Matthew W Segar1,2, Kershaw V Patel1,3, Muthiah Vaduganathan4, Melissa C Caughey5, Byron C Jaeger6, Mujeeb Basit1, Duwayne Willett1, Javed Butler7, Partho P Sengupta8, Thomas J Wang1, Darren K McGuire1,2, Ambarish Pandey9,10. 1. Division of Cardiology, Department of Internal Medicine, University of Texas Southwestern Medical Center, Dallas, TX, USA. 2. Parkland Health and Hospital System, Dallas, TX, USA. 3. Department of Cardiology, Houston Methodist DeBakey Heart and Vascular Center, Houston, TX, USA. 4. Brigham and Women's Hospital Heart and Vascular Center, Department of Medicine, Harvard Medical School, Boston, MA, USA. 5. Joint Department of Biomedical Engineering, University of North Carolina and North Carolina State University, Chapel Hill, NC, USA. 6. Department of Biostatistics, University of Alabama Birmingham, Birmingham, AL, USA. 7. Department of Internal Medicine, University of Mississippi Medical Center, Jackson, MS, USA. 8. Division of Cardiology, West Virginia University, Morgantown, WV, USA. 9. Division of Cardiology, Department of Internal Medicine, University of Texas Southwestern Medical Center, Dallas, TX, USA. ambarish.pandey@outlook.com. 10. Parkland Health and Hospital System, Dallas, TX, USA. ambarish.pandey@outlook.com.
Abstract
AIMS/HYPOTHESIS: Type 2 diabetes is a heterogeneous disease process with variable trajectories of CVD risk. We aimed to evaluate four phenomapping strategies and their ability to stratify CVD risk in individuals with type 2 diabetes and to identify subgroups who may benefit from specific therapies. METHODS: Participants with type 2 diabetes and free of baseline CVD in the Action to Control Cardiovascular Risk in Diabetes (ACCORD) trial were included in this study (N = 6466). Clustering using Gaussian mixture models, latent class analysis, finite mixture models (FMMs) and principal component analysis was compared. Clustering variables included demographics, medical and social history, laboratory values and diabetes complications. The interaction between the phenogroup and intensive glycaemic, combination lipid and intensive BP therapy for the risk of the primary outcome (composite of fatal myocardial infarction, non-fatal myocardial infarction or unstable angina) was evaluated using adjusted Cox models. The phenomapping strategies were independently assessed in an external validation cohort (Look Action for Health in Diabetes [Look AHEAD] trial: n = 4211; and Bypass Angioplasty Revascularisation Investigation 2 Diabetes [BARI 2D] trial: n = 1495). RESULTS: Over 9.1 years of follow-up, 789 (12.2%) participants had a primary outcome event. FMM phenomapping with three phenogroups was the best-performing clustering strategy in both the derivation and validation cohorts as determined by Bayesian information criterion, Dunn index and improvement in model discrimination. Phenogroup 1 (n = 663, 10.3%) had the highest burden of comorbidities and diabetes complications, phenogroup 2 (n = 2388, 36.9%) had an intermediate comorbidity burden and lowest diabetes complications, and phenogroup 3 (n = 3415, 52.8%) had the fewest comorbidities and intermediate burden of diabetes complications. Significant interactions were observed between phenogroups and treatment interventions including intensive glycaemic control (p-interaction = 0.042) and combination lipid therapy (p-interaction < 0.001) in the ACCORD, intensive lifestyle intervention (p-interaction = 0.002) in the Look AHEAD and early coronary revascularisation (p-interaction = 0.003) in the BARI 2D trial cohorts for the risk of the primary composite outcome. Favourable reduction in the risk of the primary composite outcome with these interventions was noted in low-risk participants of phenogroup 3 but not in other phenogroups. Compared with phenogroup 3, phenogroup 1 participants were more likely to have severe/symptomatic hypoglycaemic events and medication non-adherence on follow-up in the ACCORD and Look AHEAD trial cohorts. CONCLUSIONS/ INTERPRETATION: Clustering using FMMs was the optimal phenomapping strategy to identify replicable subgroups of patients with type 2 diabetes with distinct clinical characteristics, CVD risk and response to therapies.
AIMS/HYPOTHESIS: Type 2 diabetes is a heterogeneous disease process with variable trajectories of CVD risk. We aimed to evaluate four phenomapping strategies and their ability to stratify CVD risk in individuals with type 2 diabetes and to identify subgroups who may benefit from specific therapies. METHODS: Participants with type 2 diabetes and free of baseline CVD in the Action to Control Cardiovascular Risk in Diabetes (ACCORD) trial were included in this study (N = 6466). Clustering using Gaussian mixture models, latent class analysis, finite mixture models (FMMs) and principal component analysis was compared. Clustering variables included demographics, medical and social history, laboratory values and diabetes complications. The interaction between the phenogroup and intensive glycaemic, combination lipid and intensive BP therapy for the risk of the primary outcome (composite of fatal myocardial infarction, non-fatal myocardial infarction or unstable angina) was evaluated using adjusted Cox models. The phenomapping strategies were independently assessed in an external validation cohort (Look Action for Health in Diabetes [Look AHEAD] trial: n = 4211; and Bypass Angioplasty Revascularisation Investigation 2 Diabetes [BARI 2D] trial: n = 1495). RESULTS: Over 9.1 years of follow-up, 789 (12.2%) participants had a primary outcome event. FMM phenomapping with three phenogroups was the best-performing clustering strategy in both the derivation and validation cohorts as determined by Bayesian information criterion, Dunn index and improvement in model discrimination. Phenogroup 1 (n = 663, 10.3%) had the highest burden of comorbidities and diabetes complications, phenogroup 2 (n = 2388, 36.9%) had an intermediate comorbidity burden and lowest diabetes complications, and phenogroup 3 (n = 3415, 52.8%) had the fewest comorbidities and intermediate burden of diabetes complications. Significant interactions were observed between phenogroups and treatment interventions including intensive glycaemic control (p-interaction = 0.042) and combination lipid therapy (p-interaction < 0.001) in the ACCORD, intensive lifestyle intervention (p-interaction = 0.002) in the Look AHEAD and early coronary revascularisation (p-interaction = 0.003) in the BARI 2D trial cohorts for the risk of the primary composite outcome. Favourable reduction in the risk of the primary composite outcome with these interventions was noted in low-risk participants of phenogroup 3 but not in other phenogroups. Compared with phenogroup 3, phenogroup 1 participants were more likely to have severe/symptomatic hypoglycaemic events and medication non-adherence on follow-up in the ACCORD and Look AHEAD trial cohorts. CONCLUSIONS/ INTERPRETATION: Clustering using FMMs was the optimal phenomapping strategy to identify replicable subgroups of patients with type 2 diabetes with distinct clinical characteristics, CVD risk and response to therapies.
Authors: Søren L Kristensen; Rasmus Rørth; Pardeep S Jhund; Kieran F Docherty; Naveed Sattar; David Preiss; Lars Køber; Mark C Petrie; John J V McMurray Journal: Lancet Diabetes Endocrinol Date: 2019-08-14 Impact factor: 32.069
Authors: Sanjiv J Shah; Daniel H Katz; Senthil Selvaraj; Michael A Burke; Clyde W Yancy; Mihai Gheorghiade; Robert O Bonow; Chiang-Ching Huang; Rahul C Deo Journal: Circulation Date: 2014-11-14 Impact factor: 29.690
Authors: David D Berg; Stephen D Wiviott; Benjamin M Scirica; Yared Gurmu; Ofri Mosenzon; Sabina A Murphy; Deepak L Bhatt; Lawrence A Leiter; Darren K McGuire; John P H Wilding; Per Johanson; Peter A Johansson; Anna Maria Langkilde; Itamar Raz; Eugene Braunwald; Marc S Sabatine Journal: Circulation Date: 2019-08-31 Impact factor: 29.690
Authors: Thomas A Zelniker; Stephen D Wiviott; Itamar Raz; Kyungah Im; Erica L Goodrich; Marc P Bonaca; Ofri Mosenzon; Eri T Kato; Avivit Cahn; Remo H M Furtado; Deepak L Bhatt; Lawrence A Leiter; Darren K McGuire; John P H Wilding; Marc S Sabatine Journal: Lancet Date: 2018-11-10 Impact factor: 79.321
Authors: Matthew W Segar; Kershaw V Patel; Colby Ayers; Mujeeb Basit; W H Wilson Tang; Duwayne Willett; Jarett Berry; Justin L Grodin; Ambarish Pandey Journal: Eur J Heart Fail Date: 2019-10-21 Impact factor: 15.534
Authors: Daniel H Katz; Rahul C Deo; Frank G Aguilar; Senthil Selvaraj; Eva E Martinez; Lauren Beussink-Nelson; Kwang-Youn A Kim; Jie Peng; Marguerite R Irvin; Hemant Tiwari; D C Rao; Donna K Arnett; Sanjiv J Shah Journal: J Cardiovasc Transl Res Date: 2017-03-03 Impact factor: 4.132
Authors: Matthew W Segar; Muthiah Vaduganathan; Kershaw V Patel; Darren K McGuire; Javed Butler; Gregg C Fonarow; Mujeeb Basit; Vaishnavi Kannan; Justin L Grodin; Brendan Everett; Duwayne Willett; Jarett Berry; Ambarish Pandey Journal: Diabetes Care Date: 2019-09-13 Impact factor: 19.112
Authors: Qi Guo; Xiaoni Lu; Ya Gao; Jingjing Zhang; Bin Yan; Dan Su; Anqi Song; Xi Zhao; Gang Wang Journal: Sci Rep Date: 2017-03-07 Impact factor: 4.379