Noninvasive Plaque Imaging to Accelerate Coronary Artery Disease Drug Development-Reference-Cited by-同舟云学术

Noninvasive Plaque Imaging to Accelerate Coronary Artery Disease Drug Development

Published:2022-11-29 Issue:22 Volume:146 Page:1712-1727
ISSN:0009-7322
Container-title:Circulation
language:en
Short-container-title:Circulation

Author:

Figtree Gemma A.¹²³⁴^ORCID,Adamson Philip D.⁵⁶^ORCID,Antoniades Charalambos⁷⁸^ORCID,Blumenthal Roger S.⁹^ORCID,Blaha Michael⁹^ORCID,Budoff Matthew¹⁰^ORCID,Celermajer David S.⁴¹¹^ORCID,Chan Mark Y.¹²^ORCID,Chow Clara K.¹³³^ORCID,Dey Damini¹⁴^ORCID,Dwivedi Girish¹⁵¹⁶,Giannotti Nicola⁴^ORCID,Grieve Stuart M.¹⁷¹⁸,Hamilton-Craig Christian¹⁹^ORCID,Kingwell Bronwyn A.²⁰^ORCID,Kovacic Jason C.²¹²²²³^ORCID,Min James K.²⁴,Newby David E.⁶^ORCID,Patel Sanjay⁴¹¹,Peter Karlheinz²⁵²⁶^ORCID,Psaltis Peter J.²⁷²⁸^ORCID,Vernon Stephen T.¹²⁴^ORCID,Wong Dennis T.²⁹³⁰,Nicholls Stephen J.²⁹³⁰

Affiliation:

1. Kolling Institute of Medical Research, Sydney, Australia (G.A.F., S.T.V.).

2. Department of Cardiology, Royal North Shore Hospital, Northern Sydney Local Health District, Australia (G.A.F., S.T.V.).

3. Charles Perkins Centre (G.A.F., C.K.C.), University of Sydney, Australia.

4. Faculty of Medicine and Health (G.A.F., D.S.C., N.G., S.P., S.T.V.), University of Sydney, Australia.

5. Christchurch Heart Institute, University of Otago Christchurch, New Zealand (P.D.A.).

6. British Heart Foundation Centre for Cardiovascular Science, University of Edinburgh, United Kingdom (P.D.A., D.E.N.).

7. Acute Vascular Imaging Centre (C.A.), Radcliffe Department of Medicine, University of Oxford, UK.

8. Division of Cardiovascular Medicine (C.A.), Radcliffe Department of Medicine, University of Oxford, UK.

9. Johns Hopkins Ciccarone Center for the Prevention of Cardiovascular Disease, Baltimore, MD (R.S.B., M. Blaha).

10. Lundquist Institute, Torrance, CA (M.B.).

11. Departments of Cardiology (D.S.C., S.P.), Royal Prince Alfred Hospital, Sydney, Australia.

12. Department of Cardiology, National University Heart Centre, Singapore (M.Y.C.).

13. Westmead Applied Research Centre (C.K.C.), University of Sydney, Australia.

14. Biomedical Imaging Research Institute, Cedars-Sinai Medical Center, Los Angeles, CA (D.D.).

15. Harry Perkins Institute of Medical Research, University of Western Australia (G.D.).

16. Department of Cardiology, Fiona Stanley Hospital, Perth, Australia (G.D.).

17. Imaging and Phenotyping Laboratory (S.M.G.), University of Sydney, Australia.

18. Radiology (S.M.G.), Royal Prince Alfred Hospital, Sydney, Australia.

19. Faculty of Medicine and Centre for Advanced Imaging, University of Queensland and School of Medicine, Griffith University Sunshine Coast, Australia (C.H.-C.).

20. CSL Limited, Melbourne, Australia (B.A.K.).

21. Victor Chang Cardiac Research Institute, Darlinghurst, Australia (J.C.K.).

22. St Vincent’s Clinical School, University of NSW, Australia (J.C.K.).

23. Cardiovascular Research Institute, Icahn School of Medicine at Mount Sinai, New York, NY (J.C.K.).

24. Cleerly, Inc., New York, NY (J.K.M.).

25. Baker Heart and Diabetes Institute, Melbourne, Australia (K.P.).

26. Department of Cardiology, The Alfred Hospital, Melbourne, Australia (K.P.).

27. Lifelong Health, South Australian Health and Medical Research Institute, Adelaide (P.J.P.).

28. Department of Cardiology, Royal Adelaide Hospital, Australia (P.J.P.).

29. Monash Heart, Clayton, Australia (D.T.W., S.J.N.).

30. Victorian Heart Institute, Monash University, Melbourne, Australia (D.T.W., S.J.N.).

Abstract

Coronary artery disease (CAD) remains the leading cause of adult mortality globally. Targeting known modifiable risk factors has had substantial benefit, but there remains a need for new approaches. Improvements in invasive and noninvasive imaging techniques have enabled an increasing recognition of distinct quantitative phenotypes of coronary atherosclerosis that are prognostically relevant. There are marked differences in plaque phenotype, from the high-risk, lipid-rich, thin-capped atheroma to the low-risk, quiescent, eccentric, nonobstructive calcified plaque. Such distinct phenotypes reflect different pathophysiologic pathways and are associated with different risks for acute ischemic events. Noninvasive coronary imaging techniques, such as computed tomography, positron emission tomography, and coronary magnetic resonance imaging, have major potential to accelerate cardiovascular drug development, which has been affected by the high costs and protracted timelines of cardiovascular outcome trials. This may be achieved through enrichment of high-risk phenotypes with higher event rates or as primary end points of drug efficacy, at least in phase 2 trials, in a manner historically performed through intravascular coronary imaging studies. Herein, we provide a comprehensive review of the current technology available and its application in clinical trials, including implications for sample size requirements, as well as potential limitations. In its effort to accelerate drug development, the US Food and Drug Administration has approved surrogate end points for 120 conditions, but not for CAD. There are robust data showing the beneficial effects of drugs, including statins, on CAD progression and plaque stabilization in a manner that correlates with established clinical end points of mortality and major adverse cardiovascular events. This, together with a clear mechanistic rationale for using imaging as a surrogate CAD end point, makes it timely for CAD imaging end points to be considered. We discuss the importance of global consensus on these imaging end points and protocols and partnership with regulatory bodies to build a more informed, sustainable staged pathway for novel therapies.

Publisher

Ovid Technologies (Wolters Kluwer Health)

Subject

Physiology (medical),Cardiology and Cardiovascular Medicine

Reference97 articles.

1. A Call to Action for New Global Approaches to Cardiovascular Disease Drug Solutions

2. A call to action for new global approaches to cardiovascular disease drug solutions

3. Mortality in STEMI patients without standard modifiable risk factors: a sex-disaggregated analysis of SWEDEHEART registry data

4. Increasing proportion of ST elevation myocardial infarction patients with coronary atherosclerosis poorly explained by standard modifiable risk factors

5. ST‐Segment–Elevation Myocardial Infarction (STEMI) Patients Without Standard Modifiable Cardiovascular Risk Factors—How Common Are They, and What Are Their Outcomes?

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