Study objective: To demonstrate how Care Need Index (CNI), a social deprivation index, may be used to allocate total primary health care resources.
Design: Cross sectional survey and register data. The CNI was based on sociodemographic factors: elderly persons living alone, children under age 5, unemployed people, people with low educational status, single parents, high mobility, and foreign born people. The CNI weights were calculated from the ratings of Swedish GPs of the impact of these factors on their workload. The CNI scale was transformed into a positive scale to avoid negative values. CNI weights were calculated for each decile of the study population. The risk of poor self reported health in the CNI deciles was estimated by means of a hierarchical logistic regression in the age range 25–74 (n=27 346). The MigMed database comprising all people living in Sweden was used to calculate the CNI for Stockholm.
Participants: The Swedish population and the population in Stockholm County.
Main results: The means of the CNI for deciles ranged from 61 (most affluent neighbourhoods) to 140 (most deprived) in Stockholm County. The ratio between the tenth and the first decile was 1.66. There was an approximately 150% increased risk of poor self reported health for people living in the most disadvantaged neighbourhoods (OR=2.50) compared with those living in the most affluent ones (OR=1). CNI ratios for the deciles corresponded approximately to the odds ratios of poor self reported health status.
Conclusions: The CNI can be used to allocate total primary health care resources.
- Care Need Index
- self reported health
- primary health care
- CNI, Care Need Index
- SALLS, Swedish Annual Level of Living Survey
- SAMS, small area market statistics
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The purpose of this study is to show how a modified Jarman score, such as the Care Need Index (CNI),1 can be used as a direct empirical measure for the distribution of primary health care resources. Existing indices such as the Jarman score2 allocate an additional fee, above a certain cut off, to general practitioners (GPs) who have their practices in the 5% most deprived neighbourhoods. However, the presence of negative values in the scores makes it difficult to use them for a total distribution of resources. This study shows how such an index can be transformed into a more useful scale in order to allocate total resources to primary health care.
The CNI was originally developed for the purpose of measuring the potential workload of GPs in Swedish primary health care using indicators for material deprivation (unskilled, unemployed, and living in crowded households) and adding demographic factors related to family structures (elderly persons living alone, children under age 5, and single parent families), social instability (people who had moved house during the past year), and cultural needs (ethnicity) weighted by Swedish GPs.1
Scandinavian studies showed an ecological association between deprived neighbourhoods measured by CNI and indicators of poor health, such as increased admissions to psychiatric departments,3–5 a greater number of emergency room visits,6,7 high CHD mortality,8 and higher consultation rates for primary health care.9
In Stockholm County, which represents one fifth of the Swedish population, a population based resource allocation model based on consumption and need is used to distribute funds for purchasing health care services from providers of primary health care.10 In this paper we propose a new model, based on measures of material and social need for medical service summed up to form an index, for the distribution of primary health care resources.
The first aim of this study is to transform the CNI into a positive scale for allocating primary health care resources totally, not only to the most deprived areas. The second aim is to compare the means of the CNI (CNI weights) categorised into deciles, from the most affluent neighbourhoods (1st decile) to the most deprived ones (10th decile), with the risk of poor self reported health status in every decile. The third aim is to exemplify how primary health care resources in Stockholm County (1.7 million inhabitants) can be allocated by the transformed CNI, compared with the official consumption model.
Data sources 1: A sample of the Swedish population
The aim was to analyse the relation between the transformed CNI and poor self reported health in deciles of a sample of the Swedish population. The sample consists of individual data, comprising face to face interviews, from the Swedish Annual Level of Living Survey (SALLS), matched with the social position of the area (small area market statistics, SAMS) in which the respondents live, the latter being measured by CNI.1 This study is based on pooled data from 1992–9711 for the age range 25–74 and consists of 27 346 interviews. The CNI scores could not be matched with SAMS data for 1294 persons, representing about 4.7% of all participants. The ethics committee at Huddinge University Hospital, Stockholm, has approved this study.
The non-response rate for SALLS was about 20%. Refusal was the predominant reason for not responding (more than two thirds of the non-responses consisted of refusals). One fifth of all non-respondents were not found, and one tenth were ill. Mortality as a measure of ill health among both respondents and non-respondents was analysed in a proportional hazard model adjusted for sex, age, marital status, and geographical area, using the data supplied by the SALLS samples. It was found that those who refused to participate had the same mortality rate as the respondents, while the other two groups (that is, those who could not be found and those who were ill) had significantly higher mortality.
Poor self reported health status is based on the question: “How would you describe your general health?” There were three response alternatives: good, bad, or anywhere between good and bad. Those who answered that their health status was bad or anywhere between good and bad were counted as having a poor self reported health status.
Age (continuous) and sex
CNI calculated for SAMS
SAMS refers to neighbourhoods with an average population of about 2000 for Stockholm, and about 1000 for the rest of Sweden (total, 9667). The boundaries of SAMS neighbourhoods are drawn to include similar types of housing construction.
Data sources 2: MigMed databases
To calculate the CNI for all people living in Stockholm County, we used the MigMed database at the Karolinska Institutet, Sweden. The database includes the whole Swedish population. In this study 1.7 million people, the total population of Stockholm County, were used for the analysis. The database contains data on sociodemographic factors, including age, gender, socioeconomic status (SES) (education, income), country of birth, and area (9677 neighbourhoods, boundaries defined by housing structure for administrative and commercial purposes). MigMed is linked to several other databases: Louise: A register including the entire population. The database contains annual specifications of: income, education, place of residence (geographical coordinates). The Immigration Register contains data on country of birth. The Total Population Register (TPR) comprises all people who have a residence permit. People who stay more than six months in Sweden will have a permit and are included in the TPR. It includes data on mobility from one neighbourhood to another, out migration and any instances of return to Sweden. The undercoverage and overcoverage is very low.
CNI: calculation and transformation of CNI into a positive scale
Neighbourhood social position, measured by the CNI, was calculated for all SAMS neighbourhoods except those with less than 50 inhabitants (in total 943), which were excluded because of the instability of the estimated proportions.
The CNI included proportions of seven material, sociodemographic, and cultural variables from Swedish public registers for each SAMS area: elderly people living alone, children under age 5, unemployed people, people with low educational status, single parents, residents who have moved house during the past year, and foreign born people from Southern and Eastern Europe, Asia, Africa, and South America (table 1).
In the autumn of 2000, all 3922 Swedish GPs received a questionnaire that 2541 answered (response rate 64.8%), rating the impact of these factors on their workload. The CNI was based on these weights. The proportions of the variables were normalised by applying an angular transformation. The means and standard deviations of the proportions were calculated for Sweden as a whole. For each area, all seven proportions were standardised by calculating Z scores.1 The standardised value of each variable was multiplied by the corresponding new weights based on the survey of the Swedish GPs. The mean value of CNI for the whole of Sweden was 0 with SD=16.7. The higher the index value, the more deprived was the neighbourhood. The CNI scores for Sweden ranged from −54 (most affluent neighbourhood) to 78 (most deprived neighbourhood) (table 1). The CNI scale for Sweden was transformed into a positive scale (mean=100; SD=15) to avoid negative values according to the formula:
Yj is the individual j value in the transformed distribution,
Sy is the standard deviation in the transformed distribution (16.7),
My is the mean value in the transformed distribution (100),
Xj is the individual j value in the original distribution,
Sx is the standard deviation in the original distribution (15),
Mx is the mean value in the original distribution (0).
Allocation of resources by CNI: The Stockholm County example
The CNI was used to measure the social position of the area. In our MigMed database, each person in Stockholm County has an area social position measured by the CNI according to their area of living. The whole population of Stockholm County was divided into deciles according to each peson’s area social position with CNI values ranging from 61 in the most affluent decile to 140 in the most deprived decile. Each decile comprised approximately 170 000 people. In the next step, the means of the transformed CNI for Stockholm County were calculated for each decile. These means were used as CNI weights. These CNI weights for each decile of the population of Stockholm County were used in the calculation of new CNI weights for six administrative areas in Stockholm County.
Stockholm County is divided into six independent administrative areas: north east (NE), north west (NW), northern Stockholm (NS), southern Stockholm (SS), south west (SW), and south east (SE).
For the respective administrative area the following calculation was made:
the CNI weights were multiplied by the size of the population (N) of each of the CNI deciles so that 10 values (CNI weights × N) were obtained.
These 10 values were summarised into one sum [Σdecile 1-decile 10 (CNI weights x N)].
The CNI weights for each decile were summarised into one sum [Σdecile 1-decile 10 (CNI weights)].
These two sums were divided, so that the sum [Σdecile 1-decile 10 (CNI weights × N)] was divided by the sum [Σdecile 1-decile 10 (CNI weights)]. The value thus obtained is called the final CNI weight and was calculated in the same way for each administrative area.
The sum of the six final CNI weights was calculated [Σarea 1-area 6 (final CNI weights)].
The allocation of resources to each administrative area in percentage is obtained by dividing the final CNI weight for each administrative area by the sum of the final CNI weights (Σarea 1-area 6 (final CNI weights) for all administrative areas (multiplied by 100). The proposed CNI model was compared with the official model used in Stockholm County.
The prevalence of poor self reported health status was standardised by sex and age (indirect standardisation).12 Hierarchical logistic regression was used in the analysis of data and the models were fitted using the SAS macro GLIMMIX.13,14 A restricted maximum likelihood procedure was used in the method of estimation. The inclusion of a macro error term mixed the model with the CNI as a random effect. The interactions between fixed effect factors and the CNI were treated as random effects. No such interactions were found. The results were exhibited as odds ratios (OR) with 95% confidence intervals (CI). The fit of the model was inferred from an extra-dispersion parameter, which met this demand.
The reliability of the items included in SALLS was analysed by means of re-interviewing (test-retest method), giving χ coefficients between 0.7 and 0.9.15
Poor self reported health in CNI deciles in a random sample of the Swedish population
Table 2 shows the odds ratio (OR) with the 95% confidence intervals (CI) and the prevalence of poor self reported health status in different CNI deciles in a hierarchical logistic model adjusted for sex and age (25–74 years). Each transformed CNI decile includes about 2600 people representing a population of about 500 000.
The prevalence of poor self reported health increased significantly with every CNI decile compared with the reference level (decile 1) with the exception of decile 2, indicating an increasing prevalence of poor self reported health from 18% in the first most affluent decile to 33.8% in the tenth most deprived decile by increasing social deprivation. The prevalence of poor self reported health was about equal (22.8 to 24.9%) in deciles 4–7.
There was a significant strong association between the transformed CNI and poor self reported health (table 2). There was a clear gradient, an approximately 150% increased risk of poor self reported health status for people living in the most deprived neighbourhoods (OR=2.50) compared with those living in the most affluent neighbourhoods (OR=1). The OR of poor self reported health status was about 1.5 in deciles 4 to 7, representing 2 million of the Swedish population. Respondents living in neighbourhoods with addresses that could not be matched with SAMS areas had an increased risk of poor self reported health status with OR=1.51 (95% CI; 1.25 to 1.81).
CNI weights in corresponding deciles in Stockholm County
Table 3 shows the mean CNI weights and CNI ratios in deciles for Sweden (n=8.5 million inhabitants) and Stockholm County (n=1.7 million inhabitants). The ratio between the tenth and the first decile was 1.70 for Sweden and 1.66 for Stockholm—that is, the CNI ratios were almost identical.
Comparison between CNI deciles in Stockholm County and poor self reported health
There was a strong association (hierarchical logistic regression) between the transformed CNI and poor self reported health in table 2, based on a random sample (n=27 346) of the total population of Sweden. In table 3 it was shown that the CNI ratios increased with increasing CNI deciles (increasing deprivation) based both on the population of Sweden and the population of Stockholm County. As they were very similar, it is concluded that the strong association between the transformed CNI and poor self reported health obtained in a random sample of the Swedish population also exists in Stockholm County.
Application of CNI as an allocation resource index in Stockholm County
The population of Stockholm County with the number and percentage of persons by administrative area and CNI decile is presented in table 4, which shows that the demographic structure differs in the administrative areas.
In table 5, the transformed CNI model was compared with the official consumption and need model currently used for the allocation of economic resources (percentages) to the primary health care services in Stockholm County. To evaluate the neighbourhood social position, information about the area CNI, the proportion of immigrants, people with low educational status, low income, elderly people living alone, single parents, unemployed people, high mobility and children under age 5 is shown in table 5. CNI means for the six different areas have been calculated and show that some of the areas can be regarded as being more deprived. None of the most deprived neighbourhoods (decile 10) were found in the affluent north eastern (NE) part of Stockholm. The largest differences in allocation of resources when the CNI model was used were seen in the SS and SW areas. The SS area, which was as deprived as the SW area according to CNI, received 1.7 % less resources with the CNI model than with the official model and the SW area received 1.2% more resources when the CNI model was used. The difference 21.4% compared with 20.2% seems slight, but as the total annual budget for primary health care in Stockholm is 3.3 billion kronor, these additional resources would result in more than 50 new GPs for the deprived SW area. However, the SS area loses the same amount of economic resources. Therefore, even small differences in the allocation of resources, if calculated in percentages, are of great importance and represent considerable amounts of money. There were not so large changes in the allocation of resources in the NS and SE areas, −0.8% and +0.7%, respectively. In the other two areas (NE and NW) in the northern part of Stockholm, there were only minor changes when the CNI model was used.
Care Need Index might be used as a direct empirical measure for a total distribution of resources to primary health care.
CNI ratios corresponded to ORs for poor self reported health when the population in Stockholm County was divided into deciles.
The CNI model, which is based on measures of material and social need, constitutes a better theoretical basis for the distribution of primary health care resources than the consumption of primary health care in previous years.
One of the main findings of this study was that CNI, after the transformation to a positive scale, might be used as a direct empirical measure for a total distribution of resources to primary health care. Moreover, the transformed CNI ratios corresponded to ORs for poor self reported health when the population in Stockholm County was divided into deciles. In this study, we have developed a need based model for the distribution of primary health care resources, an alternative to the official consumption model. The CNI model reallocated resources to a large extent, compared with the official consumption model, in the two most deprived administrative areas, the SS and the SW area. The SW area, with a 40% larger population than the SS area, received more resources while the SS area received less. Although it is not possible to conclude which model is the best for allocating resources to primary health care, the CNI model has a better theoretical approach—that is, measures of social need, rather than actual consumption. It may be possible that the consumption model reflects the actual access to health care so that an area with a high access to primary health care has a higher consumption of medical services. Therefore, we argue that the consumption model preserves established behaviour instead of measuring people’s need for medical services.
An important concern is the significance and interpretation of the outcome factor. For example, qualms about the significance of self rated health status have been suggested by an Australian study that found unexpected gender differences in health status.16 In contrast, a Finnish longitudinal survey demonstrated the stability over time of self reported health status and that such a subjective health assessment was a valid indicator of health in middle aged populations.17 According to a study from Quebec, self reported health is the best indicator of population morbidity at the primary care level “since it tends to reflect individuals’ perceptions of their health in the context of their expectations for their health”.18 Self reported health status is widely used in European19–21 and in American 22–25 studies as a useful predictor of the health conditions of a population, but it is possibly a subjective and imprecise measure of health, which reflects a person’s general perception of the quality of life. However, the test-retest reliability of self rated health status was good when performed in another population from SALLS 1989.26
The finding that the CNI ratios and the odds ratios of poor self reported health showed a clear gradient, increasing with each decile with increasing deprivation, agreed with studies from the UK in particular. For example, people living in deprived neighbourhoods in London had an increased risk of poor self reported health,27 a finding in agreement with the present study. Moreover, the primary health care consultation rates were higher in the deprived neighbourhoods than in the affluent neighbourhoods.27 Thus, high rates of poor self reported health in deprived areas may be interpreted as a high need for primary health care. In another study from the UK, the authors showed that socioeconomic and demographic factors such as unemployment, living in a rented accommodation, and being from the Indian subcontinent were associated with more frequent consultations with GPs, even after adjustment for individual social position.28 In contrast, a British study using the Jarman score or the Townsend score did not reveal any association between these scores and poor self reported health.29
There is also an association between deprivation and other health outcomes. For example, people living in the deprived neighbourhoods in Sweden, as measured by the CNI, have higher rates of psychiatric hospital admissions, alcohol clinic admissions, cardiovascular risk factors (smoking, no physical activity, obesity), all cause mortality and coronary heart disease mortality.5,8,30 The pressure on primary health care centres located in such areas is therefore considerable.7,27 Although a causal association between social deprivation and health is difficult to prove, surveys in the UK and Sweden revealed that many GPs regarded socioeconomic factors such as a high proportion of unemployment, elderly people living alone, and single mothers as having a direct effect on their workload.1,31
The CNI is based exclusively on the need for health care, in contrast with the official pragmatic model used in Stockholm County, which is a combined model based on need and the previous year’s consumption of primary health care. This is also the traditional way health authorities in the UK calculate the budget for primary health care, a budget based on historical expenditure, with an allowance for deprivation. In a study from Scotland, it was suggested that progressivity in the delivery of health care could be regarded as a frontier problem analogous to efficiency.32 In Sweden, as in several other Western countries, recruitment of GPs to the most deprived neighbourhoods has been difficult. A more progressive distribution of resources to the primary health care centres in the most deprived neighbourhoods would facilitate the recruitment of GPs so that, hopefully, people’s health in these areas would also improve. It should be pointed out that, in this study, the tenth decile showed a much higher risk of poor self reported health (OR=2.5) than the corresponding CNI ratio (1.7). This indicates that, after the total distribution of resources has been made, additional resources may be provided for the tenth, most deprived decile.
This study has a few limitations as it is based on cross sectional data that do not permit inferences to be drawn about plausible pathways. Because of non-response, the prevalence of poor self reported health in the population may be underestimated to some extent, although probably not the relative measures. About 5% of all respondents could not be matched with CNI scores, possibly because of incorrect addresses or new residential areas without CNI scores. To gain power, these missing data were not excluded from the analysis. The risk of this introducing a bias is probably small because the risk would be at the same level in the whole Swedish population. The transformed CNI is currently focused on Stockholm, a big city with 1.7 million inhabitants, which might pose problems of generalisability. However, our findings agree with other studies from UK,27,28 and therefore we believe that they have wider application. In other developed countries CNI could be adapted as a practical tool to facilitate a total distribution of primary health care resources based on need. The analysis of the association between the transformed CNI and poor self reported health is based on a random sample of the Swedish population, but the allocation of resources is restricted to Stockholm County and constitutes a limitation. However, the conclusions concerning the association between the transformed CNI and poor self reported health obtained for the whole population of Sweden can be generalised to Stockholm County because of the close similarity between the CNI ratios in Sweden and Stockholm County, which were almost identical.
Care Need Index may be used as a basis for political decision makers re-distributing economic resources to primary health care. Additional economic resources to GP incentives in deprived neighbourhoods, where the need is greatest, would make it possible to increase the number of GPs and district nurses and improve diagnostic procedures. Although we still cannot provide evidence that the CNI model actually redistributes more resources to the most deprived neighbourhoods than the official model does it is based on measures of material, social and cultural needs, which constitute a better theoretical approach than the consumption model. However, redistribution of additional resources to deprived neighbourhoods should be done with care because of the limited economic resources in the total health care budget.
Furthermore, this study also has some additional strengths. The use of a multilevel technique provides information at both the individual and the neighbourhood level. Another substantial strength of the study is that it is based on a large and well defined simple random sample of the Swedish population. Finally, it is easy to update the index because the items in CNI are renewed annually.
CNI may be used as a basis for political decision makers re-distributing economic resources to primary health care. Additional economic resources to GP incentives in deprived neighbourhoods, where the need is greatest, would make it possible to increase the number of GPs and district nurses and improve diagnostic procedures. Although we still cannot provide evidence that the CNI model actually redistributes more resources to the most deprived neighbourhoods than the official model does, it is based on measures of material and social needs, which constitute a better theoretical approach than the consumption of primary health care in previous years. However, re-distributing of additional resources to deprived neighbourhoods should be done with care because of limited economic resources in the total health care budget. Finally, the CNI can be used to distribute total primary health care resources.
Funding: this study was supported by grants from the Swedish Medical Research Council (K01–27X-11651–04A), the Swedish Council for Social Research, the Stockholm County, the Axel and Margaret Johnson Foundation, National Institutes of Health (1RO1 HL71084–01), and the Knut and Alice Wallenberg Foundation to Jan Sundquist.
Conflicts of interest: none.
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