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Life tables for global surveillance of cancer survival (the CONCORD programme) : Data sources and methods

Spika, Devon LU ; Bannon, Finian ; Bonaventure, Audrey ; Woods, Laura M. ; Harewood, Rhea ; Carreira, Helena ; Coleman, Michel P. and Allemani, Claudia (2017) In BMC Cancer 17(1).
Abstract

Background: We set out to estimate net survival trends for 10 common cancers in 279 cancer registry populations in 67 countries around the world, as part of the CONCORD-2 study. Net survival can be interpreted as the proportion of cancer patients who survive up to a given time, after eliminating the impact of mortality from other causes (background mortality). Background mortality varies widely between populations and over time. It was therefore necessary to construct robust life tables that accurately reflected the background mortality in each of the registry populations. Methods: Life tables of all-cause mortality rates by single year of age and sex were constructed by calendar year for each population and, when possible, by racial or... (More)

Background: We set out to estimate net survival trends for 10 common cancers in 279 cancer registry populations in 67 countries around the world, as part of the CONCORD-2 study. Net survival can be interpreted as the proportion of cancer patients who survive up to a given time, after eliminating the impact of mortality from other causes (background mortality). Background mortality varies widely between populations and over time. It was therefore necessary to construct robust life tables that accurately reflected the background mortality in each of the registry populations. Methods: Life tables of all-cause mortality rates by single year of age and sex were constructed by calendar year for each population and, when possible, by racial or ethnic sub-groups. We used three different approaches, based on the type of mortality data available from each registry. With death and population counts, we adopted a flexible multivariable modelling approach. With unsmoothed mortality rates, we used the Ewbank relational method. Where no data were available from the registry or a national statistical office, we used the abridged UN Population Division life tables and interpolated these using the Elandt-Johnson method. We also investigated the impact of using state- and race-specific life tables versus national race-specific life tables on estimates of net survival from four adult cancers in the United States (US). Results: We constructed 6,514 life tables covering 327 populations. Wide variations in life expectancy at birth and mortality by age were observed, even within countries. During 1995-99, life expectancy was lowest in Nigeria and highest in Japan, ranging from 47 to 84 years among females and 46 to 78 years among males. During 2005-09, life expectancy was lowest in Lesotho and again highest in Japan, ranging from 45 to 86 years among females and 45 to 80 years among males. For the US, estimates of net survival differed by up to 4% if background mortality was fully controlled with state- and race-specific life tables, rather than with national race-specific life tables. Conclusions: Background mortality varies worldwide. This emphasises the importance of using population-specific life tables for geographic and international comparisons of net survival.

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author
; ; ; ; ; ; and
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Cubic splines, Generalised linear model, Global health, Life expectancy, Life tables, Mortality, Net survival
in
BMC Cancer
volume
17
issue
1
article number
159
publisher
BioMed Central (BMC)
external identifiers
  • scopus:85015161957
  • pmid:28241815
ISSN
1471-2407
DOI
10.1186/s12885-017-3117-8
language
English
LU publication?
no
id
7a813244-65b1-434f-8101-9966cf1f5705
date added to LUP
2019-06-10 13:37:03
date last changed
2024-05-29 14:00:15
@article{7a813244-65b1-434f-8101-9966cf1f5705,
  abstract     = {{<p>Background: We set out to estimate net survival trends for 10 common cancers in 279 cancer registry populations in 67 countries around the world, as part of the CONCORD-2 study. Net survival can be interpreted as the proportion of cancer patients who survive up to a given time, after eliminating the impact of mortality from other causes (background mortality). Background mortality varies widely between populations and over time. It was therefore necessary to construct robust life tables that accurately reflected the background mortality in each of the registry populations. Methods: Life tables of all-cause mortality rates by single year of age and sex were constructed by calendar year for each population and, when possible, by racial or ethnic sub-groups. We used three different approaches, based on the type of mortality data available from each registry. With death and population counts, we adopted a flexible multivariable modelling approach. With unsmoothed mortality rates, we used the Ewbank relational method. Where no data were available from the registry or a national statistical office, we used the abridged UN Population Division life tables and interpolated these using the Elandt-Johnson method. We also investigated the impact of using state- and race-specific life tables versus national race-specific life tables on estimates of net survival from four adult cancers in the United States (US). Results: We constructed 6,514 life tables covering 327 populations. Wide variations in life expectancy at birth and mortality by age were observed, even within countries. During 1995-99, life expectancy was lowest in Nigeria and highest in Japan, ranging from 47 to 84 years among females and 46 to 78 years among males. During 2005-09, life expectancy was lowest in Lesotho and again highest in Japan, ranging from 45 to 86 years among females and 45 to 80 years among males. For the US, estimates of net survival differed by up to 4% if background mortality was fully controlled with state- and race-specific life tables, rather than with national race-specific life tables. Conclusions: Background mortality varies worldwide. This emphasises the importance of using population-specific life tables for geographic and international comparisons of net survival.</p>}},
  author       = {{Spika, Devon and Bannon, Finian and Bonaventure, Audrey and Woods, Laura M. and Harewood, Rhea and Carreira, Helena and Coleman, Michel P. and Allemani, Claudia}},
  issn         = {{1471-2407}},
  keywords     = {{Cubic splines; Generalised linear model; Global health; Life expectancy; Life tables; Mortality; Net survival}},
  language     = {{eng}},
  month        = {{02}},
  number       = {{1}},
  publisher    = {{BioMed Central (BMC)}},
  series       = {{BMC Cancer}},
  title        = {{Life tables for global surveillance of cancer survival (the CONCORD programme) : Data sources and methods}},
  url          = {{http://dx.doi.org/10.1186/s12885-017-3117-8}},
  doi          = {{10.1186/s12885-017-3117-8}},
  volume       = {{17}},
  year         = {{2017}},
}