Exploring Variation in Glycemic Control Across and Within Eight High-Income Countries: A Cross-sectional Analysis of 64,666 Children and Adolescents With Type 1 Diabetes

TY - JOUR

T1 - Exploring Variation in Glycemic Control Across and Within Eight High-Income Countries

T2 - A Cross-sectional Analysis of 64,666 Children and Adolescents With Type 1 Diabetes

AU - Charalampopoulos, Dimitrios

AU - Hermann, Julia M

AU - Svensson, Jannet

AU - Skrivarhaug, Torild

AU - Maahs, David M

AU - Akesson, Karin

AU - Warner, Justin T

AU - Holl, Reinhard W

AU - Birkebæk, Niels H

AU - Drivvoll, Ann K

AU - Miller, Kellee M

AU - Svensson, Ann-Marie

AU - Stephenson, Terence

AU - Hofer, Sabine E

AU - Fredheim, Siri

AU - Kummernes, Siv J

AU - Foster, Nicole

AU - Hanberger, Lena

AU - Amin, Rakesh

AU - Rami-Merhar, Birgit

AU - Johansen, Anders

AU - Dahl-Jørgensen, Knut

AU - Clements, Mark

AU - Hanas, Ragnar

N1 - © 2018 by the American Diabetes Association.

PY - 2018/6/1

Y1 - 2018/6/1

N2 - OBJECTIVE International studies on childhood type 1 diabetes (T1D) have focused on wholecountrymean HbA1c levels, thereby concealing potential variations within countries. We aimed to explore the variations in HbA1c across and within eight high-income countries to best inform international benchmarking and policy recommendations. RESEARCH DESIGN AND METHODS Data were collected between 2013 and 2014 from 64,666 children with T1D who were <18 years of age across 528 centers in Germany, Austria, England, Wales, U.S., Sweden,Denmark, and Norway.We used fixed- and random-effectsmodels adjusted for age, sex, diabetes duration, and minority status to describe differences between center means and to calculate the proportion of total variation in HbA1c levels that is attributable to between-center differences (intraclass correlation [ICC]). We also explored the association between within-center variation and children's glycemic control. RESULTS Sweden had the lowestmeanHbA1c (59mmol/mol [7.6%]) and togetherwithNorway andDenmark showed the lowest between-center variations (ICC ≤4%). Germany and Austria had the next lowest mean HbA1c (61-62 mmol/mol [7.7-7.8%]) but showed the largest center variations (ICC ∼15%). Centers in England, Wales, and the U.S. showed low-to-moderate variation around high mean values. In pooled analysis, differences between counties remained significant after adjustment for children characteristics and center effects (P value <0.001). Across all countries, children attending centers withmore variable glycemic results had higher HbA1c levels (5.6mmol/mol [0.5%] per 5mmol/mol [0.5%] increase in centerSD of HbA1c values of all children attending a specific center). CONCLUSIONS Atsimilaraveragelevels ofHbA1c, countriesdisplaydifferentlevelsofcentervariation. The distribution of glycemic achievement within countries should be considered in developing informed policies that drive quality improvement.

AB - OBJECTIVE International studies on childhood type 1 diabetes (T1D) have focused on wholecountrymean HbA1c levels, thereby concealing potential variations within countries. We aimed to explore the variations in HbA1c across and within eight high-income countries to best inform international benchmarking and policy recommendations. RESEARCH DESIGN AND METHODS Data were collected between 2013 and 2014 from 64,666 children with T1D who were <18 years of age across 528 centers in Germany, Austria, England, Wales, U.S., Sweden,Denmark, and Norway.We used fixed- and random-effectsmodels adjusted for age, sex, diabetes duration, and minority status to describe differences between center means and to calculate the proportion of total variation in HbA1c levels that is attributable to between-center differences (intraclass correlation [ICC]). We also explored the association between within-center variation and children's glycemic control. RESULTS Sweden had the lowestmeanHbA1c (59mmol/mol [7.6%]) and togetherwithNorway andDenmark showed the lowest between-center variations (ICC ≤4%). Germany and Austria had the next lowest mean HbA1c (61-62 mmol/mol [7.7-7.8%]) but showed the largest center variations (ICC ∼15%). Centers in England, Wales, and the U.S. showed low-to-moderate variation around high mean values. In pooled analysis, differences between counties remained significant after adjustment for children characteristics and center effects (P value <0.001). Across all countries, children attending centers withmore variable glycemic results had higher HbA1c levels (5.6mmol/mol [0.5%] per 5mmol/mol [0.5%] increase in centerSD of HbA1c values of all children attending a specific center). CONCLUSIONS Atsimilaraveragelevels ofHbA1c, countriesdisplaydifferentlevelsofcentervariation. The distribution of glycemic achievement within countries should be considered in developing informed policies that drive quality improvement.

KW - Adolescent

KW - Austria/epidemiology

KW - Blood Glucose/metabolism

KW - Child

KW - Cross-Sectional Studies

KW - Denmark/epidemiology

KW - Developed Countries/economics

KW - Diabetes Mellitus, Type 1/blood

KW - England/epidemiology

KW - Female

KW - Germany/epidemiology

KW - Glycated Hemoglobin A/analysis

KW - Humans

KW - Income/statistics & numerical data

KW - Male

KW - Minority Groups/statistics & numerical data

KW - Norway/epidemiology

KW - Sweden/epidemiology

KW - Wales/epidemiology

U2 - 10.2337/dc17-2271

DO - 10.2337/dc17-2271

M3 - Journal article

C2 - 29650804

SN - 0149-5992

VL - 41

SP - 1180

EP - 1187

JO - Diabetes Care

JF - Diabetes Care

IS - 6

ER -