Association of Plaque Location and Vessel Geometry Determined by Coronary Computed Tomographic Angiography with Future Acute Coronary Syndrome-Causing Culprit Lesions

Donghee Han; Andrew Lin; Keiichiro Kuronuma; Evangelos Tzolos; Alan C. Kwan; Eyal Klein; Daniele Andreini; Jeroen J. Bax; Filippo Cademartiri; Kavitha Chinnaiyan; Benjamin J. W. Chow; Edoardo Conte; Ricardo C. Cury; Gudrun Feuchtner; Martin Hadamitzky; Yong-Jin Kim; Jonathon A. Leipsic; Erica Maffei; Hugo Marques; Fabian Plank; Gianluca Pontone; Todd C. Villines; Mouaz H. Al-Mallah; Pedro de Araújo Gonçalves; Ibrahim Danad; Heidi Gransar; Yao Lu; Ji-Hyun Lee; Sang-Eun Lee; Lohendran Baskaran; Subhi J. Al'Aref; Yeonyee E. Yoon; Alexander van Rosendael; Matthew J. Budoff; Habib Samady; Peter H. Stone; Renu Virmani; Stephan Achenbach; Jagat Narula; Hyuk-Jae Chang; James K. Min; Fay Y. Lin; Leslee J. Shaw; Piotr J. Slomka; Damini Dey; Daniel S. Berman

doi:https://doi.org/10.1001/jamacardio.2021.5705

Association of Plaque Location and Vessel Geometry Determined by Coronary Computed Tomographic Angiography with Future Acute Coronary Syndrome-Causing Culprit Lesions

Donghee Han, Andrew Lin, Keiichiro Kuronuma, Evangelos Tzolos, Alan C. Kwan, Eyal Klein, Daniele Andreini, Jeroen J. Bax, Filippo Cademartiri, Kavitha Chinnaiyan, Benjamin J. W. Chow, Edoardo Conte, Ricardo C. Cury, Gudrun Feuchtner, Martin Hadamitzky, Yong-Jin Kim, Jonathon A. Leipsic, Erica Maffei, Hugo Marques, Fabian PlankGianluca Pontone, Todd C. Villines, Mouaz H. Al-Mallah, Pedro de Araújo Gonçalves, Ibrahim Danad, Heidi Gransar, Yao Lu, Ji-Hyun Lee, Sang-Eun Lee, Lohendran Baskaran, Subhi J. Al'Aref, Yeonyee E. Yoon, Alexander van Rosendael, Matthew J. Budoff, Habib Samady, Peter H. Stone, Renu Virmani, Stephan Achenbach, Jagat Narula, Hyuk-Jae Chang, James K. Min, Fay Y. Lin, Leslee J. Shaw, Piotr J. Slomka, Damini Dey, Daniel S. Berman

Research output: Contribution to journal › Article › Academic › peer-review

13 Citations (Scopus)

Abstract

Importance: Distinct plaque locations and vessel geometric features predispose to altered coronary flow hemodynamics. The association between these lesion-level characteristics assessed by coronary computed tomographic angiography (CCTA) and risk of future acute coronary syndrome (ACS) is unknown. Objective: To examine whether CCTA-derived adverse geometric characteristics (AGCs) of coronary lesions describing location and vessel geometry add to plaque morphology and burden for identifying culprit lesion precursors associated with future ACS. Design, Setting, and Participants: This substudy of ICONIC (Incident Coronary Syndromes Identified by Computed Tomography), a multicenter nested case-control cohort study, included patients with ACS and a culprit lesion precursor identified on baseline CCTA (n = 116) and propensity score-matched non-ACS controls (n = 116). Data were collected from July 20, 2012, to April 30, 2017, and analyzed from October 1, 2020, to October 31, 2021. Exposures: Coronary lesions were evaluated for the following 3 AGCs: (1) distance from the coronary ostium to lesion; (2) location at vessel bifurcations; and (3) vessel tortuosity, defined as the presence of 1 bend of greater than 90° or 3 curves of 45° to 90° using a 3-point angle within the lesion. Main Outcomes and Measures: Association between lesion-level AGCs and risk of future ACS-causing culprit lesions. Results: Of 548 lesions, 116 culprit lesion precursors were identified in 116 patients (80 [69.0%] men; mean [SD], age 62.7 [11.5] years). Compared with nonculprit lesions, culprit lesion precursors had a shorter distance from the ostium (median, 35.1 [IQR, 23.6-48.4] mm vs 44.5 [IQR, 28.2-70.8] mm), more frequently localized to bifurcations (85 [73.3%] vs 168 [38.9%]), and had more tortuous vessel segments (5 [4.3%] vs 6 [1.4%]; all P <.05). In multivariable Cox regression analysis, an increasing number of AGCs was associated with a greater risk of future culprit lesions (hazard ratio [HR] for 1 AGC, 2.90 [95% CI, 1.38-6.08]; P =.005; HR for ≥2 AGCs, 6.84 [95% CI, 3.33-14.04]; P <.001). Adverse geometric characteristics provided incremental discriminatory value for culprit lesion precursors when added to a model containing stenosis severity, adverse morphological plaque characteristics, and quantitative plaque characteristics (area under the curve, 0.766 [95% CI, 0.718-0.814] vs 0.733 [95% CI, 0.685-0.782]). In per-patient comparison, patients with ACS had a higher frequency of lesions with adverse plaque characteristics, AGCs, or both compared with control patients (≥2 adverse plaque characteristics, 70 [60.3%] vs 50 [43.1%]; ≥2 AGCs, 92 [79.3%] vs 60 [51.7%]; ≥2 of both, 37 [31.9%] vs 20 [17.2%]; all P <.05). Conclusions and Relevance: These findings support the concept that CCTA-derived AGCs capturing lesion location and vessel geometry are associated with risk of future ACS-causing culprit lesions. Adverse geometric characteristics may provide additive prognostic information beyond plaque assessment in CCTA.

Original language	English
Pages (from-to)	309-319
Number of pages	11
Journal	JAMA Cardiology
Volume	7
Issue number	3
Early online date	2022
DOIs	https://doi.org/10.1001/jamacardio.2021.5705
Publication status	Published - Mar 2022

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Han, D., Lin, A., Kuronuma, K., Tzolos, E., Kwan, A. C., Klein, E., Andreini, D., Bax, J. J., Cademartiri, F., Chinnaiyan, K., Chow, B. J. W., Conte, E., Cury, R. C., Feuchtner, G., Hadamitzky, M., Kim, Y.-J., Leipsic, J. A., Maffei, E., Marques, H., ... Berman, D. S. (2022). Association of Plaque Location and Vessel Geometry Determined by Coronary Computed Tomographic Angiography with Future Acute Coronary Syndrome-Causing Culprit Lesions. JAMA Cardiology, 7(3), 309-319. https://doi.org/10.1001/jamacardio.2021.5705

@article{24817816d2e44b3cbc779a033ac2570d,

title = "Association of Plaque Location and Vessel Geometry Determined by Coronary Computed Tomographic Angiography with Future Acute Coronary Syndrome-Causing Culprit Lesions",

abstract = "Importance: Distinct plaque locations and vessel geometric features predispose to altered coronary flow hemodynamics. The association between these lesion-level characteristics assessed by coronary computed tomographic angiography (CCTA) and risk of future acute coronary syndrome (ACS) is unknown. Objective: To examine whether CCTA-derived adverse geometric characteristics (AGCs) of coronary lesions describing location and vessel geometry add to plaque morphology and burden for identifying culprit lesion precursors associated with future ACS. Design, Setting, and Participants: This substudy of ICONIC (Incident Coronary Syndromes Identified by Computed Tomography), a multicenter nested case-control cohort study, included patients with ACS and a culprit lesion precursor identified on baseline CCTA (n = 116) and propensity score-matched non-ACS controls (n = 116). Data were collected from July 20, 2012, to April 30, 2017, and analyzed from October 1, 2020, to October 31, 2021. Exposures: Coronary lesions were evaluated for the following 3 AGCs: (1) distance from the coronary ostium to lesion; (2) location at vessel bifurcations; and (3) vessel tortuosity, defined as the presence of 1 bend of greater than 90° or 3 curves of 45° to 90° using a 3-point angle within the lesion. Main Outcomes and Measures: Association between lesion-level AGCs and risk of future ACS-causing culprit lesions. Results: Of 548 lesions, 116 culprit lesion precursors were identified in 116 patients (80 [69.0%] men; mean [SD], age 62.7 [11.5] years). Compared with nonculprit lesions, culprit lesion precursors had a shorter distance from the ostium (median, 35.1 [IQR, 23.6-48.4] mm vs 44.5 [IQR, 28.2-70.8] mm), more frequently localized to bifurcations (85 [73.3%] vs 168 [38.9%]), and had more tortuous vessel segments (5 [4.3%] vs 6 [1.4%]; all P <.05). In multivariable Cox regression analysis, an increasing number of AGCs was associated with a greater risk of future culprit lesions (hazard ratio [HR] for 1 AGC, 2.90 [95% CI, 1.38-6.08]; P =.005; HR for ≥2 AGCs, 6.84 [95% CI, 3.33-14.04]; P <.001). Adverse geometric characteristics provided incremental discriminatory value for culprit lesion precursors when added to a model containing stenosis severity, adverse morphological plaque characteristics, and quantitative plaque characteristics (area under the curve, 0.766 [95% CI, 0.718-0.814] vs 0.733 [95% CI, 0.685-0.782]). In per-patient comparison, patients with ACS had a higher frequency of lesions with adverse plaque characteristics, AGCs, or both compared with control patients (≥2 adverse plaque characteristics, 70 [60.3%] vs 50 [43.1%]; ≥2 AGCs, 92 [79.3%] vs 60 [51.7%]; ≥2 of both, 37 [31.9%] vs 20 [17.2%]; all P <.05). Conclusions and Relevance: These findings support the concept that CCTA-derived AGCs capturing lesion location and vessel geometry are associated with risk of future ACS-causing culprit lesions. Adverse geometric characteristics may provide additive prognostic information beyond plaque assessment in CCTA.",

author = "Donghee Han and Andrew Lin and Keiichiro Kuronuma and Evangelos Tzolos and Kwan, {Alan C.} and Eyal Klein and Daniele Andreini and Bax, {Jeroen J.} and Filippo Cademartiri and Kavitha Chinnaiyan and Chow, {Benjamin J. W.} and Edoardo Conte and Cury, {Ricardo C.} and Gudrun Feuchtner and Martin Hadamitzky and Yong-Jin Kim and Leipsic, {Jonathon A.} and Erica Maffei and Hugo Marques and Fabian Plank and Gianluca Pontone and Villines, {Todd C.} and Al-Mallah, {Mouaz H.} and {de Ara{\'u}jo Gon{\c c}alves}, Pedro and Ibrahim Danad and Heidi Gransar and Yao Lu and Ji-Hyun Lee and Sang-Eun Lee and Lohendran Baskaran and Al'Aref, {Subhi J.} and Yoon, {Yeonyee E.} and {van Rosendael}, Alexander and Budoff, {Matthew J.} and Habib Samady and Stone, {Peter H.} and Renu Virmani and Stephan Achenbach and Jagat Narula and Hyuk-Jae Chang and Min, {James K.} and Lin, {Fay Y.} and Shaw, {Leslee J.} and Slomka, {Piotr J.} and Damini Dey and Berman, {Daniel S.}",

note = "Funding Information: receiving grants from the Doris Duke Charitable Foundation during the conduct of the study. Dr Bax reported receiving speaker fees from Abbott Laboratories, Edwards Lifesciences, research grants from Abbott Laboratories, Edwards Lifesciences, Medtronic plc, Boston Scientific Corporation, and Biotronik outside the submitted work. Dr Chinnaiyan reported receiving institutional grants from HeartfFlow Inc during the conduct of the study. Dr Chow reported research collaboration and support from Artrya Ltd, grants from AusculSciences and TD Bank, nonfinancial research support from Siemens AG, and equity interest from GE Healthcare during the conduct of the study. Dr Cury reported consulting for Covera Health, GE Healthcare, and Cleerly Inc outside the submitted work. Dr Leipsic reported consulting for and having stock options from HeartFlow Inc, speaking fees from Philips, and institutional grants from GE Healthcare outside the submitted work. Dr Al-Mallah reported receiving grants from Siemens AG outside the submitted work. Dr Al{\textquoteright}Aref reported receiving grants from the National Institutes of Health (NIH) during the conduct of the study and textbook royalties from Elsevier outside the submitted work. Dr Samady reported receiving personal fees from Philips, Abbott Vascular, and Medtronic plc during the conduct of the study, being a cofounder and equity holder of Covanos Inc, and equity holder of SIG outside the submitted work. Dr Virmani reported receiving grants from the NIH, Leducq Foundation, 4C Medical, 4Tech, Abbott Vascular, Ablative Solutions, Absorption Systems, Advanced NanoTherapies, Aerwave Medical Inc, Alivas, Amgen Inc, Asahi Medical, Aurios Medical, Avantec Vascular, BD Bioscences, Biosensors, Biotronik, Biotyx Medical, Bolt Medical Inc, Boston Scientific, Canon Inc, Cardiac Implants LLC, Cardiawave, CardioMech, Cardionomic, CeloNova BioSciences Inc, Cerus Endovascular Inc, Chansu Vascular Technologies LLC, Children{\textquoteright}s National Medical Center, Concept Medical, Cook Medical, Cooper Health, Cormaze Technologies GmbH, CRL/AccelLab, Cro{\'i}Valve, CSI, DexCom Inc, Edwards Lifesciences, Elucid Bioimaging, eLum Technologies Inc, Emboline Inc, Endotronix, Envision, Filterlex, Imperative Care Inc, Innovative Cardiovascular Solutions LLC, Intact Vascular Inc, Interface Biolgics, InterShunt Technologies Inc, Invatin Technologies, Lahav CRO, LimFlow, L & J Biosciences, Lutonix, Lyra Therapeutics Inc, Mayo Clinic, Maywell, MD Start, MedAlliance, Medanex Clinic, Medtronic plc, Mercator Limited, MicroPort, MicroVention, Neovasc Inc, Nephronyx Ltd, Nova Vascular, Nyra Medical, Occultech, Olympus Therapeutics, OhioHealth, OrbusNeich, Ossio, phenox Inc, Pi-Cardia, Polares Medical, PolyVascular, Profusa Inc, ProKidney LLC, Protembis, Pulse Biosciences Inc, Qool Therapeutics, Recombinetics, ReCor Medical Inc, Regencor Inc, Renata Medical, Restore Medical Ltd, Ripple Therapeutics, Rush University, Sanofi SA, Shockwave Medical, Sahajanand Medical Technologies Limited, SoundPipe, Spartan Micro, SpectraWAVE Inc, Surmodics Inc, Terumo Corporation, Jacobs Institute, Transmural Systems LLC, Transverse Medical Inc, TruLeaf Medical, University of California, San Francisco, University of Pennsylvania Medical Center, Vascudyne Inc, Vesper, Vetex Medical, WhiteSwell, WL Gore & Associates Inc, and Xeltis and personal fees from Abbott Vascular, Boston Scientific, CeloNova BioSciences Inc, OrbusNeich, Terumo Corporation, W. L. Gore & Associates Inc, Edwards Lifesciences, Cook Medical, CSI, ReCor Medical, Sino Medical Sciences Technology Inc, Surmodics Inc, Bard BD, Medtronic plc, and Xeltis outside the submitted work. Dr Min reported serving on the medical advisory board of Arineta during the conduct of the study, having an equity interest and serving on the medical advisory board of Arineta, and having an equity interest and being an employee of Cleerly Inc outside the submitted work. Dr F. Y. Lin reported receiving grants from GE Healthcare outside the submitted work. Dr Slomka reported software royalties from Cedars-Sinai Medical Center during the conduct of the study; grants from the NIH and Siemens AG outside the submitted work; and patents for US8885905B2 and WO2011069120A1 issued. Dr Dey reported receiving software royalties from Cedars-Sinai Medical Center and a patent outside the submitted work. Dr Berman reported a patent for software with royalties paid from Cedars-Sinai Medical Center. No other disclosures were reported. Funding Information: Funding/Support: This trial was supported by Publisher Copyright: {\textcopyright} 2022 American Medical Association. All rights reserved.",

year = "2022",

month = mar,

doi = "https://doi.org/10.1001/jamacardio.2021.5705",

language = "English",

volume = "7",

pages = "309--319",

journal = "JAMA Cardiology",

issn = "2380-6583",

publisher = "American Medical Association",

number = "3",

}

Han, D, Lin, A, Kuronuma, K, Tzolos, E, Kwan, AC, Klein, E, Andreini, D, Bax, JJ, Cademartiri, F, Chinnaiyan, K, Chow, BJW, Conte, E, Cury, RC, Feuchtner, G, Hadamitzky, M, Kim, Y-J, Leipsic, JA, Maffei, E, Marques, H, Plank, F, Pontone, G, Villines, TC, Al-Mallah, MH, de Araújo Gonçalves, P, Danad, I, Gransar, H, Lu, Y, Lee, J-H, Lee, S-E, Baskaran, L, Al'Aref, SJ, Yoon, YE, van Rosendael, A, Budoff, MJ, Samady, H, Stone, PH, Virmani, R, Achenbach, S, Narula, J, Chang, H-J, Min, JK, Lin, FY, Shaw, LJ, Slomka, PJ, Dey, D & Berman, DS 2022, 'Association of Plaque Location and Vessel Geometry Determined by Coronary Computed Tomographic Angiography with Future Acute Coronary Syndrome-Causing Culprit Lesions', JAMA Cardiology, vol. 7, no. 3, pp. 309-319. https://doi.org/10.1001/jamacardio.2021.5705

TY - JOUR

T1 - Association of Plaque Location and Vessel Geometry Determined by Coronary Computed Tomographic Angiography with Future Acute Coronary Syndrome-Causing Culprit Lesions

AU - Han, Donghee

AU - Lin, Andrew

AU - Kuronuma, Keiichiro

AU - Tzolos, Evangelos

AU - Kwan, Alan C.

AU - Klein, Eyal

AU - Andreini, Daniele

AU - Bax, Jeroen J.

AU - Cademartiri, Filippo

AU - Chinnaiyan, Kavitha

AU - Chow, Benjamin J. W.

AU - Conte, Edoardo

AU - Cury, Ricardo C.

AU - Feuchtner, Gudrun

AU - Hadamitzky, Martin

AU - Kim, Yong-Jin

AU - Leipsic, Jonathon A.

AU - Maffei, Erica

AU - Marques, Hugo

AU - Plank, Fabian

AU - Pontone, Gianluca

AU - Villines, Todd C.

AU - Al-Mallah, Mouaz H.

AU - de Araújo Gonçalves, Pedro

AU - Danad, Ibrahim

AU - Gransar, Heidi

AU - Lu, Yao

AU - Lee, Ji-Hyun

AU - Lee, Sang-Eun

AU - Baskaran, Lohendran

AU - Al'Aref, Subhi J.

AU - Yoon, Yeonyee E.

AU - van Rosendael, Alexander

AU - Budoff, Matthew J.

AU - Samady, Habib

AU - Stone, Peter H.

AU - Virmani, Renu

AU - Achenbach, Stephan

AU - Narula, Jagat

AU - Chang, Hyuk-Jae

AU - Min, James K.

AU - Lin, Fay Y.

AU - Shaw, Leslee J.

AU - Slomka, Piotr J.

AU - Dey, Damini

AU - Berman, Daniel S.

N1 - Funding Information: receiving grants from the Doris Duke Charitable Foundation during the conduct of the study. Dr Bax reported receiving speaker fees from Abbott Laboratories, Edwards Lifesciences, research grants from Abbott Laboratories, Edwards Lifesciences, Medtronic plc, Boston Scientific Corporation, and Biotronik outside the submitted work. Dr Chinnaiyan reported receiving institutional grants from HeartfFlow Inc during the conduct of the study. Dr Chow reported research collaboration and support from Artrya Ltd, grants from AusculSciences and TD Bank, nonfinancial research support from Siemens AG, and equity interest from GE Healthcare during the conduct of the study. Dr Cury reported consulting for Covera Health, GE Healthcare, and Cleerly Inc outside the submitted work. Dr Leipsic reported consulting for and having stock options from HeartFlow Inc, speaking fees from Philips, and institutional grants from GE Healthcare outside the submitted work. Dr Al-Mallah reported receiving grants from Siemens AG outside the submitted work. Dr Al’Aref reported receiving grants from the National Institutes of Health (NIH) during the conduct of the study and textbook royalties from Elsevier outside the submitted work. Dr Samady reported receiving personal fees from Philips, Abbott Vascular, and Medtronic plc during the conduct of the study, being a cofounder and equity holder of Covanos Inc, and equity holder of SIG outside the submitted work. Dr Virmani reported receiving grants from the NIH, Leducq Foundation, 4C Medical, 4Tech, Abbott Vascular, Ablative Solutions, Absorption Systems, Advanced NanoTherapies, Aerwave Medical Inc, Alivas, Amgen Inc, Asahi Medical, Aurios Medical, Avantec Vascular, BD Bioscences, Biosensors, Biotronik, Biotyx Medical, Bolt Medical Inc, Boston Scientific, Canon Inc, Cardiac Implants LLC, Cardiawave, CardioMech, Cardionomic, CeloNova BioSciences Inc, Cerus Endovascular Inc, Chansu Vascular Technologies LLC, Children’s National Medical Center, Concept Medical, Cook Medical, Cooper Health, Cormaze Technologies GmbH, CRL/AccelLab, CroíValve, CSI, DexCom Inc, Edwards Lifesciences, Elucid Bioimaging, eLum Technologies Inc, Emboline Inc, Endotronix, Envision, Filterlex, Imperative Care Inc, Innovative Cardiovascular Solutions LLC, Intact Vascular Inc, Interface Biolgics, InterShunt Technologies Inc, Invatin Technologies, Lahav CRO, LimFlow, L & J Biosciences, Lutonix, Lyra Therapeutics Inc, Mayo Clinic, Maywell, MD Start, MedAlliance, Medanex Clinic, Medtronic plc, Mercator Limited, MicroPort, MicroVention, Neovasc Inc, Nephronyx Ltd, Nova Vascular, Nyra Medical, Occultech, Olympus Therapeutics, OhioHealth, OrbusNeich, Ossio, phenox Inc, Pi-Cardia, Polares Medical, PolyVascular, Profusa Inc, ProKidney LLC, Protembis, Pulse Biosciences Inc, Qool Therapeutics, Recombinetics, ReCor Medical Inc, Regencor Inc, Renata Medical, Restore Medical Ltd, Ripple Therapeutics, Rush University, Sanofi SA, Shockwave Medical, Sahajanand Medical Technologies Limited, SoundPipe, Spartan Micro, SpectraWAVE Inc, Surmodics Inc, Terumo Corporation, Jacobs Institute, Transmural Systems LLC, Transverse Medical Inc, TruLeaf Medical, University of California, San Francisco, University of Pennsylvania Medical Center, Vascudyne Inc, Vesper, Vetex Medical, WhiteSwell, WL Gore & Associates Inc, and Xeltis and personal fees from Abbott Vascular, Boston Scientific, CeloNova BioSciences Inc, OrbusNeich, Terumo Corporation, W. L. Gore & Associates Inc, Edwards Lifesciences, Cook Medical, CSI, ReCor Medical, Sino Medical Sciences Technology Inc, Surmodics Inc, Bard BD, Medtronic plc, and Xeltis outside the submitted work. Dr Min reported serving on the medical advisory board of Arineta during the conduct of the study, having an equity interest and serving on the medical advisory board of Arineta, and having an equity interest and being an employee of Cleerly Inc outside the submitted work. Dr F. Y. Lin reported receiving grants from GE Healthcare outside the submitted work. Dr Slomka reported software royalties from Cedars-Sinai Medical Center during the conduct of the study; grants from the NIH and Siemens AG outside the submitted work; and patents for US8885905B2 and WO2011069120A1 issued. Dr Dey reported receiving software royalties from Cedars-Sinai Medical Center and a patent outside the submitted work. Dr Berman reported a patent for software with royalties paid from Cedars-Sinai Medical Center. No other disclosures were reported. Funding Information: Funding/Support: This trial was supported by Publisher Copyright: © 2022 American Medical Association. All rights reserved.

PY - 2022/3

Y1 - 2022/3

N2 - Importance: Distinct plaque locations and vessel geometric features predispose to altered coronary flow hemodynamics. The association between these lesion-level characteristics assessed by coronary computed tomographic angiography (CCTA) and risk of future acute coronary syndrome (ACS) is unknown. Objective: To examine whether CCTA-derived adverse geometric characteristics (AGCs) of coronary lesions describing location and vessel geometry add to plaque morphology and burden for identifying culprit lesion precursors associated with future ACS. Design, Setting, and Participants: This substudy of ICONIC (Incident Coronary Syndromes Identified by Computed Tomography), a multicenter nested case-control cohort study, included patients with ACS and a culprit lesion precursor identified on baseline CCTA (n = 116) and propensity score-matched non-ACS controls (n = 116). Data were collected from July 20, 2012, to April 30, 2017, and analyzed from October 1, 2020, to October 31, 2021. Exposures: Coronary lesions were evaluated for the following 3 AGCs: (1) distance from the coronary ostium to lesion; (2) location at vessel bifurcations; and (3) vessel tortuosity, defined as the presence of 1 bend of greater than 90° or 3 curves of 45° to 90° using a 3-point angle within the lesion. Main Outcomes and Measures: Association between lesion-level AGCs and risk of future ACS-causing culprit lesions. Results: Of 548 lesions, 116 culprit lesion precursors were identified in 116 patients (80 [69.0%] men; mean [SD], age 62.7 [11.5] years). Compared with nonculprit lesions, culprit lesion precursors had a shorter distance from the ostium (median, 35.1 [IQR, 23.6-48.4] mm vs 44.5 [IQR, 28.2-70.8] mm), more frequently localized to bifurcations (85 [73.3%] vs 168 [38.9%]), and had more tortuous vessel segments (5 [4.3%] vs 6 [1.4%]; all P <.05). In multivariable Cox regression analysis, an increasing number of AGCs was associated with a greater risk of future culprit lesions (hazard ratio [HR] for 1 AGC, 2.90 [95% CI, 1.38-6.08]; P =.005; HR for ≥2 AGCs, 6.84 [95% CI, 3.33-14.04]; P <.001). Adverse geometric characteristics provided incremental discriminatory value for culprit lesion precursors when added to a model containing stenosis severity, adverse morphological plaque characteristics, and quantitative plaque characteristics (area under the curve, 0.766 [95% CI, 0.718-0.814] vs 0.733 [95% CI, 0.685-0.782]). In per-patient comparison, patients with ACS had a higher frequency of lesions with adverse plaque characteristics, AGCs, or both compared with control patients (≥2 adverse plaque characteristics, 70 [60.3%] vs 50 [43.1%]; ≥2 AGCs, 92 [79.3%] vs 60 [51.7%]; ≥2 of both, 37 [31.9%] vs 20 [17.2%]; all P <.05). Conclusions and Relevance: These findings support the concept that CCTA-derived AGCs capturing lesion location and vessel geometry are associated with risk of future ACS-causing culprit lesions. Adverse geometric characteristics may provide additive prognostic information beyond plaque assessment in CCTA.

AB - Importance: Distinct plaque locations and vessel geometric features predispose to altered coronary flow hemodynamics. The association between these lesion-level characteristics assessed by coronary computed tomographic angiography (CCTA) and risk of future acute coronary syndrome (ACS) is unknown. Objective: To examine whether CCTA-derived adverse geometric characteristics (AGCs) of coronary lesions describing location and vessel geometry add to plaque morphology and burden for identifying culprit lesion precursors associated with future ACS. Design, Setting, and Participants: This substudy of ICONIC (Incident Coronary Syndromes Identified by Computed Tomography), a multicenter nested case-control cohort study, included patients with ACS and a culprit lesion precursor identified on baseline CCTA (n = 116) and propensity score-matched non-ACS controls (n = 116). Data were collected from July 20, 2012, to April 30, 2017, and analyzed from October 1, 2020, to October 31, 2021. Exposures: Coronary lesions were evaluated for the following 3 AGCs: (1) distance from the coronary ostium to lesion; (2) location at vessel bifurcations; and (3) vessel tortuosity, defined as the presence of 1 bend of greater than 90° or 3 curves of 45° to 90° using a 3-point angle within the lesion. Main Outcomes and Measures: Association between lesion-level AGCs and risk of future ACS-causing culprit lesions. Results: Of 548 lesions, 116 culprit lesion precursors were identified in 116 patients (80 [69.0%] men; mean [SD], age 62.7 [11.5] years). Compared with nonculprit lesions, culprit lesion precursors had a shorter distance from the ostium (median, 35.1 [IQR, 23.6-48.4] mm vs 44.5 [IQR, 28.2-70.8] mm), more frequently localized to bifurcations (85 [73.3%] vs 168 [38.9%]), and had more tortuous vessel segments (5 [4.3%] vs 6 [1.4%]; all P <.05). In multivariable Cox regression analysis, an increasing number of AGCs was associated with a greater risk of future culprit lesions (hazard ratio [HR] for 1 AGC, 2.90 [95% CI, 1.38-6.08]; P =.005; HR for ≥2 AGCs, 6.84 [95% CI, 3.33-14.04]; P <.001). Adverse geometric characteristics provided incremental discriminatory value for culprit lesion precursors when added to a model containing stenosis severity, adverse morphological plaque characteristics, and quantitative plaque characteristics (area under the curve, 0.766 [95% CI, 0.718-0.814] vs 0.733 [95% CI, 0.685-0.782]). In per-patient comparison, patients with ACS had a higher frequency of lesions with adverse plaque characteristics, AGCs, or both compared with control patients (≥2 adverse plaque characteristics, 70 [60.3%] vs 50 [43.1%]; ≥2 AGCs, 92 [79.3%] vs 60 [51.7%]; ≥2 of both, 37 [31.9%] vs 20 [17.2%]; all P <.05). Conclusions and Relevance: These findings support the concept that CCTA-derived AGCs capturing lesion location and vessel geometry are associated with risk of future ACS-causing culprit lesions. Adverse geometric characteristics may provide additive prognostic information beyond plaque assessment in CCTA.

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U2 - https://doi.org/10.1001/jamacardio.2021.5705

DO - https://doi.org/10.1001/jamacardio.2021.5705

M3 - Article

C2 - 35080587

SN - 2380-6583

VL - 7

SP - 309

EP - 319

JO - JAMA Cardiology

JF - JAMA Cardiology

IS - 3

ER -

Association of Plaque Location and Vessel Geometry Determined by Coronary Computed Tomographic Angiography with Future Acute Coronary Syndrome-Causing Culprit Lesions

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