Multimorbidity prevalence and health outcome prediction: assessing the impact of lookback periods, disease count, and definition criteria in health administrative data at the population-based level

Marc Simard; Elham Rahme; Marjolaine Dubé; Véronique Boiteau; Denis Talbot; Caroline Sirois

doi:10.1186/s12874-024-02243-0

BMC Medical Research Methodology (May 2024)

Multimorbidity prevalence and health outcome prediction: assessing the impact of lookback periods, disease count, and definition criteria in health administrative data at the population-based level

Marc Simard,
Elham Rahme,
Marjolaine Dubé,
Véronique Boiteau,
Denis Talbot,
Caroline Sirois

Affiliations

Marc Simard: Institut national de santé publique du Québec
Elham Rahme: The Research Institute of the McGill University Health Centre
Marjolaine Dubé: Institut national de santé publique du Québec
Véronique Boiteau: Institut national de santé publique du Québec
Denis Talbot: Department of social and preventive medicine, Faculty of Medicine, Université Laval
Caroline Sirois: Institut national de santé publique du Québec

DOI: https://doi.org/10.1186/s12874-024-02243-0
Journal volume & issue: Vol. 24, no. 1
pp. 1 – 10

Abstract

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Abstract Background Health administrative databases play a crucial role in population-level multimorbidity surveillance. Determining the appropriate retrospective or lookback period (LP) for observing prevalent and newly diagnosed diseases in administrative data presents challenge in estimating multimorbidity prevalence and predicting health outcome. The aim of this population-based study was to assess the impact of LP on multimorbidity prevalence and health outcomes prediction across three multimorbidity definitions, three lists of diseases used for multimorbidity assessment, and six health outcomes. Methods We conducted a population-based study including all individuals ages > 65 years on April 1st, 2019, in Québec, Canada. We considered three lists of diseases labeled according to the number of chronic conditions it considered: (1) L60 included 60 chronic conditions from the International Classification of Diseases (ICD); (2) L20 included a core of 20 chronic conditions; and (3) L31 included 31 chronic conditions from the Charlson and Elixhauser indices. For each list, we: (1) measured multimorbidity prevalence for three multimorbidity definitions (at least two [MM2+], three [MM3+] or four (MM4+) chronic conditions); and (2) evaluated capacity (c-statistic) to predict 1-year outcomes (mortality, hospitalisation, polypharmacy, and general practitioner, specialist, or emergency department visits) using LPs ranging from 1 to 20 years. Results Increase in multimorbidity prevalence decelerated after 5–10 years (e.g., MM2+, L31: LP = 1y: 14%, LP = 10y: 58%, LP = 20y: 69%). Within the 5–10 years LP range, predictive performance was better for L20 than L60 (e.g., LP = 7y, mortality, MM3+: L20 [0.798;95%CI:0.797-0.800] vs. L60 [0.779; 95%CI:0.777–0.781]) and typically better for MM3 + and MM4 + definitions (e.g., LP = 7y, mortality, L60: MM4+ [0.788;95%CI:0.786–0.790] vs. MM2+ [0.768;95%CI:0.766–0.770]). Conclusions In our databases, ten years of data was required for stable estimation of multimorbidity prevalence. Within that range, the L20 and multimorbidity definitions MM3 + or MM4 + reached maximal predictive performance.

Published in BMC Medical Research Methodology

ISSN: 1471-2288 (Online)
Publisher: BMC
Country of publisher: United Kingdom
LCC subjects: Medicine: Medicine (General)
Website: http://bmcmedresmethodol.biomedcentral.com

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