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6. Association of Factor V Leiden With Subsequent Atherothrombotic Events: A GENIUS-CHD Study of Individual Participant Data

Author

Mahmoodi, B.K., Tragante, V., Kleber, M.E., Holmes, M.V., Schmidt, A.F., McCubrey, R.O., Howe, L.J., Direk, K., Allayee, H., Baranova, E.V., Braund, P.S., Delgado, G.E., Eriksson, N., Gijsberts, C.M., Gong, Y., Hartiala, J., Heydarpour, M., Pasterkamp, G., Kotti, S., Kuukasjärvi, P., Lenzini, P.A., Levin, D., Lyytikäinen, L.P., Muehlschlegel, J.D., Nelson, C.P., Nikus, K., Pilbrow, A.P., Tang, W.H., Laan, S.W. van der, Setten, J. van, Vilmundarson, R.O., Deanfield, J., Deloukas, P., Dudbridge, F., James, S., Mordi, I.R., Teren, A., Bergmeijer, T.O., Body, S.C., Bots, M., Burkhardt, R., Cooper-DeHoff, R.M., Cresci, S., Danchin, N., Doughty, R.N., Grobbee, D.E., Hagström, E., Hazen, S.L., Held, C., Hoefer, I.E., Hovingh, G.K., Johnson, J.A., Kaczor, M.P., Kähönen, M., Klungel, O.H., Laurikka, J.O., Lehtimäki, T., Maitland-van der Zee, A.H., McPherson, R., Palmer, C.N., Kraaijeveld, A.O., Pepine, C.J., Sanak, M., Sattar, N., Scholz, M., Simon, T., Spertus, J.A., Stewart, A.F., Szczeklik, W., Thiery, J., Visseren, F.L., Waltenberger, J., Richards, A.M.S., Lang, C.C., Cameron, V.A., Åkerblom, A., Pare, G., März, W., Samani, N.J., Hingorani, A.D., Berg, J.M. ten, Wallentin, L., Asselbergs, F.W., Patel, R.S., Mahmoodi, B.K., Tragante, V., Kleber, M.E., Holmes, M.V., Schmidt, A.F., McCubrey, R.O., Howe, L.J., Direk, K., Allayee, H., Baranova, E.V., Braund, P.S., Delgado, G.E., Eriksson, N., Gijsberts, C.M., Gong, Y., Hartiala, J., Heydarpour, M., Pasterkamp, G., Kotti, S., Kuukasjärvi, P., Lenzini, P.A., Levin, D., Lyytikäinen, L.P., Muehlschlegel, J.D., Nelson, C.P., Nikus, K., Pilbrow, A.P., Tang, W.H., Laan, S.W. van der, Setten, J. van, Vilmundarson, R.O., Deanfield, J., Deloukas, P., Dudbridge, F., James, S., Mordi, I.R., Teren, A., Bergmeijer, T.O., Body, S.C., Bots, M., Burkhardt, R., Cooper-DeHoff, R.M., Cresci, S., Danchin, N., Doughty, R.N., Grobbee, D.E., Hagström, E., Hazen, S.L., Held, C., Hoefer, I.E., Hovingh, G.K., Johnson, J.A., Kaczor, M.P., Kähönen, M., Klungel, O.H., Laurikka, J.O., Lehtimäki, T., Maitland-van der Zee, A.H., McPherson, R., Palmer, C.N., Kraaijeveld, A.O., Pepine, C.J., Sanak, M., Sattar, N., Scholz, M., Simon, T., Spertus, J.A., Stewart, A.F., Szczeklik, W., Thiery, J., Visseren, F.L., Waltenberger, J., Richards, A.M.S., Lang, C.C., Cameron, V.A., Åkerblom, A., Pare, G., März, W., Samani, N.J., Hingorani, A.D., Berg, J.M. ten, Wallentin, L., Asselbergs, F.W., and Patel, R.S.

Abstract

Contains fulltext : 235380.pdf (Publisher’s version ) (Closed access), BACKGROUND: Studies examining the role of factor V Leiden among patients at higher risk of atherothrombotic events, such as those with established coronary heart disease (CHD), are lacking. Given that coagulation is involved in the thrombus formation stage on atherosclerotic plaque rupture, we hypothesized that factor V Leiden may be a stronger risk factor for atherothrombotic events in patients with established CHD. METHODS: We performed an individual-level meta-analysis including 25 prospective studies (18 cohorts, 3 case-cohorts, 4 randomized trials) from the GENIUS-CHD (Genetics of Subsequent Coronary Heart Disease) consortium involving patients with established CHD at baseline. Participating studies genotyped factor V Leiden status and shared risk estimates for the outcomes of interest using a centrally developed statistical code with harmonized definitions across studies. Cox proportional hazards regression models were used to obtain age- and sex-adjusted estimates. The obtained estimates were pooled using fixed-effect meta-analysis. The primary outcome was composite of myocardial infarction and CHD death. Secondary outcomes included any stroke, ischemic stroke, coronary revascularization, cardiovascular mortality, and all-cause mortality. RESULTS: The studies included 69 681 individuals of whom 3190 (4.6%) were either heterozygous or homozygous (n=47) carriers of factor V Leiden. Median follow-up per study ranged from 1.0 to 10.6 years. A total of 20 studies with 61 147 participants and 6849 events contributed to analyses of the primary outcome. Factor V Leiden was not associated with the combined outcome of myocardial infarction and CHD death (hazard ratio, 1.03 [95% CI, 0.92-1.16]; I(2)=28%; P-heterogeneity=0.12). Subgroup analysis according to baseline characteristics or strata of traditional cardiovascular risk factors did not show relevant differences. Similarly, risk estimates for the secondary outcomes including stroke, coronary revascularization, card

Published
2020

8. Subsequent Event Risk in Individuals With Established Coronary Heart Disease Design and Rationale of the GENIUS-CHD Consortium

Author

Patel, Riyaz, Tragante, Vinicius, Schmidt, Amand F., McCubrey, Raymond O., Holmes, Michael V., Howe, Laurence J., Direk, Kenan, Åkerblom, Axel, Leander, Karin, Virani, Salim S., Kaminski, Karol A., Muehlschlegel, Jochen D., Allayee, Hooman, Almgren, Peter, Alver, Maris, Baranova, Ekaterina V., Behlouli, Hassan, Boeckx, Bram, Braund, Peter S., Breitling, Lutz P., Delgado, Graciela, Duarte, Nubia E., Dubé, Marie-Pierre, Dufresne, Line, Eriksson, Niclas, Foco, Luisa, Scholz, Markus, Gijsberts, Crystel M., Glinge, Charlotte, Gong, Yan, Hartiala, Jaana, Heydarpour, Mahyar, Hubacek, Jaroslav A., Kleber, Marcus, Kofink, Daniel, Kotti, Salma, Kuukasjärvi, Pekka, Lee, Vei-Vei, Leiherer, Andreas, Lenzini, Petra A., Levin, Daniel, Lyytikäinen, Leo-Pekka, Martinelli, Nicola, Mons, Ute, Nelson, Christopher P., Nikus, Kjell, Pilbrow, Anna P., Ploski, Rafal, Sun, Yan V., Tanck, Michael W.T., Tang, W H Wilson, Trompet, Stella, van der Laan, Sander W., Van Setten, Jessica, Vilmundarson, Ragnar O., Viviani Anselmi, Chiara, Vlachopoulou, Efthymia, Al Ali, Lawien, Boerwinkle, Eric, Briguori, Carlo, Carlquist, John F., Carruthers, Kathryn F., Casu, Gavino, Deanfield, John, Deloukas, Panos, Dudbridge, Frank, Engström, Thomas, Fitzpatrick, Natalie, Fox, Kim, Gigante, Bruna, James, Stefan, Lokki, Marja-Liisa, Lotufo, Paulo A., Marziliano, Nicola, Mordi, Ify R., Muhlestein, Joseph B., Newton-Cheh, Christopher, Pitha, Jan, Saely, Christoph H., Samman-Tahhan, Ayman, Sandesara, Pratik B., Teren, Andrej, Timmis, Adam, Van de Werf, Frans, Wauters, Els, Wilde, Arthur A.M., Ford, Ian, Stott, David J., Algra, Ale, Andreassi, Maria G., Ardissino, Diego, Arsenault, Benoit J., Ballantyne, Christie M., Bergmeijer, Thomas O., Bezzina, Connie R., Body, Simon C., Boersma, Eric H., Bogaty, Peter, Bots, Michiel, Brenner, Hermann, Brugts, Jasper J., Burkhardt, Ralph, Carpeggiani, Clara, Condorelli, Gianluigi, Cooper-DeHoff, Rhonda M., Cresci, Sharon, Danchin, Nicolas, de Faire, Ulf, Doughty, Robert N., Drexel, Heinz, Engert, James C., Fox, Keith A.A., Girelli, Domenico, Grobbee, Diederick E., Hagström, Emil, Hazen, Stanley L., Held, Claes, Hemingway, Harry, Hoefer, Imo E., Hovingh, G. Kees, Jabbari, Reza, Johnson, Julie A., Jukema, J. Wouter, Kaczor, Marcin P., Kähönen, Mika, Kettner, Jiri, Kiliszek, Marek, Klungel, Olaf H., Lagerqvist, Bo, Lambrechts, Diether, Laurikka, Jari O., Lehtimäki, Terho, Lindholm, Daniel, Mahmoodi, B.K., Maitland-van der Zee, Anke H., McPherson, Ruth, Melander, Olle, Metspalu, Andres, Niemcunowicz-Janica, Anna, Olivieri, Oliviero, Opolski, Grzegorz, Palmer, Colin N., Pasterkamp, Gerard, Pepine, Carl J., Pereira, Alexandre C., Pilote, Louise, Quyyumi, Arshed A., Richards, A. Mark, Sanak, Marek, Siegbahn, Agneta, Simon, Tabassome, Sinisalo, Juha, Smith, J. Gustav, Spertus, John A., Stender, Steen, Stewart, Alexandre F.R., Szczeklik, Wojciech, Szpakowicz, Anna, Tardif, Jean-Claude, Ten Berg, Jurriën M., Tfelt-Hansen, Jacob, Thanassoulis, George, Thiery, Joachim, Torp-Pedersen, Christian, van der Graaf, Yolanda, Visseren, Frank L.J., Waltenberger, Johannes, Weeke, Peter E., Van der Harst, Pim, Lang, Chim C., Sattar, Naveed, Cameron, Vicky A., Anderson, Jeffrey L., Brophy, James M., Paré, Guillaume, Horne, Benjamin D., März, Winfried, Wallentin, Lars, Samani, Nilesh J., Hingorani, Aroon D., Asselbergs, Folkert W., and Cardiovascular Centre (CVC)

Subjects
Adult, Male, Cardiac & Cardiovascular Systems, CARDIOVASCULAR MORTALITY, Coronary Disease, BIOBANK, Article, Sex Factors, Risk Factors, Journal Article, Humans, ARTERY-DISEASE, Cardiac and Cardiovascular Systems, genetics, Aged, Proportional Hazards Models, Genetics & Heredity, Kardiologi, Science & Technology, Smoking, Age Factors, Middle Aged, BODY-MASS INDEX, myocardial infarction, MYOCARDIAL-INFARCTION, PUBLIC-HEALTH, Cardiovascular System & Cardiology, Female, prognosis, Life Sciences & Biomedicine, coronary artery disease, secondary prevention
Abstract

BACKGROUND: The Genetics of Subsequent Coronary Heart Disease (GENIUS-CHD) consortium was established to facilitate discovery and validation of genetic variants and biomarkers for risk of subsequent CHD events, in individuals with established CHD. METHODS: The consortium currently includes 57 studies from 18 countries, recruiting 185 614 participants with either acute coronary syndrome, stable CHD, or a mixture of both at baseline. All studies collected biological samples and followed-up study participants prospectively for subsequent events. RESULTS: Enrollment into the individual studies took place between 1985 to present day with a duration of follow-up ranging from 9 months to 15 years. Within each study, participants with CHD are predominantly of self-reported European descent (38%-100%), mostly male (44%-91%) with mean ages at recruitment ranging from 40 to 75 years. Initial feasibility analyses, using a federated analysis approach, yielded expected associations between age (hazard ratio, 1.15; 95% CI, 1.14-1.16) per 5-year increase, male sex (hazard ratio, 1.17; 95% CI, 1.13-1.21) and smoking (hazard ratio, 1.43; 95% CI, 1.35-1.51) with risk of subsequent CHD death or myocardial infarction and differing associations with other individual and composite cardiovascular endpoints. CONCLUSIONS: GENIUS-CHD is a global collaboration seeking to elucidate genetic and nongenetic determinants of subsequent event risk in individuals with established CHD, to improve residual risk prediction and identify novel drug targets for secondary prevention. Initial analyses demonstrate the feasibility and reliability of a federated analysis approach. The consortium now plans to initiate and test novel hypotheses as well as supporting replication and validation analyses for other investigators. ispartof: CIRCULATION-GENOMIC AND PRECISION MEDICINE vol:12 issue:4 ispartof: location:United States status: published

Published
2019

9. Association of Chromosome 9p21 With Subsequent Coronary Heart Disease Events A GENIUS-CHD Study of Individual Participant Data

Author

Patel, R.S., Schmidt, A.F., Tragante, V., McCubrey, R.O., Holmes, M.V., Howe, L.J., Direk, K., Akerblom, A., Leander, K., Virani, S.S., Kaminski, K.A., Muehlschlegel, J.D., Dube, M.P., Allayee, H., Almgren, P., Alver, M., Baranova, E.V., Behlouli, H., Boeckx, B., Braund, P.S., Breitling, L.P., Delgado, G., Duarte, N.E., Dufresne, L., Eriksson, N., Foco, L., Gijsberts, C.M., Gong, Y., Hartiala, J., Heydarpour, M., Hubacek, J.A., Kleber, M., Kofink, D., Kuukasjarvi, P., Lee, V.V., Leiherer, A., Lenzini, P.A., Levin, D., Lyytikainen, L.P., Martinelli, N., Mons, U., Nelson, C.P., Nikus, K., Pilbrow, A.P., Ploski, R., Sun, Y.V., Tanck, M.W.T., Tang, W.H.W., Trompet, S., Laan, S.W. van der, Setten, J. van, Vilmundarson, R.O., Anselmi, C.V., Vlachopoulou, E., Boerwinkle, E., Briguori, C., Carlquist, J.F., Carruthers, K.F., Casu, G., Deanfield, J., Deloukas, P., Dudbridge, F., Fitzpatrick, N., Gigante, B., James, S., Lokki, M.L., Lotufo, P.A., Marziliano, N., Mordi, I.R., Muhlestein, J.B., Cheh, C.N., Pitha, J., Saely, C.H., Samman-Tahhan, A., Sandesara, P.B., Teren, A., Timmis, A., Werf, F. van de, Wauters, E., Wilde, A.A.M., Ford, I., Stott, D.J., Algra, A., Andreassi, M.G., Ardissino, D., Arsenault, B.J., Ballantyne, C.M., Bergmeijer, T.O., Bezzina, C.R., Body, S.C., Bogaty, P., Borst, G.J. de, Brenner, H., Burkhardt, R., Carpeggiani, C., Condorelli, G., Cooper-DeHoff, R.M., Cresci, S., Faire, U. de, Doughty, R.N., Drexel, H., Engert, J.C., Fox, K.A.A., Girelli, D., Hagstrom, E., Hazen, S.L., Held, C., Hemingway, H., Hoefer, I.E., Hovingh, G.K., Johnson, J.A., Jong, P.A. de, Jukema, J.W., Kaczor, M.P., Kahonen, M., Kettner, J., Kiliszek, M., Klungel, O.H., Lagerqvist, B., Lambrechts, D., Laurikka, J.O., Lehtimaki, T., Lindholm, D., Mahmoodi, B.K., Maitland-van der Zee, A.H., McPherson, R., Melander, O., Metspalu, A., Pepinski, W., Olivieri, O., Opolski, G., Palmer, C.N., Pasterkamp, G., Pepine, C.J., Pereira, A.C., Note, L., Quyyumi, A.A., Richards, A.M., Sanak, M., Scholz, M., Siegbahn, A., Sinisalo, J., Smith, J.G., Spertus, J.A., Stewart, A.F.R., Szczeklik, W., Szpakowicz, A., Berg, J.M. ten, Thanassoulis, G., Thieiy, J., Graaf, Y. van der, Visseren, F.L.J., Waltenberger, J., Harst, P. van der, Tardif, J.C., Sattar, N., Lang, C.C., Pare, G., Brophy, J.M., Anderson, J.L., Marz, W., Wallentin, L., Cameron, V.A., Horne, B.D., Samani, N.J., Hingorani, A.D., Asselbergs, F.W., and CARDIo-GRAMPlusC4D Consortium

Subjects
myocardial infarction, risk factor, cardiovascular diseases, chromosome, genetic, variation, secondary prevention
Abstract

BACKGROUND: Genetic variation at chromosome 9p21 is a recognized risk factor for coronary heart disease (CHD). However, its effect on disease progression and subsequent events is unclear, raising questions about its value for stratification of residual risk.METHODS: A variant at chromosome 9p21 (rs1333049) was tested for association with subsequent events during follow-up in 103 357 Europeans with established CHD at baseline from the GENIUS-CHD (Genetics of Subsequent Coronary Heart Disease) Consortium (73.1% male, mean age 62.9 years). The primary outcome, subsequent CHD death or myocardial infarction (CHD death/myocardial infarction), occurred in 13 040 of the 93 115 participants with available outcome data. Effect estimates were compared with case/control risk obtained from the CARDIoGRAMplusC4D consortium (Coronary Artery Disease Genome-wide Replication and Meta-analysis [CARDIoGRAM] plus The Coronary Artery Disease [C4D] Genetics) including 47 222 CHD cases and 122 264 controls free of CHD.RESULTS: Meta-analyses revealed no significant association between chromosome 9p21 and the primary outcome of CHD death/myocardial infarction among those with established CHD at baseline (GENIUSCHD odds ratio, 1.02; 95% CI, 0.99-1.05). This contrasted with a strong association in CARDIoGRAMPlusC4D odds ratio 1.20; 95% CI, 1.18-1.22; P for interaction < 0.001 compared with the GENIUS-CHD estimate. Similarly, no clear associations were identified for additional subsequent outcomes, including all-cause death, although we found a modest positive association between chromosome 9p21 and subsequent revascularization (odds ratio, 1.07; 95% CI, 1.04-1.09).CONCLUSIONS: In contrast to studies comparing individuals with CHD to disease-free controls, we found no clear association between genetic variation at chromosome 9p21 and risk of subsequent acute CHD events when all individuals had CHD at baseline. However, the association with subsequent revascularization may support the postulated mechanism of chromosome 9p21 for promoting atheroma development.

Published
2019

10. Subsequent Event Risk in Individuals With Established Coronary Heart Disease

Author

Patel, R.S. (Riyaz), Tragante, V. (Vinicius), Schmidt, A.F. (Amand), McCubrey, R.O. (Raymond O.), Holmes, M.V. (Michael), Howe, L.J. (Laurence J.), Direk, K. (Kenan), Åkerblom, A. (Axel), Leander, K. (Karin), Virani, S.S. (Salim), Kaminski, K.A. (Karol A.), Muehlschlegel, J.D. (Jochen), Allayee, H. (Hooman), Almgren, P. (Peter), Alver, M. (Maris), Baranova, E.V. (Ekaterina V.), Behloui, H. (Hassan), Boeckx, B. (Bram), Braund, P.S. (Peter), Breitling, L.P. (Lutz), Delgado, G., Duarte, N.E. (Nubia E.), Dubé, G.P. (Gregory), Dufresne, L. (Line), Eriksson, N. (Niclas), Foco, L. (Luisa), Scholz, M. (Markus), Gijsberts, C.M. (Crystel M.), Glinge, C. (Charlotte), Gong, Y. (Yan), Hartiala, J. (Jaana), Heydarpour, M. (Mahyar), Hubacek, J.A. (Jaroslav A.), Kleber, M.E. (Marcus), Kofink, D. (Daniel), Kotti, S. (Salma), Kuukasjärvi, P. (Pekka), Lee, V.-V. (Vei-Vei), Leiherer, A. (Andreas), Lenzini, P.A. (Petra A.), Levin, D. (Daniel), Lyytikäinen, L.-P. (Leo-Pekka), Martinelli, N. (Nicola), Mons, U. (Ute), Nelson, C.P. (Christopher P.), Nikus, K. (Kjell), Pilbrow, A.P. (Anna P.), Ploski, R. (Rafal), Sun, Y.V. (Yan V.), Tanck, M.W.T. (Michael), Tang, W. (W.), Trompet, S. (Stella), van der Laan, S.W. (Sander W.), Setten, J. (Jessica) van, Vilmundarson, R.O. (Ragnar O.), Viviani Anselmi, C. (Chiara), Vlachopoulou, E. (Efthymia), Al Ali, L. (Lawien), Boerwinkle, E.A. (Eric), Briguori, C. (Carlo), Carlquist, J.F. (John), Carruthers, K.F. (Kathryn), Casu, G. (Gavino), Deanfield, J. (John), Deloukas, P. (Panos), Dudbridge, F. (Frank), Engstrøm, T. (Thomas), Fitzpatrick, N. (Natalie), Fox, K.M. (Kim), Gigante, B. (Bruna), James, S.K. (Stefan), Lokki, M.-L. (Marja-Liisa), Lotufo, P.A. (Paulo A.), Marziliano, N. (Nicola), Mordi, I.R. (Ify R.), Muhlestein, J.B. (Joseph), Newton-Cheh, C. (Christopher), Pitha, J. (Jan), Saely, C.H. (Christoph H.), Samman-Tahhan, A. (Ayman), Sandesara, P.B. (Pratik B.), Teren, A. (Andrej), Timmis, A. (Adam), Van de Werf, F. (Frans), Wilde, A.A.M. (Arthur), Ford, I. (Ian), Stott, D.J. (David. J.), Algra, A. (Ale), Andreassi, M.G. (Maria G.), Ardissino, D. (Diego), Arsenault, B.J. (Benoit J.), Ballantyne, C. (Christie), Bergmeijer, T.O. (Thomas O.), Bezzina, C.R. (Connie R.), Body, S.C. (Simon C.), Boersma, E.H. (Eric H.), Bogaty, P. (Peter), Bots, M.L. (Michiel), Brenner, H. (Hermann), Brugts, J.J. (Jasper), Burkhardt, R. (Ralph), Carpeggiani, C. (Clara), Condorelli, G. (Gianluigi), Cooper-Dehoff, R.M. (Rhonda), Cresci, S. (Sharon), Danchin, N. (Nicolas), Faire, U. (Ulf) de, Doughty, R.N. (Robert N.), Drexel, H. (Heinz), Engert, J.C. (James C.), Fox, K.A.A. (Keith), Girelli, D. (Domenico), Grobbee, D.E. (Diederick E.), Hagström, E. (Emil), Hazen, S.L. (Stanley), Held, C. (Claes), Hemingway, H., Hoefer, I.E. (Imo), Hovingh, G.K. (G Kees), Jabbari, R. (Reza), Johnson, J.A. (Jennifer ), Jukema, J.W. (Jan Wouter), Kaczor, M.P. (Marcin P.), Kähönen, M. (Mika), Kettner, J. (Jiri), Kiliszek, M. (Marek), Klungel, O.H. (Olaf), Lagerqvist, B. (Bo), Lambrechts, D. (Diether), Laurikka, J.O. (Jari O.), Lehtimäki, T. (Terho), Lindholm, D. (Daniel), Mahmoodi, B.K. (Bakhtawar K.), Maitland-van der Zee, A-H. (Anke-Hilse), McPherson, R. (Ruth), Melander, O. (Olle), Metspalu, A. (Andres), Niemcunowicz-Janica, A. (Anna), Olivieri, O. (Oliviero), Opolski, G. (Grzegorz), Palmer, C.N.A. (Colin), Pasterkamp, G. (Gerard), Pepine, C.J. (Carl), Pereira, A. (A.), Pilote, L. (Louise), Erdmann, J. (Jeanette), Richards, A.M. (A Mark), Sanak, M. (Marek), Siegbahn, A. (Agneta), Simon, T. (Tabassome), Sinisalo, J. (Juha), Smith, J.G. (J Gustav), Schwartz, S.M. (Stephen), Stender, S. (Steen), Stewart, A.F. (Alexandre F.), Szczeklik, W. (Wojciech), Szpakowicz, A. (Anna), Tardif, J.-C. (Jean-Claude), Berg, J.M. (Jurrien) ten, Tfelt-Hansen, J. (Jacob), Thanassoulis, G. (George), Thiery, J.P. (Joachim), Torp-Pedersen, C. (Christian Tobias), Graaf, Y. (Yolanda) van der, Visseren, F.L.J. (Frank), Waltenberger, J. (Johannes), Weeke, P.E. (Peter E.), Harst, P. (Pim) van der, Lang, C.C. (Chim C.), Sattar, N. (Naveed), Cameron, V.A. (Vicky A.), Anderson, J.L. (Jeffrey), Brophy, J.M. (James M.), Pare, G. (Guillame), Horne, B.D. (Benjamin), Ye, S. (Shu), Wallentin, L. (Lars), Wauters, E. (Els), Samani, N.J. (Nilesh), Hingorani, A. (Aroon), Asselbergs, F.W. (Folkert), Patel, R.S. (Riyaz), Tragante, V. (Vinicius), Schmidt, A.F. (Amand), McCubrey, R.O. (Raymond O.), Holmes, M.V. (Michael), Howe, L.J. (Laurence J.), Direk, K. (Kenan), Åkerblom, A. (Axel), Leander, K. (Karin), Virani, S.S. (Salim), Kaminski, K.A. (Karol A.), Muehlschlegel, J.D. (Jochen), Allayee, H. (Hooman), Almgren, P. (Peter), Alver, M. (Maris), Baranova, E.V. (Ekaterina V.), Behloui, H. (Hassan), Boeckx, B. (Bram), Braund, P.S. (Peter), Breitling, L.P. (Lutz), Delgado, G., Duarte, N.E. (Nubia E.), Dubé, G.P. (Gregory), Dufresne, L. (Line), Eriksson, N. (Niclas), Foco, L. (Luisa), Scholz, M. (Markus), Gijsberts, C.M. (Crystel M.), Glinge, C. (Charlotte), Gong, Y. (Yan), Hartiala, J. (Jaana), Heydarpour, M. (Mahyar), Hubacek, J.A. (Jaroslav A.), Kleber, M.E. (Marcus), Kofink, D. (Daniel), Kotti, S. (Salma), Kuukasjärvi, P. (Pekka), Lee, V.-V. (Vei-Vei), Leiherer, A. (Andreas), Lenzini, P.A. (Petra A.), Levin, D. (Daniel), Lyytikäinen, L.-P. (Leo-Pekka), Martinelli, N. (Nicola), Mons, U. (Ute), Nelson, C.P. (Christopher P.), Nikus, K. (Kjell), Pilbrow, A.P. (Anna P.), Ploski, R. (Rafal), Sun, Y.V. (Yan V.), Tanck, M.W.T. (Michael), Tang, W. (W.), Trompet, S. (Stella), van der Laan, S.W. (Sander W.), Setten, J. (Jessica) van, Vilmundarson, R.O. (Ragnar O.), Viviani Anselmi, C. (Chiara), Vlachopoulou, E. (Efthymia), Al Ali, L. (Lawien), Boerwinkle, E.A. (Eric), Briguori, C. (Carlo), Carlquist, J.F. (John), Carruthers, K.F. (Kathryn), Casu, G. (Gavino), Deanfield, J. (John), Deloukas, P. (Panos), Dudbridge, F. (Frank), Engstrøm, T. (Thomas), Fitzpatrick, N. (Natalie), Fox, K.M. (Kim), Gigante, B. (Bruna), James, S.K. (Stefan), Lokki, M.-L. (Marja-Liisa), Lotufo, P.A. (Paulo A.), Marziliano, N. (Nicola), Mordi, I.R. (Ify R.), Muhlestein, J.B. (Joseph), Newton-Cheh, C. (Christopher), Pitha, J. (Jan), Saely, C.H. (Christoph H.), Samman-Tahhan, A. (Ayman), Sandesara, P.B. (Pratik B.), Teren, A. (Andrej), Timmis, A. (Adam), Van de Werf, F. (Frans), Wilde, A.A.M. (Arthur), Ford, I. (Ian), Stott, D.J. (David. J.), Algra, A. (Ale), Andreassi, M.G. (Maria G.), Ardissino, D. (Diego), Arsenault, B.J. (Benoit J.), Ballantyne, C. (Christie), Bergmeijer, T.O. (Thomas O.), Bezzina, C.R. (Connie R.), Body, S.C. (Simon C.), Boersma, E.H. (Eric H.), Bogaty, P. (Peter), Bots, M.L. (Michiel), Brenner, H. (Hermann), Brugts, J.J. (Jasper), Burkhardt, R. (Ralph), Carpeggiani, C. (Clara), Condorelli, G. (Gianluigi), Cooper-Dehoff, R.M. (Rhonda), Cresci, S. (Sharon), Danchin, N. (Nicolas), Faire, U. (Ulf) de, Doughty, R.N. (Robert N.), Drexel, H. (Heinz), Engert, J.C. (James C.), Fox, K.A.A. (Keith), Girelli, D. (Domenico), Grobbee, D.E. (Diederick E.), Hagström, E. (Emil), Hazen, S.L. (Stanley), Held, C. (Claes), Hemingway, H., Hoefer, I.E. (Imo), Hovingh, G.K. (G Kees), Jabbari, R. (Reza), Johnson, J.A. (Jennifer ), Jukema, J.W. (Jan Wouter), Kaczor, M.P. (Marcin P.), Kähönen, M. (Mika), Kettner, J. (Jiri), Kiliszek, M. (Marek), Klungel, O.H. (Olaf), Lagerqvist, B. (Bo), Lambrechts, D. (Diether), Laurikka, J.O. (Jari O.), Lehtimäki, T. (Terho), Lindholm, D. (Daniel), Mahmoodi, B.K. (Bakhtawar K.), Maitland-van der Zee, A-H. (Anke-Hilse), McPherson, R. (Ruth), Melander, O. (Olle), Metspalu, A. (Andres), Niemcunowicz-Janica, A. (Anna), Olivieri, O. (Oliviero), Opolski, G. (Grzegorz), Palmer, C.N.A. (Colin), Pasterkamp, G. (Gerard), Pepine, C.J. (Carl), Pereira, A. (A.), Pilote, L. (Louise), Erdmann, J. (Jeanette), Richards, A.M. (A Mark), Sanak, M. (Marek), Siegbahn, A. (Agneta), Simon, T. (Tabassome), Sinisalo, J. (Juha), Smith, J.G. (J Gustav), Schwartz, S.M. (Stephen), Stender, S. (Steen), Stewart, A.F. (Alexandre F.), Szczeklik, W. (Wojciech), Szpakowicz, A. (Anna), Tardif, J.-C. (Jean-Claude), Berg, J.M. (Jurrien) ten, Tfelt-Hansen, J. (Jacob), Thanassoulis, G. (George), Thiery, J.P. (Joachim), Torp-Pedersen, C. (Christian Tobias), Graaf, Y. (Yolanda) van der, Visseren, F.L.J. (Frank), Waltenberger, J. (Johannes), Weeke, P.E. (Peter E.), Harst, P. (Pim) van der, Lang, C.C. (Chim C.), Sattar, N. (Naveed), Cameron, V.A. (Vicky A.), Anderson, J.L. (Jeffrey), Brophy, J.M. (James M.), Pare, G. (Guillame), Horne, B.D. (Benjamin), Ye, S. (Shu), Wallentin, L. (Lars), Wauters, E. (Els), Samani, N.J. (Nilesh), Hingorani, A. (Aroon), and Asselbergs, F.W. (Folkert)

Abstract

BACKGROUND: The Genetics of Subsequent Coronary Heart Disease (GENIUS-CHD) consortium was established to facilitate discovery and validation of genetic variants a

Published
2019
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14. Associations of kidney disease measures with mortality and end-stage renal disease in individuals with and without hypertension: a meta-analysis

Author

Mahmoodi, B.K., Matsushita, K., Woodward, M., Blankestijn, P.J., Cirillo, M., Ohkubo, T., Rossing, P., Sarnak, M.J., Stengel, B., Yamagishi, K., Yamashita, K., Zhang, L., Coresh, J., Jong, P.E. de, Astor, B.C., Wetzels, J.F., et al., Mahmoodi, B.K., Matsushita, K., Woodward, M., Blankestijn, P.J., Cirillo, M., Ohkubo, T., Rossing, P., Sarnak, M.J., Stengel, B., Yamagishi, K., Yamashita, K., Zhang, L., Coresh, J., Jong, P.E. de, Astor, B.C., Wetzels, J.F., and et al.

Abstract

Item does not contain fulltext, BACKGROUND: Hypertension is the most prevalent comorbidity in individuals with chronic kidney disease. However, whether the association of the kidney disease measures, estimated glomerular filtration rate (eGFR) and albuminuria, with mortality or end-stage renal disease (ESRD) differs by hypertensive status is unknown. METHODS: We did a meta-analysis of studies selected according to Chronic Kidney Disease Prognosis Consortium criteria. Data transfer and analyses were done between March, 2011, and June, 2012. We used Cox proportional hazards models to estimate the hazard ratios (HR) of mortality and ESRD associated with eGFR and albuminuria in individuals with and without hypertension. FINDINGS: We analysed data for 45 cohorts (25 general population, seven high-risk, and 13 chronic kidney disease) with 1,127,656 participants, 364,344 of whom had hypertension. Low eGFR and high albuminuria were associated with mortality irrespective of hypertensive status in the general population and high-risk cohorts. All-cause mortality risk was 1.1-1.2 times higher in individuals with hypertension than in those without hypertension at preserved eGFR. A steeper relative risk gradient in individuals without hypertension than in those with hypertension at eGFR range 45-75 mL/min per 1.73 m(2) led to much the same mortality risk at lower eGFR. With a reference eGFR of 95 mL/min per 1.73 m(2) in each group to explicitly assess interaction, adjusted HR for all-cause mortality at eGFR 45 mL/min per 1.73 m(2) was 1.77 (95% CI 1.57-1.99) in individuals without hypertension versus 1.24 (1.11-1.39) in those with hypertension (p for overall interaction=0.0003). Similarly, for albumin-creatinine ratio of 300 mg/g (vs 5 mg/g), HR was 2.30 (1.98-2.68) in individuals without hypertension versus 2.08 (1.84-2.35) in those with hypertension (p for overall interaction=0.019). We recorded much the same results for cardiovascular mortality. The associations of eGFR and albuminuria with ESRD, however, d

Published
2012

15. Age and association of kidney measures with mortality and end-stage renal disease

Author

Hallan, S.I., Matsushita, K., Sang, Y., Mahmoodi, B.K., Black, C., Ishani, A., Kleefstra, N., Naimark, D., Roderick, P., Tonelli, M., Wetzels, J.F.M., Astor, B.C., Gansevoort, R.T., Levin, A., Wen, C.P., Coresh, J., Chronic Kidney Disease Prognosis, C., Hallan, S.I., Matsushita, K., Sang, Y., Mahmoodi, B.K., Black, C., Ishani, A., Kleefstra, N., Naimark, D., Roderick, P., Tonelli, M., Wetzels, J.F.M., Astor, B.C., Gansevoort, R.T., Levin, A., Wen, C.P., Coresh, J., and Chronic Kidney Disease Prognosis, C.

Abstract

Item does not contain fulltext, CONTEXT: Chronic kidney disease (CKD) is prevalent in older individuals, but the risk implications of low estimated glomerular filtration rate (eGFR) and high albuminuria across the full age range are controversial. OBJECTIVE: To evaluate possible effect modification (interaction) by age of the association of eGFR and albuminuria with clinical risk, examining both relative and absolute risks. DESIGN, SETTING, AND PARTICIPANTS: Individual-level meta-analysis including 2,051,244 participants from 33 general population or high-risk (of vascular disease) cohorts and 13 CKD cohorts from Asia, Australasia, Europe, and North/South America, conducted in 1972-2011 with a mean follow-up time of 5.8 years (range, 0-31 years). MAIN OUTCOME MEASURES: Hazard ratios (HRs) of mortality and end-stage renal disease (ESRD) according to eGFR and albuminuria were meta-analyzed across age categories after adjusting for sex, race, cardiovascular disease, diabetes, systolic blood pressure, cholesterol, body mass index, and smoking. Absolute risks were estimated using HRs and average incidence rates. RESULTS: Mortality (112,325 deaths) and ESRD (8411 events) risks were higher at lower eGFR and higher albuminuria in every age category. In general and high-risk cohorts, relative mortality risk for reduced eGFR decreased with increasing age; eg, adjusted HRs at an eGFR of 45 mL/min/1.73 m2 vs 80 mL/min/1.73 m2 were 3.50 (95% CI, 2.55-4.81), 2.21 (95% CI, 2.02-2.41), 1.59 (95% CI, 1.42-1.77), and 1.35 (95% CI, 1.23-1.48) in age categories 18-54, 55-64, 65-74, and >/=75 years, respectively (P <.05 for age interaction). Absolute risk differences for the same comparisons were higher at older age (9.0 [95% CI, 6.0-12.8], 12.2 [95% CI, 10.3-14.3], 13.3 [95% CI, 9.0-18.6], and 27.2 [95% CI, 13.5-45.5] excess deaths per 1000 person-years, respectively). For increased albuminuria, reduction of relative risk with increasing age was less evident, while differences in absolute risk were higher in older ag

Published
2012

16. Comparison of risk prediction using the CKD-EPI equation and the MDRD study equation for estimated glomerular filtration rate.

Author

Matsushita, K., Mahmoodi, B.K., Woodward, M., Emberson, J.R., Jafar, T.H., Jee, S.H., Polkinghorne, K.R., Shankar, A., Smith, D.H., Tonelli, M., Warnock, D.G., Wen, C.P., Coresh, J., Gansevoort, R.T., Hemmelgarn, B.R., Levey, A.S., Wetzels, J.F., et al., Matsushita, K., Mahmoodi, B.K., Woodward, M., Emberson, J.R., Jafar, T.H., Jee, S.H., Polkinghorne, K.R., Shankar, A., Smith, D.H., Tonelli, M., Warnock, D.G., Wen, C.P., Coresh, J., Gansevoort, R.T., Hemmelgarn, B.R., Levey, A.S., Wetzels, J.F., and et al.

Abstract

Item does not contain fulltext, CONTEXT: The Chronic Kidney Disease Epidemiology Collaboration (CKD-EPI) equation more accurately estimates glomerular filtration rate (GFR) than the Modification of Diet in Renal Disease (MDRD) Study equation using the same variables, especially at higher GFR, but definitive evidence of its risk implications in diverse settings is lacking. OBJECTIVE: To evaluate risk implications of estimated GFR using the CKD-EPI equation compared with the MDRD Study equation in populations with a broad range of demographic and clinical characteristics. DESIGN, SETTING, AND PARTICIPANTS: A meta-analysis of data from 1.1 million adults (aged >/= 18 years) from 25 general population cohorts, 7 high-risk cohorts (of vascular disease), and 13 CKD cohorts. Data transfer and analyses were conducted between March 2011 and March 2012. MAIN OUTCOME MEASURES: All-cause mortality (84,482 deaths from 40 cohorts), cardiovascular mortality (22,176 events from 28 cohorts), and end-stage renal disease (ESRD) (7644 events from 21 cohorts) during 9.4 million person-years of follow-up; the median of mean follow-up time across cohorts was 7.4 years (interquartile range, 4.2-10.5 years). RESULTS: Estimated GFR was classified into 6 categories (>/=90, 60-89, 45-59, 30-44, 15-29, and <15 mL/min/1.73 m(2)) by both equations. Compared with the MDRD Study equation, 24.4% and 0.6% of participants from general population cohorts were reclassified to a higher and lower estimated GFR category, respectively, by the CKD-EPI equation, and the prevalence of CKD stages 3 to 5 (estimated GFR <60 mL/min/1.73 m(2)) was reduced from 8.7% to 6.3%. In estimated GFR of 45 to 59 mL/min/1.73 m(2) by the MDRD Study equation, 34.7% of participants were reclassified to estimated GFR of 60 to 89 mL/min/1.73 m(2) by the CKD-EPI equation and had lower incidence rates (per 1000 person-years) for the outcomes of interest (9.9 vs 34.5 for all-cause mortality, 2.7 vs 13.0 for cardiovascular mortality, and 0.5 vs 0.8 for ESRD) compare

Published
2012

17. Comparison of risk prediction using the CKD-EPI equation and the MDRD study equation for estimated glomerular filtration rate.

Author

Gansevoort R.T., Polkinghorne K.R., Coresh J., Hemmelgarn B.R., Levey A.S., Matsushita K., Mahmoodi B.K., Woodward M., Emberson J.R., Jafar T.H., Jee S.H., Shankar A., Smith D.H., Tonelli M., Warnock D.G., Wen C.-P., Gansevoort R.T., Polkinghorne K.R., Coresh J., Hemmelgarn B.R., Levey A.S., Matsushita K., Mahmoodi B.K., Woodward M., Emberson J.R., Jafar T.H., Jee S.H., Shankar A., Smith D.H., Tonelli M., Warnock D.G., and Wen C.-P.

Abstract

Context: The Chronic Kidney Disease Epidemiology Collaboration (CKD-EPI) equation more accurately estimates glomerular filtration rate (GFR) than the Modification of Diet in Renal Disease (MDRD) Study equation using the same variables, especially at higher GFR, but definitive evidence of its risk implications in diverse settings is lacking. Objective(s): To evaluate risk implications of estimated GFR using the CKD-EPI equation compared with the MDRD Study equation in populations with a broad range of demographic and clinical characteristics. Design, Setting, and Participant(s): A meta-analysis of data from 1.1 million adults (aged >=18 years) from 25 general population cohorts, 7 high-risk cohorts (of vascular disease), and 13 CKD cohorts. Data transfer and analyses were conducted between March 2011 and March 2012. Main Outcome Measure(s): All-cause mortality (84 482 deaths from 40 cohorts), cardiovascular mortality (22 176 events from 28 cohorts), and end-stage renal disease (ESRD) (7644 events from 21 cohorts) during 9.4 million person-years of follow-up; the median of mean follow-up time across cohorts was 7.4 years (interquartile range, 4.2-10.5 years). Result(s): Estimated GFR was classified into 6 categories (>=90, 60-89, 45-59, 30-44, 15- 29, and <15 mL/min/1.73m2) by both equations. Compared with theMDRDStudy equation, 24.4% and 0.6% of participants from general population cohorts were reclassified to a higher and lower estimated GFR category, respectively, by the CKD-EPI equation, and the prevalence of CKD stages 3 to 5 (estimated GFR <60 mL/min/1.73 m2) was reduced from 8.7% to 6.3%. In estimated GFR of 45 to 59 mL/min/1.73 m 2 by the MDRD Study equation, 34.7% of participants were reclassified to estimated GFR of 60 to 89 mL/min/1.73 m2 by the CKD-EPI equation and had lower incidence rates (per 1000 person years) for the outcomes of interest (9.9 vs 34.5 for all-cause mortality, 2.7 vs 13.0 for cardiovascular mortality, and 0.5 vs 0.8 for ESRD) compared w

Published
2012

18. High absolute risks and predictors of venous and arterial thromboembolic events in patients with nephrotic syndrome: results from a large retrospective cohort study.

Author

Mahmoodi, B.K., Kate, M.K. ten, Waanders, F., Veeger, N.J., Brouwer, J.L.P., Vogt, L., Navis, G., Meer, J.W.M. van der, Mahmoodi, B.K., Kate, M.K. ten, Waanders, F., Veeger, N.J., Brouwer, J.L.P., Vogt, L., Navis, G., and Meer, J.W.M. van der

Abstract

Contains fulltext : 70031.pdf (publisher's version ) (Closed access), BACKGROUND: No data are available on the absolute risk of either venous thromboembolism (VTE) or arterial thromboembolism (ATE) in patients with nephrotic syndrome. Reported risks are based on multiple case reports and small studies with mostly short-term follow-up. We assessed the absolute risk of VTE and ATE in a large, single-center, retrospective cohort study and attempted to identify predictive factors in these patients. METHODS AND RESULTS: A total of 298 consecutive patients with nephrotic syndrome (59% men; mean age, 42+/-18 years) were enrolled. Mean follow-up was 10+/-9 years. Nephrotic syndrome was defined by proteinuria > or =3.5 g/d, and patients were classified according to underlying histological lesions accounting for nephrotic syndrome. Objectively verified symptomatic thromboembolic events were the primary study outcome. Annual incidences of VTE and ATE were 1.02% (95% confidence interval, 0.68 to 1.46) and 1.48% (95% confidence interval, 1.07 to 1.99), respectively. Over the first 6 months of follow-up, these rates were 9.85% and 5.52%, respectively. Proteinuria and serum albumin levels tended to be related to VTE; however, only the predictive value of the ratio of proteinuria to serum albumin was significant (hazard ratio, 5.6; 95% confidence interval, 1.2 to 26.2; P=0.03). In contrast, neither the degree of proteinuria nor serum albumin levels were related to ATE. Sex, age, hypertension, diabetes, smoking, prior ATE, and estimated glomerular filtration rate predicted ATE (P< or =0.02). CONCLUSIONS: This study verifies high absolute risks of symptomatic VTE and ATE that were remarkably elevated within the first 6 months. Whereas the ratio of proteinuria to serum albumin predicted VTE, estimated glomerular filtration rate and multiple classic risk factors for atherosclerosis were predictors of ATE.

Published
2008

19. Hereditary deficiency of protein C or protein S confers increased risk of arterial thromboembolic events at a young age: results from a large family cohort study.

Author

Mahmoodi, B.K., Brouwer, J.L.P., Veeger, N.J., Meer, J.W.M. van der, Mahmoodi, B.K., Brouwer, J.L.P., Veeger, N.J., and Meer, J.W.M. van der

Abstract

Contains fulltext : 70054.pdf (publisher's version ) (Closed access), BACKGROUND: Whether hereditary protein S, protein C, or antithrombin deficiency is associated with arterial thromboembolism (ATE) and whether history of venous thromboembolism in these subjects predisposes them to subsequent ATE have yet to be determined. METHODS AND RESULTS: On the basis of pedigree analysis, we enrolled a total of 552 subjects (52% women; mean age, 46+/-17 years), belonging to 84 different kindreds, in this retrospective family cohort study. Detailed information on previous episodes of venous thromboembolism, ATE, anticoagulant use, and atherosclerosis risk factors was collected. Primary study outcome was objectively verified symptomatic ATE. Of 552 subjects, 308 had protein S (35%), protein C (39%), or antithrombin (26%) deficiency. Overall, annual incidences of ATE were 0.34% (95% confidence interval [CI], 0.23 to 0.49) in deficient versus 0.17% (95% CI, 0.09 to 0.28) in nondeficient subjects; the hazard ratio was 2.3 (95% CI, 1.2 to 4.5). Because the risk hazards varied over lifetime, we performed a time-dependent analysis. After adjusting for atherosclerosis risk factors and clustering within families, we found that deficient subjects had a 4.7-fold (95% CI, 1.5 to 14.2; P=0.007) higher risk for ATE before 55 years of age versus 1.1 (95% CI, 0.5 to 2.6) thereafter compared with nondeficient family members. For separate deficiencies, the risks were 4.6- (95% CI, 1.1 to 18.3), 6.9- (95% CI, 2.1 to 22.2), and 1.1- (95% CI, 0.1 to 10.9) fold higher in protein S-, protein C-, and antithrombin-deficient subjects, respectively, before 55 years of age. History of venous thromboembolism was not related to subsequent ATE (hazard ratio, 1.1; 95% CI, 0.5 to 2.2). CONCLUSIONS: Compared with nondeficient family members, subjects with protein S or protein C deficiency but not antithrombin deficiency have a higher risk for ATE before 55 years of age that is independent of prior venous thromboembolism.

Published
2008

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