Measuring and monitoring inequalities in health is important for informing policies and programs that aim to tackle health inequities. Broadly defined, inequalities in health are measurable differences in health across population subgroups defined by dimensions of inequality (demographic, socioeconomic or geographic characteristics). Summary measures of inequality summarise the amount of inequality across subgroups in a single number – which facilitates the comparison of inequalities over time and across different settings and indicators.
Summary measures of health inequality use either disaggregated data or individual-level data as inputs.
Disaggregated data refers to health indicator data recorded for different subgroups of a population that are defined according to dimensions of inequality, such as demographic, socioeconomic or geographic characteristics (such as wealth quintiles or subnational regions). Each record in the dataset contains data for a population subgroup.
Individual-level data refers to data where each record in the dataset contains data pertaining to an individual.
Simple summary measures (difference and ratio) compare two population subgroups. They can be calculated for all dimensions of inequality (with two subgroups or more). Complex measures are calculated for inequality dimensions with more than two population subgroups and consider the situation in all subgroups. They can only be calculated for dimensions with more than two subgroups.
Selecting appropriate measures for analysing and reporting inequality involves considering several methodological issues. There are considerations relating to the characteristics of the underlying data, which determines the types of measures that can be calculated and how they are calculated:
There are also considerations relating to the properties of the different measures and the desired purpose of the analysis:
The paper Summary measures of health inequality: a review of existing measures and their application provides further information about these considerations.
The following summary measures of health inequality are included in
the healthequal
library:
d
)r
)aci
)rci
)sii
)rii
)bgv
)bgsd
)covar
)mdmu
and mdmw
)mdbu
and mdbw
)mdru
and mdrw
)idisu
and
idisw
)ti
)mld
)parisk
)paf
)healthequal
libraryFirst, load the healthequal
library in your R session.
This requires the dplyr
package.
healthequal
packageThe healthequal
package comes with sample data for users
to be able to test the package functions. The OrderedSample
and NonorderedSample
data contain data disaggregated by
economic status and subnational region, respectively, for a single
indicator.
indicator
1 Births attended by skilled health personnel (%)
2 Births attended by skilled health personnel (%)
3 Births attended by skilled health personnel (%)
4 Births attended by skilled health personnel (%)
dimension subgroup subgroup_order
1 Economic status (wealth quintile) Quintile 1 (poorest) 1
2 Economic status (wealth quintile) Quintile 2 2
3 Economic status (wealth quintile) Quintile 3 3
4 Economic status (wealth quintile) Quintile 4 4
estimate se population setting_average favourable_indicator
1 75.60530 1.5996131 2072.436 91.59669 1
2 91.01997 1.1351504 2112.204 91.59669 1
3 96.03959 0.6461946 1983.059 91.59669 1
4 97.04223 0.5676206 2052.124 91.59669 1
ordered_dimension indicator_scale
1 1 100
2 1 100
3 1 100
4 1 100
indicator dimension
1 Births attended by skilled health personnel (%) Subnational region
2 Births attended by skilled health personnel (%) Subnational region
3 Births attended by skilled health personnel (%) Subnational region
4 Births attended by skilled health personnel (%) Subnational region
subgroup estimate se population setting_average
1 aceh 95.11784 1.538443 230.20508 91.59669
2 bali 100.00000 0.000000 149.46272 91.59669
3 bangka balitung 97.41001 1.267644 55.66533 91.59669
4 banten 80.35694 3.544053 451.26550 91.59669
favourable_indicator ordered_dimension indicator_scale reference_subgroup
1 1 0 100 1
2 1 0 100 0
3 1 0 100 0
4 1 0 100 0
The OrderedSampleMultipleind
and
OrderedSampleMultipleind
data contain disaggregated data by
economic status and subnational region, respectively, for two
indicators.
indicator
1 Births attended by skilled health personnel (%)
2 Births attended by skilled health personnel (%)
3 Births attended by skilled health personnel (%)
4 Births attended by skilled health personnel (%)
dimension subgroup subgroup_order
1 Economic status (wealth quintile) Quintile 1 (poorest) 1
2 Economic status (wealth quintile) Quintile 2 2
3 Economic status (wealth quintile) Quintile 3 3
4 Economic status (wealth quintile) Quintile 4 4
estimate se population setting_average favourable_indicator
1 75.60530 1.5996131 2072.436 91.59669 1
2 91.01997 1.1351504 2112.204 91.59669 1
3 96.03959 0.6461946 1983.059 91.59669 1
4 97.04223 0.5676206 2052.124 91.59669 1
ordered_dimension indicator_scale
1 1 100
2 1 100
3 1 100
4 1 100
indicator dimension
1 Births attended by skilled health personnel (%) Subnational region
2 Births attended by skilled health personnel (%) Subnational region
3 Births attended by skilled health personnel (%) Subnational region
4 Births attended by skilled health personnel (%) Subnational region
subgroup estimate se population setting_average
1 aceh 95.11784 1.538443 230.20508 91.59669
2 bali 100.00000 0.000000 149.46272 91.59669
3 bangka balitung 97.41001 1.267644 55.66533 91.59669
4 banten 80.35694 3.544053 451.26550 91.59669
favourable_indicator ordered_dimension indicator_scale reference_subgroup
1 1 0 100 1
2 1 0 100 0
3 1 0 100 0
4 1 0 100 0
For information about the datasets, type the following commands, which will display the corresponding dataset help file:
The Absolute Concentration Index (ACI) is a summary measure of health inequality that can be used with ordered dimensions. For information about the ACI function type the following command, which will display the corresponding help file:
The OrderedSample
dataset can be used to calculate ACI.
Two arguments are required: est
(the subgroup estimate,
recorded as estimate
in the same dataset), and
subgroup_order
(the order of subgroups in an increasing
sequence). Other arguments, such as pop
(the number of
people within each subgroup, recorded as population
in the
sample dataset) or weight
(the sampling weight for survey
data), are optional. Lastly, the force
argument can be used
to estimate ACI when some estimates are missing.
measure estimate se lowerci upperci
1 aci 4.30052 1.284031 1.783865 6.817174
The Slope Index of Inequality (SII) is a summary measure of health inequality that can be used with ordered dimensions. The slope index of inequality (SII) is an absolute measure of inequality that represents the difference in estimated indicator values between the most-advantaged and most-disadvantaged, while taking into consideration the situation in all other subgroups/individuals – using an appropriate regression model.
For information about the SII function type the following command, which will display the corresponding help file:
SII can be calculated using disaggregated or individual data. In this
example, the IndividualSample
dataset, a survey weighted
dataset, is used. For this type of data, five arguments are required:
est
(the individual estimate, recorded as sba
in the same dataset), subgroup_order
(the order of
subgroups in an increasing sequence), weight
(the sampling
weight), psu
(the primary sampling unit) and
strata
(the variable identifying the strata).
with(IndividualSample,
aci(est = sba,
subgroup_order = subgroup_order,
weight = weight,
psu = psu,
strata = strata))
measure estimate se lowerci upperci
1 aci 0.07801353 0.002950566 0.07223053 0.08379654
Between-group variance (BGV) is a summary measure of health
inequality that it can be used to measure inequality across
non-ordered dimensions of inequality. It is calculated
as the weighted average of squared differences between subgroup
estimates and the weighted mean. Type ?bgv
to view the
corresponding help file.
The NonorderedSample
dataset can be used to calculate
BGV, which requires two arguments: pop
(the number of
people within each subgroup, recorded as population
in the
sample dataset), and est
(the subgroup estimate, recorded
as estimate
in the same dataset). The argument
se
(the standard error of the subgroup estimate) is
required only to compute the corresponding 95% confidence intervals.
measure estimate se lowerci upperci
1 bgv 50.42023 9.560196 31.68259 69.15787
The previous examples showed the calculation of a single measure of
inequality for a single indicator-dimension combination. These next
examples use the dataset NonorderedSampleMultipleind
, which
contains disaggregated data by subnational region for two
indicators:
The data can be inspected as follows:
indicator dimension
1 Births attended by skilled health personnel (%) Subnational region
2 Births attended by skilled health personnel (%) Subnational region
3 Births attended by skilled health personnel (%) Subnational region
4 Births attended by skilled health personnel (%) Subnational region
subgroup estimate se population setting_average
1 aceh 95.11784 1.538443 230.20508 91.59669
2 bali 100.00000 0.000000 149.46272 91.59669
3 bangka balitung 97.41001 1.267644 55.66533 91.59669
4 banten 80.35694 3.544053 451.26550 91.59669
favourable_indicator ordered_dimension indicator_scale reference_subgroup
1 1 0 100 1
2 1 0 100 0
3 1 0 100 0
4 1 0 100 0
[1] "Births attended by skilled health personnel (%)"
[2] "Under-five mortality rate (deaths per 1000 live births)"
The Coefficient of Variation (COV) is a summary measure of health
inequality that it can be used to measure inequality across
non-ordered dimensions of inequality. COV is a relative
measure of inequality that considers all population subgroups. Type
?covar
to view the corresponding help file. The
NonorderedSampleMultipleind
dataset can be used to
calculate COV for two different dimensions.
library(dplyr)
measures <- NonorderedSampleMultipleind %>%
dplyr::group_by(indicator) %>%
dplyr::summarize(covar(est = estimate,
se = se,
pop = population,
scaleval = indicator_scale))
as.data.frame(measures)
indicator measure estimate se
1 Births attended by skilled health personnel (%) cov 7.752158 NA
2 Under-five mortality rate (deaths per 1000 live births) cov 41.500365 NA
lowerci upperci
1 6.860121 9.349835
2 39.094980 46.881011
The NonorderedSampleMultipleind
dataset can also be used
to calculate two or more different summary measures (in the example
below COV and BGV) for multiple dimensions.
multiplemeasures <- NonorderedSampleMultipleind %>%
dplyr::group_by(indicator,
dimension) %>%
dplyr::summarize(
covar = covar(est = estimate,
se = se,
pop = population,
scaleval = indicator_scale),
bgv = bgv(est = estimate,
se = se,
pop = population))
# It is possible to extract the measures separately
multiplemeasures$covar
measure estimate se lowerci upperci
1 cov 7.752158 NA 6.860121 9.349835
2 cov 41.500365 NA 39.094980 46.881011
measure estimate se lowerci upperci
1 bgv 50.42023 9.560196 31.68259 69.15787
2 bgv 2468.70951 273.155091 1933.33537 3004.08365
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