers and health professionals to identify any confounding and residual correlations of the crude estimates for social disparities for their conditions of interests—adjusted not only of gender and age, but also an unprecedented total of all 199 chronic conditions. Findings on socioeconomic differences showed that showed that many of the crude estimate tendencies where also confirmed in the adjusted regression analysis, and that particular people with no educational achievement had the highest OR within disease group F–Mental and behavioural disorders and M—Diseases of the musculoskeletal system and connective tissue. Earlier studies have also shown that schizophrenia is often associated with low educational achievement and high unemployment [88, 89]. Low parental socioeconomic and a family history of mental disorders are in the literature two well establish risk factors of schizophrenia [90, 91]. However, a large Danish study showed that even though parental socioeconomic and a family history of mental disorders contribute to the development of schizophrenia, they made a very limited difference on a person with schizophrenias ability to be employed and get an education [88].
Furthermore, present findings showed an increasing prevalence of people with no educational achievement for every number of chronic diseases they have more than one. People living with multimorbidity have to follow a trajectory for each of the single diseases they suffer from that is a potential driver for a high treatment burden [92]. Additionally, socioeconomic factors such as low educational achievement is associated with high treatment burden [25, 92, 93]. Treatment burden is all the aspects of treatment that a patient experience regarding manage of their disease(s) and the impact this has on the patient’s wellbeing [92, 94]. The increasing number of people living with multimorbidity is an advancing public health problem [24, 94]. This underlines the importance of minimizing the treatment burden for patients with multimorbidity [25]. Especially, because a high treatment burden may lead to involuntary non-adherence, adverse health outcomes and increasing health care cost [92, 93].
Strengths
One major strength of the current study is the size and high quality of the data. A full nationwide register-based recorded dataset for chronic conditions and medical treatments including more than 4.5 million people. The high number of recorded chronic conditions is also a major strength. Moreover, the study is unique in terms of the big data linkage of seven different high-quality registers, combining many chronic conditions with three different socioeconomic measurements. This approach using uniform methodology within a single study has provided comparable socioeconomic data of 199 chronic conditions, and thus the potential to identify treatment potentials, optimising treatments by differentiating and targeting patients accordingly to socioeconomic differences.
Limitations
At least three main limitations exist. First, there are register-based issues of report identification and data misclassification. One fundamental limitation of register studies is not identifying conditions not treated in the healthcare system, self-treatments, as it is not reported within registers, leading to underestimates (see detailed evaluation in previous studies [55, 56, 95]. On the other hand, being treated for a chronic condition is not necessarily the same as being actually or severely ill. There may be instances of defensive medicine, patients being treated on suspicion of a chronic condition, or even over-diagnosis, leading to the identification and overestimates from registers [56]. Moreover, data misclassification is also a source of bias due to different coding practices between hospitals [61], clinical disagreements, dissimilar clinical and administrative practices, and interpretation of the ICD-10 criteria [96]. These issues would naturally affect our estimates of socioeconomic disparities. However, earlier studies have not found evidence of systematic misclassification; reported diagnoses of psychiatric and somatic conditions have been validated with good results [95, 97–102].
Second, high ratios, i.e., large differences in disease prevalence by thousandth between high and low educational achievements for a disease, do not necessarily, although often, comprise conditions that have the overall lowest proportions of people with low educational achievement, as seen in Table 3, S1, S4 Tables in S1 File. As conditions with the lowest educational levels are of interest to healthcare professionals, this poses a challenge. On the other hand, conditions with the lowest proportions of people with no educational achievement might not have a potential for improvement, as there might not be any real differences between high and no educational achievement prevalence (e.g., low ratio). Thus, the ratio was used to measure real-world treatment potential. However, we urge readers to use both the ratio and proportions of educational achievements when identifying and comparing conditions of interest.
Third, practical difficulties in presenting an overview of the results due to the number of socioeconomic measurements and diseases. While the catalogue is easily accessible for a few or single conditions for use in specific treatments, it is difficult to maintain an overview of differences across all the conditions. This might pose an issue for the practical use by decision-makers in prioritising and comparing a larger number of conditions.
Future studies
There is no gold standard for socioeconomic measurements. In this study, we mainly relayed in educational achievements, and future studies should aim to combine educational achievement, income, and job status to get a more accurate socioeconomic measure. This is especially challenging when handling a large chunk of data like this study. Therefore, future studies also need to consider how to handle and compare large chunks of data and conditions.
Conclusions
The present study provides a catalogue of diseases prevalence associated with socioeconomic differences for 199 different clinical-reported chronic conditions and conditions by sex, age, education, income, and socioeconomic position, based on a total nationwide population. To the best of the authors’ knowledge, the study provides the most comprehensive, comparable descriptive register study and catalogue of chronic conditions’ socioeconomic prevalence, characteristics, and differences.
Supporting information
S1 File.
https://doi.org/10.1371/journal.pone.0278380.s001
(DOCX)
Acknowledgments
The authors would like to thank data management specialists Ole Schou Rasmussen and Thomas Mulvad Larsen from The North Denmark Region, Niels Bohrs Vej, 9220 Aalborg, Denmark, for helpful suggestions and assistance in data management with the comprehensive SAS programming of the definitions of the chronic conditions.
Citation: Hvidberg MF, Frølich A, Lundstrøm SL (2022) Catalogue of socioeconomic disparities and characteristics of 199+ chronic conditions—A nationwide register-based population study. PLoS ONE 17(12): e0278380. https://doi.org/10.1371/journal.pone.0278380
About the Authors:
Michael Falk Hvidberg
Roles: Conceptualization, Formal analysis, Investigation, Methodology, Writing – original draft, Writing – review & editing
E-mail: [email protected]
Affiliations: Innovation and Research Centre for Multimorbidity, Slagelse Hospital, Slagelse, Denmark, University of York, York, United Kingdom
ORICD: https://orcid.org/0000-0003-0632-3866
Anne Frølich
Roles: Conceptualization, Formal analysis, Writing – review & editing
Affiliations: Innovation and Research Centre for Multimorbidity, Slagelse Hospital, Slagelse, Denmark, The Research Unit for General Practice and Section of General Practice, Department of Public Health, University of Copenhagen, Copenhagen, Denmark
Sanne Lykke Lundstrøm
Roles: Conceptualization, Formal analysis, Writing – review & editing
Affiliations: Innovation and Research Centre for Multimorbidity, Slagelse Hospital, Slagelse, Denmark, Center for Clinical Research and Prevention, Bispebjerg and Frederiksberg Hospital, Copenhagen, The Capital Region of Denmark
ORICD: https://orcid.org/0000-0001-6284-8478
1. Nordahl H. Social inequality in chronic disease outcomes. Dan Med J 2014; 61: B4943. pmid:25370965
2. Detollenaere J, Desmarest AS, Boeckxstaens P, et al. The link between income inequality and health in Europe, adding strength dimensions of primary care to the equation. Soc Sci Med 2018; 201: 103–110. pmid:29471179
3. Huisman M, Kunst AE, Bopp M, et al. Educational inequalities in cause-specific mortality in middle-aged and older men and women in eight western European populations. Lancet 2005; 365: 493–500. pmid:15705459
4. Mackenbach JP, Stirbu I, Roskam A-JR, et al. Socioeconomic Inequalities in Health in 22 European Countries. N Engl J Med 2008; 358: 2468–2481. pmid:18525043
5. Eikemo TA, Huisman M, Bambra C, et al. Health inequalities according to educational level in different welfare regimes: A comparison of 23 European countries. Sociol Heal Illn 2008; 30: 565–582. pmid:18298629
6. Mackenbach JP. Persistence of social inequalities in modern welfare states: Explanation of a paradox. Scand J Public Health 2017; 45: 113–120. pmid:28212600
7. Mackenbach JP, Bos V, Andersen O, et al. Widening socioeconomic inequalities in mortality in six Western European countries. Int J Epidemiol 2003; 32: 830–837. pmid:14559760
8. Mackenbach JP. The persistence of health inequalities in modern welfare states: The explanation of a paradox. Soc Sci Med 2012; 75: 761–769. pmid:22475407
9. Wilkinson RG. Unhealthy Societies: The Afflictions of Inequality (1st ed.). Routledge. Epub ahead of print 11 September 1996.
10. Kawachi I, Kennedy BP. Income inequality and health: pathways and mechanisms. Health Serv Res 1999; 34: 215–27. pmid:10199670
11. Lynch J. Reframing inequality? The health inequalities turn as a dangerous frame shift. J Public Heal (United Kingdom) 2017; 39: 653–660. pmid:28069990
12. Kondo N, Sembajwe G, Kawachi I, et al. Income inequality, mortality, and self rated health: Meta-analysis of multilevel studies. BMJ 2009; 339: 1178–1181. pmid:19903981
13. De Vogli R, Mistry R, Gnesolto R, et al. Has the relation between income inequality and life expectancy disappeared? Evidence from Italy and top industrialised countries. J Epidemiol Community Health 2005; 59: 158–162. pmid:15650149
14. Offer A, Pechey R, Ulijaszek S (eds). Insecurity, Inequality, and Obesity in Affluent Societies. Oxford University Press, https://econpapers.repec.org/RePEc:oxp:obooks:9780197264980 (2012).
15. United Nations. Transforming our world: The 2030 agenda for sustainable development. New York. Epub ahead of print 2015.
16. Rowlingson K. Does income inequality cause health and social problems? Joseph Rowntree Found 2011; 51.
17. Hales S, Howden-Chapman P, Salmond C, et al. National infant mortality rates in relation to gross national product and distribution of income. Lancet 1999; 354: 2047. pmid:10636372
18. Drain PK, Smith JS, Hughes JP, et al. Correlates of National HIV Seroprevalence: An Ecologic Analysis of 122 Developing Countries. J Acquir Immune Defic Syndr 2004; 35: 407–420. pmid:15097158
19. Subramanian SV., Kawachi I. Income inequality and health: What have we learned so far? Epidemiol Rev 2004; 26: 78–91. pmid:15234949
20. Wilkinson RG, Pickett KE. Income inequality and population health: A review and explanation of the evidence. Soc Sci Med 2006; 62: 1768–1784. pmid:16226363
21. Pickett KE, Kelly S, Brunner E, et al. Wider income gaps, wider waistbands? An ecological study of obesity and income inequality. J Epidemiol Community Health 2005; 59: 670–674. pmid:16020644
22. Ram R. Further examination of the cross-country association between income inequality and population health. Soc Sci Med 2006; 62: 779–791. pmid:16051408
23. Babones SJ. Income inequality and population health: Correlation and causality. Soc Sci Med 2008; 66: 1614–1626. pmid:18222588
24. Schiøtz ML, Stockmarr A, Høst D, et al. Social disparities in the prevalence of multimorbidity—A register-based population study. BMC Public Health 2017; 17: 1–11.
25. Hvidberg MF, Frølich A, Lundstrøm SL, et al. Catalogue of multimorbidity mean based severity and associational prevalence rates between 199+ chronic conditions—A nationwide register-based population study. PLoS One 2022; 17: e0273850. pmid:36103504
26. Organisation for Economic Cooperation and Development. In it Together: Why Less Inequality Benefits All. Paris: OECD Publishing, 2015. Epub ahead of print 2015.
27. Stiglitz JE, Fitoussi J-P, Bofinger P, et al. A Call for Policy Change in Europe. OECD Publishing, 2014. Epub ahead of print 2014.
28. Islam N, Lacey B, Shabnam S, et al. Social inequality and the syndemic of chronic disease and COVID-19: County-level analysis in the USA. J Epidemiol Community Health 2021; 75: 496–500. pmid:33402397
29. Skou ST, Mair FS, Fortin M, et al. Multimorbidity. Nat Rev Dis Prim; 8. Epub ahead of print 2022. pmid:35835758
30. Barnett K, Mercer S, Norbury M, et al. Epidemiology of multimorbidity and implications for health care, research, and medical education: a cross-sectional study. Lancet 2012; 380: 37–43. pmid:22579043
31. Naghavi M, Wang H, Lozano R, et al. Global, regional, and national age–sex specific all-cause and cause-specific mortality for 240 causes of death, 1990–2013: a systematic analysis for the Global Burden of Disease Study 2013. Lancet 2015; 385: 117–171. pmid:25530442
32. Murray CJL, Ezzati M, Flaxman A. Supplementary appendix—comprehensive systematic analysis of global epidemiology: definitions, methods, simplification of DALYs, and comparative results from the Global Burden of Disease Study 2010. Lancet 2012; 380: 2063–66.
33. Murray CJ, Ezzati M, Flaxman AD, et al. GBD 2010: design, definitions, and metrics. Lancet 2012; 380: 2063–2066. pmid:23245602
34. Vos T, Barber RM, Bell B, et al. Global, regional, and national incidence, prevalence, and years lived with disability for 301 acute and chronic diseases and injuries in 188 countries, 1990–2013: a systematic analysis for the Global Burden of Disease Study 2013. Lancet 2015; 386: 743–800. pmid:26063472
35. World Health Organization (WHO). World Health Statistics 2015. World H 2015; 164.
36. World Health Organization (WHO). Global status report on noncommunicable diseases 2014. World Health. Epub ahead of print 2014. ISBN 9789241564854.
37. World Health Organization (WHO). Global status report on noncommunicable diseases 2010. World Health. Epub ahead of print 2010. ISBN 978 92 4 156422 9.
38. Murray CJL, Barber RM, Foreman KJ, et al. Global, regional, and national disability-adjusted life years (DALYs) for 306 diseases and injuries and healthy life expectancy (HALE) for 188 countries, 1990–2013: quantifying the epidemiological transition. Lancet 2015; 386: 2145–2191. pmid:26321261
39. Murray CJL, Vos T, Lozano R, et al. Disability-adjusted life years (DALYs) for 291 diseases and injuries in 21 regions, 1990–2010: a systematic analysis for the Global Burden of Disease Study 2010. Lancet 2012; 380: 2197–2223. pmid:23245608
40. Murray CJL, Lopez AD. The global burden of disease: a comprehensive assessment of mortality and disability from deceases, injuries and risk factors in 1990 and projected to 2010. World Health Organization. Epub ahead of print 1996.
41. Schiller JS, Lucas JW, Ward BW, et al. Summary health statistics for U.S. adults: National Health Interview Survey, 2011. Vital Heal Stat 2012; 10: 1–207. pmid:25116400
42. Garrett N, Martini EM. The boomers are coming: A total cost of care model of the impact of population aging on the cost of chronic conditions in the United States. Dis Manag 2007; 10: 51–60. pmid:17444790
43. Sundhedsstyrelsen [Danish National Board of Health]. Kronisk sygdom: patient, sundhedsvæsen og samfund [Chronic conditions: patient, health care and society]. National Boards of Health, https://sundhedsstyrelsen.dk/~/media/B687391740314F2DBC0B5690D53A7031.ashx (2005, accessed 18 June 2022).
44. Esteban-Vasallo M, Dominguez-Berjon M, Astray-Mochales J, et al. Epidemiological usefulness of population-based electronic clinical records in primary care: estimation of the prevalence of chronic diseases. Fam Pract 2009; 26: 445–454. pmid:19815673
45. Frølich A, Ghith N, Schiøtz M, et al. Multimorbidity, healthcare utilization and socioeconomic status: A register-based study in Denmark. PLoS One 2019; 14: e0214183. pmid:31369580
46. Makady A, ten Ham R, de Boer A, et al. Policies for Use of Real-World Data in Health Technology Assessment (HTA): A Comparative Study of Six HTA Agencies. Value Heal 2017; 20: 520–532. pmid:28407993
47. Garrison LP, Neumann PJ, Erickson P, et al. Using real-world data for coverage and payment decisions: The ISPOR real-world data Task Force report. Value Heal 2007; 10: 326–335. pmid:17888097
48. Mauskopf J, Earnshaw SR, Brogan A, Wolowacz S BT. Budget-impact analysis of health care interventions. Manchester: Adis, 2017.
49. Angelis A, Tordrup D, Kanavos P. Socio-economic burden of rare diseases: A systematic review of cost of illness evidence. Health Policy (New York) 2015; 119: 964–979. pmid:25661982
50. Plaß D. The Burden of Disease framework–success story but necessities for adaptations: potentials and challenges when measuring the disease burden of infectious diseases and the disease burden at a sub-national level [PhD dissertation]. Bielefeld: Universität Bielefeld. Epub ahead of print 2014. urn:nbn:de:hbz:361–26947850.
51. Polinder S, Haagsma JA, Stein C, et al. Systematic review of general burden of disease studies using disability-adjusted life years. Popul Health Metr 2012; 10: 21. pmid:23113929
52. Nord E. Disability weights in the Global Burden of Disease 2010: unclear meaning and overstatement of international agreement. Health Policy (New York) 2013; 111: 99–104. pmid:23608637
53. Nord E. Uncertainties about disability weights for the Global Burden of Disease study. Lancet Glob Heal 2015; 3: e661–e662. pmid:26475004
54. Hvidberg MF. A framework for identifying disease burden and estimating health-related quality of life and prevalence rates for 199 medically defined conditions. 1st ed. Aalborg University Press. Epub ahead of print 2016.
55. Hvidberg MF, Johnsen SP, Glümer C, et al. Catalog of 199 register-based definitions of chronic conditions. Scand J Public Health 2016; 44: 462–479. pmid:27098981
56. Hvidberg MF, Johnsen SP, Davidsen M, et al. A Nationwide Study of Prevalence Rates and Characteristics of 199 Chronic Conditions in Denmark. PharmacoEconomics—Open. Epub ahead of print 24 July 2019. pmid:31342402
57. Hvidberg MF, Johnsen SP, Davidsen M, et al. Supplementary material: A nationwide study of prevalence rates and characteristics of 199 chronic conditions in Denmark. PharmacoEconomics—Open. Epub ahead of print 2019. pmid:31342402
58. Hvidberg MF, Johnsen SP, Glumer C, et al. Supplementary material: process, content and considerations of the medical review and ratification regarding register-based definitions of chronic conditions (to ‘Catalog of 199 register-based definitions of chronic conditions’). Scand J Public Health 2016; 44: 462–479.
59. Klinisk Epidemiologisk Afdeling [Department of Clinical Epidemiology]. Sygehuskontakter og lægemiddelforbrug for udvalgte kroniske sygdomme i Region Nordjylland [Hospital contacts and drug consumption for selected chronic diseases in North Jutland]. Department of Clinical Epidemiology, https://kea.au.dk/fileadmin/KEA/filer/Other_reports/34_Kroniske_sygdomme_og_laegemiddelforbrug_RN.pdf (2007).
60. Robinson KM, Juel Lau C, Jeppesen M, et al. Kroniske sygdomme—forekomst af kroniske sygdomme og forbrug af sundhedsydelser i Region Hovedstaden v2.0 [Chronic diseases—prevalence of chronic diseases and use of health services in the Capital Region v2.0]. Glostrup, Denmark, https://research.regionh.dk/bispebjerg/files/55781657/Kroniske_sygdomme_forekomst_af_kroniske_sygdomme_og_forbrug_af_sundhedsydelser_i_Region_Hovedstaden.pdf (March 2012).
61. Sundhedsstyrelsen [Danish National Board of Health]. Beskrivelse af Sundhedsstyrelsens monitorering af kronisk sygdom [Description of National Board of Health’s monitoring of chronic disease]. National Board of Health, www.sst.dk (2012).
62. Statens Serum Institute. Monitorering af kronisk sygdom hos Statens Serum Institut [Monitoring of chronic disease at Statens Serum Institute]. Statens Serum Institute, www.ssi.dk (2012).
63. Wiréhn A-BE, Karlsson HM, Carstensen JM. Estimating disease prevalence using a population-based administrative healthcare database. Scand J Public Health 2007; 35: 424–431. pmid:17786807
64. Hommel K, Rasmussen S, Madsen M, et al. The Danish Registry on Regular Dialysis and Transplantation:completeness and validity of incident patient registration. Nephrol Dial Transplant 2010; 25: 947–951. pmid:19861312
65. Carstensen B, Kristensen JK, Marcussen MM, et al. The National Diabetes Register. Scand J Public Health 2011; 39: 58–61. pmid:21775353
66. [email protected]. Nordic PharmacoEpidemiological Network (NorPEN), http://www.norpen.org/pages/publications.html (accessed 16 April 2019).
67. Pampel FC, Krueger PM, Denney JT. Socioeconomic disparities in health behaviors. Annu Rev Sociol 2010; 36: 349–370. pmid:21909182
68. Meillier L. I gang igen efter blodprop i hjertet—socialt differentieret hjerterehabilitering [Getting started again after a blood clot in the heart—socially differentiated cardiac rehabilitation]. Aarhus & Copenhagen: Center for Folkesundhed, Region Midtjylland, i samarbejde med Hjerteforeningen, https://hjerteforeningen.dk/wp-content/uploads/2016/11/i-gang-igen-efter-blodprop-i-hjertet.pdf (2007).
69. Ingholt, L., Rod, M. H., Holmberg, T., Srivarathan, A., Rossau, H. K., & Tjørnhøj-Thomsen T. Socialdifferentieret hjerterehabilitering i praksis: Sundhedsprofessionelles og patienters perspektiver [Socially differentiated cardiac rehabilitation in practice: Perspectives from health professionals and patients]. Copenhagen: Syddansk Universitet. Statens Institut for Folkesundhed., https://findresearcher.sdu.dk:8443/ws/portalfiles/portal/124605011/Rosseau_et_al_2016_socialdifferentieret_hjerterehabilitering_i_praksis.pdf (2016).
70. Meillier LK, Larsen FB, Nielsen KM, et al. Socially differentiated cardiac rehabilitation: Can we improve referral, attendance and adherence among patients with first myocardial infarction? Scand J Public Health 2012; 40: 286–293. pmid:22637368
71. Pedersen M, Overgaard D, Andersen I, et al. Mechanisms and drivers of social inequality in phase II cardiac rehabilitation attendance: A convergent mixed methods study. J Adv Nurs 2018; 74: 2181–2195. pmid:29772607
72. Andersen MB, Bjørkman ASD, Pedersen M, et al. Social inequality in lifestyle, motivation to change lifestyle and received health advice in individuals with diabetes: A nationwide study. Scand J Public Health 2020; 48: 847–854. pmid:31808737
73. Olsen J, Basso O, Sørensen HT. What is a population-based registry? Scand J Public Health 1999; 27: 78. pmid:10847676
74. Jensen VM, Rasmussen AW. Danish education registers. Scand J Public Health 2011; 39: 91–94. pmid:21775362
75. Baadsgaard M, Quitzau J. Danish registers on personal income and transfer payments. Scand J Public Health 2011; 39: 103–105. pmid:21775365
76. Lynge E, Sandegaard JL, Rebolj M. The Danish National Patient Register. Scand J Public Health 2011; 39: 30–33. pmid:21775347
77. Mors O, Perto GP, Mortensen PB. The Danish Psychiatric Central Research Register. Scand J Public Health 2011; 39: 54–57. pmid:21775352
78. Sahl Andersen J, De Fine Olivarius N, Krasnik A. The Danish National Health Service Register. Scand J Public Health 2011; 39: 34–37. pmid:21775348
79. Wallach Kildemoes H, Toft Sorensen H, Hallas J. The Danish National Prescription Registry. Scand J Public Health 2011; 39: 38–41. pmid:21775349
80. Pedersen CB, Gøtzsche H, Møller JO, et al. The Danish Civil Registration System. A cohort of eight million persons. Dan Med Bull 2006; 53: 441–449. pmid:17150149
81. Kamper-Jørgensen F. New editor and new publisher for the Scandinavian Journal of Public Health. Scand J Public Health 2008; 36: 1–2.
82. Paez KA, Zhao L, Hwang W. Rising out-of-pocket spending for chronic conditions: a ten-year trend. Health Aff 2009; 28: 15–25. pmid:19124848
83. Sullivan PW, Ghushchyan V. Preference-based EQ-5D index scores for chronic conditions in the United States. Med Decis Mak 2006; 26: 410–420. pmid:16855129
84. Sullivan PW, Slejko JF, Sculpher MJ, et al. Catalogue of EQ-5D scores for the United Kingdom. Med Decis Mak 2011; 31: 800–804. pmid:21422468
85. National Center for Health Statistics. National Center for Health Statistics: Age Standardization and Population Estimates. Prevention, Centers for Disease Control and 2020; 1–31.
86. Naing NN. Easy way to learn standardization: direct and indirect methods. Malays J Med Sci 2000; 7: 10–5. pmid:22844209
87. Christensen AI, Ekholm O, Glumer C, et al. The Danish National Health Survey 2010. Study design and respondent characteristics. Scand J Public Health 2012; 40: 391–397. pmid:22786925
88. Hakulinen C, McGrath JJ, Timmerman A, et al. The association between early-onset schizophrenia with employment, income, education, and cohabitation status: nationwide study with 35 years of follow-up. Soc Psychiatry Psychiatr Epidemiol 2019; 54: 1343–1351.
89. Evensen S, Wisløff T, Lystad JU, et al. Prevalence, employment rate, and cost of schizophrenia in a high-income welfare society: A population-based study using comprehensive health and welfare registers. Schizophr Bull 2016; 42: 476–483. pmid:26433216
90. Dean K, Stevens H, Mortensen PB, et al. Full spectrum of psychiatric outcomes among offspring with parental history of mental disorder. Arch Gen Psychiatry 2010; 67: 822–829. pmid:20679590
91. Mors O, Meier S, Sullivan PF, et al. Polygenic Risk Score, Parental Socioeconomic Status, Family History of Psychiatric Disorders, and the Risk for Schizophrenia. JAMA Psychiatry 2015; 72: 635.
92. Morris JE, Roderick PJ, Harris S, et al. Treatment burden for patients with multimorbidity: Cross-sectional study with exploration of a single-item measure. Br J Gen Pract 2021; 71: E381–E390. pmid:33875419
93. Herzig L, Zeller A, Pasquier J, et al. Factors associated with patients’ and GPs’ assessment of the burden of treatment in multimorbid patients: A cross-sectional study in primary care. BMC Fam Pract 2019; 20: 1–11.
94. Friis K, Lasgaard M, Pedersen MH, et al. Health literacy, multimorbidity, and patient-perceived treatment burden in individuals with cardiovascular disease. A Danish population-based study. Patient Educ Couns 2019; 102: 1932–1938. pmid:31151781
95. Pedersen CB, Mors O, Bertelsen A, et al. A comprehensive nationwide study of the incidence rate and lifetime risk for treated mental disorders. JAMA Psychiatry 2014; 71: 573. pmid:24806211
96. Falk Hvidberg M, Brinth LS, Olesen AV., et al. The health-related quality of life for patients with myalgic encephalomyelitis / chronic fatigue syndrome (ME/CFS). PLoS One; 10. Epub ahead of print 6 July 2015. pmid:26147503
97. Kessing L. Validity of diagnoses and other clinical register data in patients with affective disorder. Eur Psychiatry 1998; 13: 392–398. pmid:19698654
98. Pedersen M, Klarlund M, Jacobsen S, et al. Validity of rheumatoid arthritis diagnoses in the Danish National Patient Registry. Eur J Epidemiol 2004; 19: 1097–1103. pmid:15678789
99. Phung TKT, Andersen BB, Hoegh P, et al. Validity of dementia diagnoses in the Danish hospital registers. Dement Geriatr Cogn Disord 2007; 24: 220–228. pmid:17690555
100. Bock C, Bukh J, Vinberg M, et al. Validity of the diagnosis of a single depressive episode in a case register. Clin Pract Epidemiol Ment Heal 2009; 5: 4.
101. Uggerby P, Østergaard SD, Røge R, et al. The validity of the schizophrenia diagnosis in the Danish Psychiatric Central Research Register is good. Dan Med J 2013; 60: A4578. pmid:23461991
102. Thygesen SK, Christiansen CF, Christensen S, et al. The predictive value of ICD-10 diagnostic coding used to assess Charlson comorbidity index conditions in the population-based Danish National Registry of Patients. BMC Med Res Methodol 2011; 11: 83. pmid:21619668
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
© 2022 Hvidberg et al. This is an open access article distributed under the terms of the Creative Commons Attribution License: http://creativecommons.org/licenses/by/4.0/ (the “License”), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.
Abstract
Background
Real-world information on socioeconomic differences within and between chronic conditions represents an important data source for treatments and decision-makers executing and prioritising healthcare resources.
Aims
The aim of this study was to estimate the prevalence and mean of socioeconomic disparities from educational, income, and socioeconomic positions of 199 chronic conditions and disease groups, including sex and age group estimates, for use in planning of care services and prioritisation, by healthcare professionals, decision-makers and researchers.
Methods
The study population includes all Danish residents 16 years and above, alive on 1 January 2013 (n = 4,555,439). The data was established by linking seven national registers encompassing educational achievements, incomes, socioeconomic positions, hospital- and general practice services, and filled-in out-of-hospital prescriptions. The health register data were used to identify the 199+ chronic conditions. Socioeconomic differences were primarily measured as differences in educational prevalence levels from low to high educational achievements using a ratio. Furthermore, multiple binary logistic regression models were carried out to control for potential confounding and residual correlations of the crude estimates.
Results
The prevalence of having one or more chronic conditions for patients with no educational achievement was 768 per thousand compared to 601.3 for patients with higher educational achievement (ratio 1.3). Across disease groups, the highest educational differences were found within disease group F–mental and behavioural (ratio 2.5), E–endocrine, nutritional and metabolic disease (ratio 2.4), I–diseases of the circulatory system (ratio 2.1) and, K–diseases of the digestive system (ratio 2.1). The highest educational differences among the 29 common diseases were found among schizophrenia (ratio 5.9), hyperkinetic disorders (ratio 5.2), dementia (ratio 4.9), osteoporosis (ratio 3.9), type 2 diabetes (ratio 3.8), chronic obstructive pulmonary disease COPD (ratio 3.3), heart conditions and stroke (ratios ranging from 2.3–3.1).
Conclusions
A nationwide catalogue of socioeconomic disparities for 199+ chronic conditions and disease groups is catalogued and provided. The catalogue findings underline a large scope of socioeconomic disparities that exist across most chronic conditions. The data offer essential information on the socioeconomic disparities to inform future socially differentiated treatments, healthcare planning, etiological, economic, and other research areas.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer
Details
; Frølich, Anne; Lundstrøm, Sanne Lykke