Your search keyword '"Teare, Harriet J A"' showing total 27 results

1. Dynamic Consent : An Evaluation and Reporting Framework

Author

Prictor, Megan, Lewis, Megan A., Newson, Ainsley J., Haas, Matilda, Baba, Sachiko, Kim, Hannah, Kokado, Minori, Minari, Jusaku, Molnár-Gábor, Fruzsina, Yamamoto, Beverley, Kaye, Jane, and Teare, Harriet J. A.

Published

2020

2. Reflections on dynamic consent in biomedical research: the story so far

Author

Teare, Harriet J. A., Prictor, Megan, and Kaye, Jane

Published

2021

3. Discovery of biomarkers for glycaemic deterioration before and after the onset of type 2 diabetes: descriptive characteristics of the epidemiological studies within the IMI DIRECT Consortium

Author

Koivula, Robert W., Forgie, Ian M., Kurbasic, Azra, Viñuela, Ana, Heggie, Alison, Giordano, Giuseppe N., Hansen, Tue H., Hudson, Michelle, Koopman, Anitra D. M., Rutters, Femke, Siloaho, Maritta, Allin, Kristine H., Brage, Søren, Brorsson, Caroline A., Dawed, Adem Y., De Masi, Federico, Groves, Christopher J., Kokkola, Tarja, Mahajan, Anubha, Perry, Mandy H., Rauh, Simone P., Ridderstråle, Martin, Teare, Harriet J. A., Thomas, E. Louise, Tura, Andrea, Vestergaard, Henrik, White, Tom, Adamski, Jerzy, Bell, Jimmy D., Beulens, Joline W., Brunak, Søren, Dermitzakis, Emmanouil T., Froguel, Philippe, Frost, Gary, Gupta, Ramneek, Hansen, Torben, Hattersley, Andrew, Jablonka, Bernd, Kaye, Jane, Laakso, Markku, McDonald, Timothy J., Pedersen, Oluf, Schwenk, Jochen M., Pavo, Imre, Mari, Andrea, McCarthy, Mark I., Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, Franks, Paul W., and for the IMI DIRECT Consortium

Published

2019

4. The governance structure for data access in the DIRECT consortium: an innovative medicines initiative (IMI) project

Author

Teare, Harriet J. A., de Masi, Federico, Banasik, Karina, Barnett, Anna, Herrgard, Sanna, Jablonka, Bernd, Postma, Jacqueline W. M., McDonald, Timothy J., Forgie, Ian, Chmura, Piotr J., Rydzka, Emil K., Gupta, Ramneek, Brunak, Soren, Pearson, Ewan, and Kaye, Jane

Published

2018

5. Discovery of biomarkers for glycaemic deterioration before and after the onset of type 2 diabetes: rationale and design of the epidemiological studies within the IMI DIRECT Consortium

Author

Koivula, Robert W., Heggie, Alison, Barnett, Anna, Cederberg, Henna, Hansen, Tue H., Koopman, Anitra D., Ridderstråle, Martin, Rutters, Femke, Vestergaard, Henrik, Gupta, Ramneek, Herrgård, Sanna, Heymans, Martijn W., Perry, Mandy H., Rauh, Simone, Siloaho, Maritta, Teare, Harriet J. A., Thorand, Barbara, Bell, Jimmy, Brunak, Søren, Frost, Gary, Jablonka, Bernd, Mari, Andrea, McDonald, Tim J., Dekker, Jacqueline M., Hansen, Torben, Hattersley, Andrew, Laakso, Markku, Pedersen, Oluf, Koivisto, Veikko, Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, Franks, Paul W., and for the DIRECT Consortium

Published

2014

6. Correction to: The role of physical activity in metabolic homeostasis before and after the onset of type 2 diabetes: an IMI DIRECT study (Diabetologia, (2020), 63, 4, (744-756), 10.1007/s00125-019-05083-6)

Author

Koivula, Robert W., Atabaki-Pasdar, Naeimeh, Giordano, Giuseppe N., White, Tom, Adamski, Jerzy, Bell, Jimmy D., Beulens, Joline, Brage, S. ren, Brunak, S. ren, de Masi, Federico, Dermitzakis, Emmanouil T., Forgie, Ian M., Frost, Gary, Hansen, Torben, Hansen, Tue H., Hattersley, Andrew, Kokkola, Tarja, Kurbasic, Azra, Laakso, Markku, Mari, Andrea, McDonald, Timothy J., Pedersen, Oluf, Rutters, Femke, Schwenk, Jochen M., Teare, Harriet J. A., Thomas, E. Louise, Vinuela, Ana, Mahajan, Anubha, McCarthy, Mark I., Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, Pavo, Imre, Franks, Paul W., Epidemiology and Data Science, ACS - Diabetes & metabolism, APH - Health Behaviors & Chronic Diseases, APH - Aging & Later Life, and ACS - Heart failure & arrhythmias

Abstract

Unfortunately, ‘Present address’ was omitted from one of the addresses provided for Mark I. McCarthy (#26). The corrected address details are given on the following page.

Published

2021

7. The role of physical activity in metabolic homeostasis before and after the onset of type 2 diabetes:an IMI DIRECT study

Author

Koivula, Robert W, Atabaki-Pasdar, Naeimeh, Giordano, Giuseppe N, White, Tom, Adamski, Jerzy, Bell, Jimmy D, Beulens, Joline, Brage, Søren, Brunak, Søren, De Masi, Federico, Dermitzakis, Emmanouil T, Forgie, Ian M, Frost, Gary, Hansen, Torben, Hansen, Tue H, Hattersley, Andrew, Kokkola, Tarja, Kurbasic, Azra, Laakso, Markku, Mari, Andrea, McDonald, Timothy J, Pedersen, Oluf, Rutters, Femke, Schwenk, Jochen M, Teare, Harriet J A, Thomas, E Louise, Vinuela, Ana, Mahajan, Anubha, McCarthy, Mark I, Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, Pavo, Imre, Franks, Paul W, Koivula, Robert W, Atabaki-Pasdar, Naeimeh, Giordano, Giuseppe N, White, Tom, Adamski, Jerzy, Bell, Jimmy D, Beulens, Joline, Brage, Søren, Brunak, Søren, De Masi, Federico, Dermitzakis, Emmanouil T, Forgie, Ian M, Frost, Gary, Hansen, Torben, Hansen, Tue H, Hattersley, Andrew, Kokkola, Tarja, Kurbasic, Azra, Laakso, Markku, Mari, Andrea, McDonald, Timothy J, Pedersen, Oluf, Rutters, Femke, Schwenk, Jochen M, Teare, Harriet J A, Thomas, E Louise, Vinuela, Ana, Mahajan, Anubha, McCarthy, Mark I, Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, Pavo, Imre, and Franks, Paul W

Abstract

AIMS/HYPOTHESIS: It is well established that physical activity, abdominal ectopic fat and glycaemic regulation are related but the underlying structure of these relationships is unclear. The previously proposed twin-cycle hypothesis (TC) provides a mechanistic basis for impairment in glycaemic control through the interactions of substrate availability, substrate metabolism and abdominal ectopic fat accumulation. Here, we hypothesise that the effect of physical activity in glucose regulation is mediated by the twin-cycle. We aimed to examine this notion in the Innovative Medicines Initiative Diabetes Research on Patient Stratification (IMI DIRECT) Consortium cohorts comprised of participants with normal or impaired glucose regulation (cohort 1: N ≤ 920) or with recently diagnosed type 2 diabetes (cohort 2: N ≤ 435).METHODS: We defined a structural equation model that describes the TC and fitted this within the IMI DIRECT dataset. A second model, twin-cycle plus physical activity (TC-PA), to assess the extent to which the effects of physical activity in glycaemic regulation are mediated by components in the twin-cycle, was also fitted. Beta cell function, insulin sensitivity and glycaemic control were modelled from frequently sampled 75 g OGTTs (fsOGTTs) and mixed-meal tolerance tests (MMTTs) in participants without and with diabetes, respectively. Abdominal fat distribution was assessed using MRI, and physical activity through wrist-worn triaxial accelerometry. Results are presented as standardised beta coefficients, SE and p values, respectively.RESULTS: The TC and TC-PA models showed better fit than null models (TC: χ2 = 242, p = 0.004 and χ2 = 63, p = 0.001 in cohort 1 and 2, respectively; TC-PA: χ2 = 180, p = 0.041 and χ2 = 60, p = 0.008 in cohort 1 and 2, respectively). The association of physical activity with glycaemic control was primarily mediated by variables in the liver fat cycle.CONCLUSIONS/INTERPRETATION: These analyses partially

Published

2020

8. Reflections on dynamic consent in biomedical research: the story so far

Author

Teare, Harriet J. A., primary, Prictor, Megan, additional, and Kaye, Jane, additional

Published

2020

9. Discovery of biomarkers for glycaemic deterioration before and after the onset of type 2 diabetes:descriptive characteristics of the epidemiological studies within the IMI DIRECT Consortium

Author

Koivula, Robert W, Forgie, Ian M, Kurbasic, Azra, Viñuela, Ana, Heggie, Alison, Giordano, Giuseppe N, Hansen, Tue H., Hudson, Michelle, Koopman, Anitra D M, Rutters, Femke, Siloaho, Maritta, Allin, Kristine H., Brage, Søren, Brorsson, Caroline A, Dawed, Adem Y, De Masi, Federico, Groves, Christopher J, Kokkola, Tarja, Mahajan, Anubha, Perry, Mandy H, Rauh, Simone P, Ridderstråle, Martin, Teare, Harriet J A, Thomas, E Louise, Tura, Andrea, Vestergaard, Henrik, White, Tom, Adamski, Jerzy, Bell, Jimmy D, Beulens, Joline W, Brunak, Søren, Dermitzakis, Emmanouil T, Froguel, Philippe, Frost, Gary, Gupta, Ramneek, Hansen, Torben, Hattersley, Andrew, Jablonka, Bernd, Kaye, Jane, Laakso, Markku, McDonald, Timothy J, Pedersen, Oluf, Schwenk, Jochen M, Pavo, Imre, Mari, Andrea, McCarthy, Mark I, Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, Franks, Paul W, Koivula, Robert W, Forgie, Ian M, Kurbasic, Azra, Viñuela, Ana, Heggie, Alison, Giordano, Giuseppe N, Hansen, Tue H., Hudson, Michelle, Koopman, Anitra D M, Rutters, Femke, Siloaho, Maritta, Allin, Kristine H., Brage, Søren, Brorsson, Caroline A, Dawed, Adem Y, De Masi, Federico, Groves, Christopher J, Kokkola, Tarja, Mahajan, Anubha, Perry, Mandy H, Rauh, Simone P, Ridderstråle, Martin, Teare, Harriet J A, Thomas, E Louise, Tura, Andrea, Vestergaard, Henrik, White, Tom, Adamski, Jerzy, Bell, Jimmy D, Beulens, Joline W, Brunak, Søren, Dermitzakis, Emmanouil T, Froguel, Philippe, Frost, Gary, Gupta, Ramneek, Hansen, Torben, Hattersley, Andrew, Jablonka, Bernd, Kaye, Jane, Laakso, Markku, McDonald, Timothy J, Pedersen, Oluf, Schwenk, Jochen M, Pavo, Imre, Mari, Andrea, McCarthy, Mark I, Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, and Franks, Paul W

Abstract

AIMS/HYPOTHESIS: Here, we describe the characteristics of the Innovative Medicines Initiative (IMI) Diabetes Research on Patient Stratification (DIRECT) epidemiological cohorts at baseline and follow-up examinations (18, 36 and 48 months of follow-up).METHODS: From a sampling frame of 24,682 adults of European ancestry enrolled in population-based cohorts across Europe, participants at varying risk of glycaemic deterioration were identified using a risk prediction algorithm (based on age, BMI, waist circumference, use of antihypertensive medication, smoking status and parental history of type 2 diabetes) and enrolled into a prospective cohort study (n = 2127) (cohort 1, prediabetes risk). We also recruited people from clinical registries with type 2 diabetes diagnosed 6-24 months previously (n = 789) into a second cohort study (cohort 2, diabetes). Follow-up examinations took place at ~18 months (both cohorts) and at ~48 months (cohort 1) or ~36 months (cohort 2) after baseline examinations. The cohorts were studied in parallel using matched protocols across seven clinical centres in northern Europe.RESULTS: Using ADA 2011 glycaemic categories, 33% (n = 693) of cohort 1 (prediabetes risk) had normal glucose regulation and 67% (n = 1419) had impaired glucose regulation. Seventy-six per cent of participants in cohort 1 was male. Cohort 1 participants had the following characteristics (mean ± SD) at baseline: age 62 (6.2) years; BMI 27.9 (4.0) kg/m2; fasting glucose 5.7 (0.6) mmol/l; 2 h glucose 5.9 (1.6) mmol/l. At the final follow-up examination the participants' clinical characteristics were as follows: fasting glucose 6.0 (0.6) mmol/l; 2 h OGTT glucose 6.5 (2.0) mmol/l. In cohort 2 (diabetes), 66% (n = 517) were treated by lifestyle modification and 34% (n = 272) were treated with metformin plus lifestyle modification at enrolment. Fifty-eight per cent of participants in cohort 2 was male. Cohort 2 participants had the following characteristics at

Published

2019

10. Dynamic Consent: An Evaluation and Reporting Framework

Author

Prictor, Megan, primary, Lewis, Megan A., additional, Newson, Ainsley J., additional, Haas, Matilda, additional, Baba, Sachiko, additional, Kim, Hannah, additional, Kokado, Minori, additional, Minari, Jusaku, additional, Molnár-Gábor, Fruzsina, additional, Yamamoto, Beverley, additional, Kaye, Jane, additional, and Teare, Harriet J. A., additional

Published

2019

11. The governance structure for data access in the DIRECT consortium:an innovative medicines initiative (IMI) project

Author

Teare, Harriet J A, de Masi, Federico, Banasik, Karina, Barnett, Anna, Herrgard, Sanna, Jablonka, Bernd, Postma, Jacqueline W M, McDonald, Timothy J, Forgie, Ian, Chmura, Piotr J, Rydzka, Emil K, Gupta, Ramneek, Brunak, Søren, Pearson, Ewan, Kaye, Jane, Teare, Harriet J A, de Masi, Federico, Banasik, Karina, Barnett, Anna, Herrgard, Sanna, Jablonka, Bernd, Postma, Jacqueline W M, McDonald, Timothy J, Forgie, Ian, Chmura, Piotr J, Rydzka, Emil K, Gupta, Ramneek, Brunak, Søren, Pearson, Ewan, and Kaye, Jane

Abstract

Biomedical research projects involving multiple partners from public and private sectors require coherent internal governance mechanisms to engender good working relationships. The DIRECT project is an example of such a venture, funded by the Innovative Medicines Initiative Joint Undertaking (IMI JU). This paper describes the data access policy that was developed within DIRECT to support data access and sharing, via the establishment of a 3-tiered Data Access Committee. The process was intended to allow quick access to data, whilst enabling strong oversight of how data were being accessed and by whom, and any subsequent analyses, to contribute to the overall objectives of the consortium.

Published

2018

12. The RUDY Study: Using digital technologies to enable a research partnership

Author

Teare, Harriet J A, Hogg, Joanna, Kaye, Jane, Luqmani, Raashid, Rush, Elaine, Turner, Alison, Watts, Laura, Williams, Melanie, and Javaid, M Kassim

Subjects

Humans, Musculoskeletal Diseases, Professional-Patient Relations, Vascular Diseases, Cooperative Behavior, Patient Participation, Article, Software

Abstract

Patients have extensive experience of their disease that can enhance the design and execution of research leading to significant innovations and efficiencies in the research process. The research community on the whole have been slow to adopt practices that enable patients to become active partners in research. Digital technologies are providing the means to do this more easily and so are increasingly being used to interact with patients and involve them in the design and execution of research. The RUDY (Rare UK Diseases of bone, joints and blood vessels) Study’s pioneering approach applies a custom-developed electronic platform where patients can contribute information over time about their disease experience, lifestyle and clinical history. This is combined with a state-of-the-art Dynamic Consent model and a commitment to patient-driven research, to further our understanding of rare diseases. This paper describes the RUDY Study and the benefits that have been gained from adopting this partnership approach to research.

Published

2017

13. Equitable Participation in Biobanks: The Risks and Benefits of a “Dynamic Consent” Approach

Author

Prictor, Megan, primary, Teare, Harriet J. A., additional, and Kaye, Jane, additional

Published

2018

14. Dynamic Consent : a potential solution to some of the challenges of modern biomedical research

Author

Budin-Ljosne, Isabelle, Teare, Harriet J. A., Kaye, Jane, Beck, Stephan, Bentzen, Heidi Beate, Caenazzo, Luciana, Collett, Clive, D'Abramo, Flavio, Felzmann, Heike, Finlay, Teresa, Javaid, Muhammad Kassim, Jones, Erica, Katic, Visnja, Simpson, Amy, Mascalzoni, Deborah, Budin-Ljosne, Isabelle, Teare, Harriet J. A., Kaye, Jane, Beck, Stephan, Bentzen, Heidi Beate, Caenazzo, Luciana, Collett, Clive, D'Abramo, Flavio, Felzmann, Heike, Finlay, Teresa, Javaid, Muhammad Kassim, Jones, Erica, Katic, Visnja, Simpson, Amy, and Mascalzoni, Deborah

Abstract

Background: Innovations in technology have contributed to rapid changes in the way that modern biomedical research is carried out. Researchers are increasingly required to endorse adaptive and flexible approaches to accommodate these innovations and comply with ethical, legal and regulatory requirements. This paper explores how Dynamic Consent may provide solutions to address challenges encountered when researchers invite individuals to participate in research and follow them up over time in a continuously changing environment. Methods: An interdisciplinary workshop jointly organised by the University of Oxford and the COST Action CHIP ME gathered clinicians, researchers, ethicists, lawyers, research participants and patient representatives to discuss experiences of using Dynamic Consent, and how such use may facilitate the conduct of specific research tasks. The data collected during the workshop were analysed using a content analysis approach. Results: Dynamic Consent can provide practical, sustainable and future-proof solutions to challenges related to participant recruitment, the attainment of informed consent, participant retention and consent management, and may bring economic efficiencies. Conclusions: Dynamic Consent offers opportunities for ongoing communication between researchers and research participants that can positively impact research. Dynamic Consent supports inter-sector, cross-border approaches and large scale data-sharing. Whilst it is relatively easy to set up and maintain, its implementation will require that researchers re-consider their relationship with research participants and adopt new procedures.

Published

2017

15. Dynamic Consent: a potential solution to some of the challenges of modern biomedical research

Author

Budin-Ljøsne, Isabelle, primary, Teare, Harriet J. A., additional, Kaye, Jane, additional, Beck, Stephan, additional, Bentzen, Heidi Beate, additional, Caenazzo, Luciana, additional, Collett, Clive, additional, D’Abramo, Flavio, additional, Felzmann, Heike, additional, Finlay, Teresa, additional, Javaid, Muhammad Kassim, additional, Jones, Erica, additional, Katić, Višnja, additional, Simpson, Amy, additional, and Mascalzoni, Deborah, additional

Published

2017

16. Consent for data processing under the General Data Protection Regulation: Could 'dynamic consent' be a useful tool for researchers?

Author

Prictor, Megan, Teare, Harriet J. A., Bell, Jessica, Taylor, Mark, and Kaye, Jane

Published

2019

17. Using digital technologies to engage with medical research: views of myotonic dystrophy patients in Japan

Author

Coathup, Victoria, primary, Teare, Harriet J. A., additional, Minari, Jusaku, additional, Yoshizawa, Go, additional, Kaye, Jane, additional, Takahashi, Masanori P., additional, and Kato, Kazuto, additional

Published

2016

18. Citizen science or scientific citizenship? Disentangling the uses of public engagement rhetoric in national research initiatives

Author

Woolley, J. Patrick, primary, McGowan, Michelle L., additional, Teare, Harriet J. A., additional, Coathup, Victoria, additional, Fishman, Jennifer R., additional, Settersten, Richard A., additional, Sterckx, Sigrid, additional, Kaye, Jane, additional, and Juengst, Eric T., additional

Published

2016

19. Discovery of biomarkers for glycaemic deterioration before and after the onset of type 2 diabetes: rationale and design of the epidemiological studies within the IMI DIRECT Consortium.

Author

Koivula, Robert, Heggie, Alison, Barnett, Anna, Cederberg, Henna, Hansen, Tue H, Koopman, Anitra D, Ridderstråle, Martin, Rutters, Femke, Vestergaard, Henrik, Gupta, Ramneek, Herrgård, Sanna, Heymans, Martijn W, Perry, Mandy H, Rauh, Simone, Siloaho, Maritta, Teare, Harriet J A, Thorand, Barbara, Bell, Jimmy, Brunak, Søren, Frost, Gary, Jablonka, Bernd, Mari, Andrea, McDonald, Tim J, Dekker, Jacqueline M, Hansen, Torben, Hattersley, Andrew, Laakso, Markku, Pedersen, Oluf, Koivisto, Veikko, Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, Franks, Paul, Koivula, Robert, Heggie, Alison, Barnett, Anna, Cederberg, Henna, Hansen, Tue H, Koopman, Anitra D, Ridderstråle, Martin, Rutters, Femke, Vestergaard, Henrik, Gupta, Ramneek, Herrgård, Sanna, Heymans, Martijn W, Perry, Mandy H, Rauh, Simone, Siloaho, Maritta, Teare, Harriet J A, Thorand, Barbara, Bell, Jimmy, Brunak, Søren, Frost, Gary, Jablonka, Bernd, Mari, Andrea, McDonald, Tim J, Dekker, Jacqueline M, Hansen, Torben, Hattersley, Andrew, Laakso, Markku, Pedersen, Oluf, Koivisto, Veikko, Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, and Franks, Paul

Abstract

The DIRECT (Diabetes Research on Patient Stratification) Study is part of a European Union Framework 7 Innovative Medicines Initiative project, a joint undertaking between four industry and 21 academic partners throughout Europe. The Consortium aims to discover and validate biomarkers that: (1) predict the rate of glycaemic deterioration before and after type 2 diabetes onset; (2) predict the response to diabetes therapies; and (3) help stratify type 2 diabetes into clearly definable disease subclasses that can be treated more effectively than without stratification. This paper describes two new prospective cohort studies conducted as part of DIRECT.

Published

2014

20. Towards 'Engagement 2.0': Insights from a study of dynamic consent with biobank participants.

Author

Teare, Harriet J. A., Morrison, Michael, Whitley, Edgar A., and Kaye, Jane

Published

2015

21. The role of physical activity in metabolic homeostasis before and after the onset of type 2 diabetes: an IMI DIRECT study

Author

Koivula, Robert W., Atabaki-Pasdar, Naeimeh, Giordano, Giuseppe N., White, Tom, Adamski, Jerzy, Bell, Jimmy D., Beulens, Joline, Brage, Søren, Brunak, Søren, De Masi, Federico, Dermitzakis, Emmanouil T., Forgie, Ian M., Frost, Gary, Hansen, Torben, Hansen, Tue H., Hattersley, Andrew, Kokkola, Tarja, Kurbasic, Azra, Laakso, Markku, Mari, Andrea, McDonald, Timothy J., Pedersen, Oluf, Rutters, Femke, Schwenk, Jochen M., Teare, Harriet J. A., Thomas, E. Louise, Vinuela, Ana, Mahajan, Anubha, McCarthy, Mark I., Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, Pavo, Imre, and Franks, Paul W.

Subjects

Physical activity, Structural equation modelling, Glycaemic control, Beta cell function, Type 2 diabetes, 16. Peace & justice, Insulin sensitivity, Prediabetes, Article, Ectopic fat, 3. Good health

Abstract

Aims/hypothesis: It is well established that physical activity, abdominal ectopic fat and glycaemic regulation are related but the underlying structure of these relationships is unclear. The previously proposed twin-cycle hypothesis (TC) provides a mechanistic basis for impairment in glycaemic control through the interactions of substrate availability, substrate metabolism and abdominal ectopic fat accumulation. Here, we hypothesise that the effect of physical activity in glucose regulation is mediated by the twin-cycle. We aimed to examine this notion in the Innovative Medicines Initiative Diabetes Research on Patient Stratification (IMI DIRECT) Consortium cohorts comprised of participants with normal or impaired glucose regulation (cohort 1: N ≤ 920) or with recently diagnosed type 2 diabetes (cohort 2: N ≤ 435). Methods: We defined a structural equation model that describes the TC and fitted this within the IMI DIRECT dataset. A second model, twin-cycle plus physical activity (TC-PA), to assess the extent to which the effects of physical activity in glycaemic regulation are mediated by components in the twin-cycle, was also fitted. Beta cell function, insulin sensitivity and glycaemic control were modelled from frequently sampled 75 g OGTTs (fsOGTTs) and mixed-meal tolerance tests (MMTTs) in participants without and with diabetes, respectively. Abdominal fat distribution was assessed using MRI, and physical activity through wrist-worn triaxial accelerometry. Results are presented as standardised beta coefficients, SE and p values, respectively. Results: The TC and TC-PA models showed better fit than null models (TC: χ2 = 242, p = 0.004 and χ2 = 63, p = 0.001 in cohort 1 and 2, respectively; TC-PA: χ2 = 180, p = 0.041 and χ2 = 60, p = 0.008 in cohort 1 and 2, respectively). The association of physical activity with glycaemic control was primarily mediated by variables in the liver fat cycle. Conclusions/interpretation: These analyses partially support the mechanisms proposed in the twin-cycle model and highlight mechanistic pathways through which insulin sensitivity and liver fat mediate the association between physical activity and glycaemic control.

22. The role of physical activity in metabolic homeostasis before and after the onset of type 2 diabetes: an IMI DIRECT study

Author

Koivula, Robert W., Atabaki-Pasdar, Naeimeh, Giordano, Giuseppe N., White, Tom, Adamski, Jerzy, Bell, Jimmy D., Beulens, Joline, Brage, Søren, Brunak, Søren, De Masi, Federico, Dermitzakis, Emmanouil T., Forgie, Ian M., Frost, Gary, Hansen, Torben, Hansen, Tue H., Hattersley, Andrew, Kokkola, Tarja, Kurbasic, Azra, Laakso, Markku, Mari, Andrea, McDonald, Timothy J., Pedersen, Oluf, Rutters, Femke, Schwenk, Jochen M., Teare, Harriet J. A., Thomas, E. Louise, Vinuela, Ana, Mahajan, Anubha, McCarthy, Mark I., Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, Pavo, Imre, and Franks, Paul W.

Subjects

Physical activity, Structural equation modelling, Glycaemic control, Beta cell function, Type 2 diabetes, Insulin sensitivity, Prediabetes, Article, Ectopic fat, 3. Good health

Abstract

Aims/hypothesis: It is well established that physical activity, abdominal ectopic fat and glycaemic regulation are related but the underlying structure of these relationships is unclear. The previously proposed twin-cycle hypothesis (TC) provides a mechanistic basis for impairment in glycaemic control through the interactions of substrate availability, substrate metabolism and abdominal ectopic fat accumulation. Here, we hypothesise that the effect of physical activity in glucose regulation is mediated by the twin-cycle. We aimed to examine this notion in the Innovative Medicines Initiative Diabetes Research on Patient Stratification (IMI DIRECT) Consortium cohorts comprised of participants with normal or impaired glucose regulation (cohort 1: N ≤ 920) or with recently diagnosed type 2 diabetes (cohort 2: N ≤ 435). Methods: We defined a structural equation model that describes the TC and fitted this within the IMI DIRECT dataset. A second model, twin-cycle plus physical activity (TC-PA), to assess the extent to which the effects of physical activity in glycaemic regulation are mediated by components in the twin-cycle, was also fitted. Beta cell function, insulin sensitivity and glycaemic control were modelled from frequently sampled 75 g OGTTs (fsOGTTs) and mixed-meal tolerance tests (MMTTs) in participants without and with diabetes, respectively. Abdominal fat distribution was assessed using MRI, and physical activity through wrist-worn triaxial accelerometry. Results are presented as standardised beta coefficients, SE and p values, respectively. Results: The TC and TC-PA models showed better fit than null models (TC: χ2 = 242, p = 0.004 and χ2 = 63, p = 0.001 in cohort 1 and 2, respectively; TC-PA: χ2 = 180, p = 0.041 and χ2 = 60, p = 0.008 in cohort 1 and 2, respectively). The association of physical activity with glycaemic control was primarily mediated by variables in the liver fat cycle. Conclusions/interpretation: These analyses partially support the mechanisms proposed in the twin-cycle model and highlight mechanistic pathways through which insulin sensitivity and liver fat mediate the association between physical activity and glycaemic control.

23. Discovery of biomarkers for glycaemic deterioration before and after the onset of type 2 diabetes: descriptive characteristics of the epidemiological studies within the IMI DIRECT Consortium

Author

Koivula, Robert W., Forgie, Ian M., Kurbasic, Azra, Viñuela, Ana, Heggie, Alison, Giordano, Giuseppe N., Hansen, Tue H., Hudson, Michelle, Koopman, Anitra D. M., Rutters, Femke, Siloaho, Maritta, Allin, Kristine H., Brage, Søren, Brorsson, Caroline A., Dawed, Adem Y., De Masi, Federico, Groves, Christopher J., Kokkola, Tarja, Mahajan, Anubha, Perry, Mandy H., Rauh, Simone P., Ridderstråle, Martin, Teare, Harriet J. A., Thomas, E. Louise, Tura, Andrea, Vestergaard, Henrik, White, Tom, Adamski, Jerzy, Bell, Jimmy D., Beulens, Joline W., Brunak, Søren, Dermitzakis, Emmanouil T., Froguel, Philippe, Frost, Gary, Gupta, Ramneek, Hansen, Torben, Hattersley, Andrew, Jablonka, Bernd, Kaye, Jane, Laakso, Markku, McDonald, Timothy J., Pedersen, Oluf, Schwenk, Jochen M., Pavo, Imre, Mari, Andrea, McCarthy, Mark I., Ruetten, Hartmut, Walker, Mark, Pearson, Ewan, and Franks, Paul W.

Subjects

Genome, Physical activity, Insulin secretion, Glycaemic control, Personalised medicine, Type 2 diabetes, 16. Peace & justice, Insulin sensitivity, Prediabetes, Article, Ectopic fat, 3. Good health, Diet

Abstract

Aims/hypothesis: Here, we describe the characteristics of the Innovative Medicines Initiative (IMI) Diabetes Research on Patient Stratification (DIRECT) epidemiological cohorts at baseline and follow-up examinations (18, 36 and 48 months of follow-up). Methods: From a sampling frame of 24,682 adults of European ancestry enrolled in population-based cohorts across Europe, participants at varying risk of glycaemic deterioration were identified using a risk prediction algorithm (based on age, BMI, waist circumference, use of antihypertensive medication, smoking status and parental history of type 2 diabetes) and enrolled into a prospective cohort study (n = 2127) (cohort 1, prediabetes risk). We also recruited people from clinical registries with type 2 diabetes diagnosed 6–24 months previously (n = 789) into a second cohort study (cohort 2, diabetes). Follow-up examinations took place at ~18 months (both cohorts) and at ~48 months (cohort 1) or ~36 months (cohort 2) after baseline examinations. The cohorts were studied in parallel using matched protocols across seven clinical centres in northern Europe. Results: Using ADA 2011 glycaemic categories, 33% (n = 693) of cohort 1 (prediabetes risk) had normal glucose regulation and 67% (n = 1419) had impaired glucose regulation. Seventy-six per cent of participants in cohort 1 was male. Cohort 1 participants had the following characteristics (mean ± SD) at baseline: age 62 (6.2) years; BMI 27.9 (4.0) kg/m2; fasting glucose 5.7 (0.6) mmol/l; 2 h glucose 5.9 (1.6) mmol/l. At the final follow-up examination the participants’ clinical characteristics were as follows: fasting glucose 6.0 (0.6) mmol/l; 2 h OGTT glucose 6.5 (2.0) mmol/l. In cohort 2 (diabetes), 66% (n = 517) were treated by lifestyle modification and 34% (n = 272) were treated with metformin plus lifestyle modification at enrolment. Fifty-eight per cent of participants in cohort 2 was male. Cohort 2 participants had the following characteristics at baseline: age 62 (8.1) years; BMI 30.5 (5.0) kg/m2; fasting glucose 7.2 (1.4) mmol/l; 2 h glucose 8.6 (2.8) mmol/l. At the final follow-up examination, the participants’ clinical characteristics were as follows: fasting glucose 7.9 (2.0) mmol/l; 2 h mixed-meal tolerance test glucose 9.9 (3.4) mmol/l. Conclusions/interpretation: The IMI DIRECT cohorts are intensely characterised, with a wide-variety of metabolically relevant measures assessed prospectively. We anticipate that the cohorts, made available through managed access, will provide a powerful resource for biomarker discovery, multivariate aetiological analyses and reclassification of patients for the prevention and treatment of type 2 diabetes.

24. Correction to: The role of physical activity in metabolic homeostasis before and after the onset of type 2 diabetes: an IMI DIRECT study.

Author

Koivula RW, Atabaki-Pasdar N, Giordano GN, White T, Adamski J, Bell JD, Beulens J, Brage S, Brunak S, De Masi F, Dermitzakis ET, Forgie IM, Frost G, Hansen T, Hansen TH, Hattersley A, Kokkola T, Kurbasic A, Laakso M, Mari A, McDonald TJ, Pedersen O, Rutters F, Schwenk JM, Teare HJA, Thomas EL, Vinuela A, Mahajan A, McCarthy MI, Ruetten H, Walker M, Pearson E, Pavo I, and Franks PW

Abstract

Unfortunately, 'Present address' was omitted from one of the addresses provided for Mark I. McCarthy (#26).

Published

2021

25. Post-load glucose subgroups and associated metabolic traits in individuals with type 2 diabetes: An IMI-DIRECT study.

Author

Obura M, Beulens JWJ, Slieker R, Koopman ADM, Hoekstra T, Nijpels G, Elders P, Koivula RW, Kurbasic A, Laakso M, Hansen TH, Ridderstråle M, Hansen T, Pavo I, Forgie I, Jablonka B, Ruetten H, Mari A, McCarthy MI, Walker M, Heggie A, McDonald TJ, Perry MH, De Masi F, Brunak S, Mahajan A, Giordano GN, Kokkola T, Dermitzakis E, Viñuela A, Pedersen O, Schwenk JM, Adamski J, Teare HJA, Pearson ER, Franks PW, 't Hart LM, and Rutters F

Subjects

Aged, Blood Glucose analysis, Diabetes Mellitus, Type 2 blood, Fasting blood, Fasting metabolism, Female, Follow-Up Studies, Glycated Hemoglobin analysis, Glycated Hemoglobin metabolism, Humans, Male, Middle Aged, Triglycerides blood, Triglycerides metabolism, Blood Glucose metabolism, Diabetes Mellitus, Type 2 metabolism

Abstract

Aim: Subclasses of different glycaemic disturbances could explain the variation in characteristics of individuals with type 2 diabetes (T2D). We aimed to examine the association between subgroups based on their glucose curves during a five-point mixed-meal tolerance test (MMT) and metabolic traits at baseline and glycaemic deterioration in individuals with T2D., Methods: The study included 787 individuals with newly diagnosed T2D from the Diabetes Research on Patient Stratification (IMI-DIRECT) Study. Latent class trajectory analysis (LCTA) was used to identify distinct glucose curve subgroups during a five-point MMT. Using general linear models, these subgroups were associated with metabolic traits at baseline and after 18 months of follow up, adjusted for potential confounders., Results: At baseline, we identified three glucose curve subgroups, labelled in order of increasing glucose peak levels as subgroup 1-3. Individuals in subgroup 2 and 3 were more likely to have higher levels of HbA1c, triglycerides and BMI at baseline, compared to those in subgroup 1. At 18 months (n = 651), the beta coefficients (95% CI) for change in HbA1c (mmol/mol) increased across subgroups with 0.37 (-0.18-1.92) for subgroup 2 and 1.88 (-0.08-3.85) for subgroup 3, relative to subgroup 1. The same trend was observed for change in levels of triglycerides and fasting glucose., Conclusions: Different glycaemic profiles with different metabolic traits and different degrees of subsequent glycaemic deterioration can be identified using data from a frequently sampled mixed-meal tolerance test in individuals with T2D. Subgroups with the highest peaks had greater metabolic risk., Competing Interests: The authors have read the journal’s policy and have the following competing interests: IP is employed by Eli Lilly Regional Operations GmbH, Vienna, Austria and BJ and HR are employees of Sanofi-Aventis Deutschland GmbH, R&D, Frankfurt am Main, Germany. This does not alter our adherence to PLOS ONE policies on sharing data and materials. There are no patents, products in development or marketed products associated with this research to declare.

Published

2020

26. The role of physical activity in metabolic homeostasis before and after the onset of type 2 diabetes: an IMI DIRECT study.

Author

Koivula RW, Atabaki-Pasdar N, Giordano GN, White T, Adamski J, Bell JD, Beulens J, Brage S, Brunak S, De Masi F, Dermitzakis ET, Forgie IM, Frost G, Hansen T, Hansen TH, Hattersley A, Kokkola T, Kurbasic A, Laakso M, Mari A, McDonald TJ, Pedersen O, Rutters F, Schwenk JM, Teare HJA, Thomas EL, Vinuela A, Mahajan A, McCarthy MI, Ruetten H, Walker M, Pearson E, Pavo I, and Franks PW

Subjects

Aged, Blood Glucose metabolism, Cohort Studies, Cross-Sectional Studies, Denmark epidemiology, Diabetes Mellitus, Type 2 blood, Diabetes Mellitus, Type 2 epidemiology, Diabetes Mellitus, Type 2 therapy, Female, Finland epidemiology, Glucose Tolerance Test, Glycemic Control, Humans, Insulin Resistance, Male, Middle Aged, Netherlands epidemiology, Sweden epidemiology, Diabetes Mellitus, Type 2 metabolism, Energy Metabolism physiology, Exercise physiology, Homeostasis physiology

Abstract

Aims/hypothesis: It is well established that physical activity, abdominal ectopic fat and glycaemic regulation are related but the underlying structure of these relationships is unclear. The previously proposed twin-cycle hypothesis (TC) provides a mechanistic basis for impairment in glycaemic control through the interactions of substrate availability, substrate metabolism and abdominal ectopic fat accumulation. Here, we hypothesise that the effect of physical activity in glucose regulation is mediated by the twin-cycle. We aimed to examine this notion in the Innovative Medicines Initiative Diabetes Research on Patient Stratification (IMI DIRECT) Consortium cohorts comprised of participants with normal or impaired glucose regulation (cohort 1: N ≤ 920) or with recently diagnosed type 2 diabetes (cohort 2: N ≤ 435)., Methods: We defined a structural equation model that describes the TC and fitted this within the IMI DIRECT dataset. A second model, twin-cycle plus physical activity (TC-PA), to assess the extent to which the effects of physical activity in glycaemic regulation are mediated by components in the twin-cycle, was also fitted. Beta cell function, insulin sensitivity and glycaemic control were modelled from frequently sampled 75 g OGTTs (fsOGTTs) and mixed-meal tolerance tests (MMTTs) in participants without and with diabetes, respectively. Abdominal fat distribution was assessed using MRI, and physical activity through wrist-worn triaxial accelerometry. Results are presented as standardised beta coefficients, SE and p values, respectively., Results: The TC and TC-PA models showed better fit than null models (TC: χ 2  = 242, p = 0.004 and χ 2  = 63, p = 0.001 in cohort 1 and 2, respectively; TC-PA: χ 2  = 180, p = 0.041 and χ 2  = 60, p = 0.008 in cohort 1 and 2, respectively). The association of physical activity with glycaemic control was primarily mediated by variables in the liver fat cycle., Conclusions/interpretation: These analyses partially support the mechanisms proposed in the twin-cycle model and highlight mechanistic pathways through which insulin sensitivity and liver fat mediate the association between physical activity and glycaemic control.

Published

2020

27. Australian Aboriginal and Torres Strait Islander Collections of Genetic Heritage: The Legal, Ethical and Practical Considerations of a Dynamic Consent Approach to Decision Making.

Author

Prictor M, Huebner S, Teare HJA, Burchill L, and Kaye J

Subjects

Australia ethnology, Collections as Topic, Culture, Human Rights, Humans, Ownership, Australian Aboriginal and Torres Strait Islander Peoples, Decision Making, Genomics ethics, Indigenous Peoples genetics, Informed Consent ethics, Informed Consent legislation & jurisprudence

Abstract

Dynamic Consent (DC) is both a model and a specific web-based tool that enables clear, granular communication and recording of participant consent choices over time. The DC model enables individuals to know and to decide how personal research information is being used and provides a way in which to exercise legal rights provided in privacy and data protection law. The DC tool is flexible and responsive, enabling legal and ethical requirements in research data sharing to be met and for online health information to be maintained. DC has been used in rare diseases and genomics, to enable people to control and express their preferences regarding their own data. However, DC has never been explored in relationship to historical collections of bioscientific and genetic heritage or to contexts involving Aboriginal and Torres Strait Islander people (First Peoples of Australia). In response to the growing interest by First Peoples throughout Australia in genetic and genomic research, and the increasing number of invitations from researchers to participate in community health and wellbeing projects, this article examines the legal and ethical attributes and challenges of DC in these contexts. It also explores opportunities for including First Peoples' cultural perspectives, governance, and leadership as a method for defining (or redefining) DC on cultural terms that engage best practice research and data analysis as well as respect for meaningful and longitudinal individual and family participation.

Published

2020