BACKGROUND: Stent edge restenosis (SER) remains a potential limitation of drug-eluting stents. The aim of this study was to determine optical coherence tomography (OCT) predictors for angiographic late SER after everolimus-eluting stent implantation. METHODS AND RESULTS: We retrospectively analyzed 319 patients who underwent OCT immediately after everolimus-eluting stent implantation and scheduled 9- to 12-month follow-up angiography. The binary angiographic SER rate was 10% (32/319) in the patients, 8.4% (32/382) in lesions, and 4.4% (33/744) in stent edge segments. In the stent edge segments at post stenting, OCT-derived lipidic plaque (61% versus 20%; P<0.001) was more often observed in the SER group, and OCT-measured minimum lumen area (4.13±2.61 versus 5.58±2.46 mm2; P=0.001) was significantly smaller in the SER group compared with the non-SER group. Multivariate analysis identified lipidic plaque (odds ratio: 5.99; 95% confidence interval: 2.89-12.81; P<0.001) and minimum lumen area (odds ratio: 0.64; 95% confidence interval: 0.42-0.96; P=0.029) as independent predictors of binary SER. Receiver-operating characteristic analysis demonstrated that lipid arc of 185° (sensitivity: 71%; specificity: 72%; area under the curve: 0.761) and minimum lumen area of 4.10 mm2 (sensitivity: 67%; specificity: 77%; area under the curve: 0.787) were optimal cutoff values for predicting ischemia-driven SER. CONCLUSIONS: The present OCT study demonstrated that lipidic plaque and minimum lumen area in the stent edge segments at post stenting were associated with late SER after everolimus-eluting stent implantation. OCT provides valuable information to determine an appropriate landing zone for stent implantation.
BACKGROUND: Stent edge restenosis (SER) remains a potential limitation of drug-eluting stents. The aim of this study was to determine optical coherence tomography (OCT) predictors for angiographic late SER after everolimus-eluting stent implantation. METHODS AND RESULTS: We retrospectively analyzed 319 patients who underwent OCT immediately after everolimus-eluting stent implantation and scheduled 9- to 12-month follow-up angiography. The binary angiographic SER rate was 10% (32/319) in the patients, 8.4% (32/382) in lesions, and 4.4% (33/744) in stent edge segments. In the stent edge segments at post stenting, OCT-derived lipidic plaque (61% versus 20%; P<0.001) was more often observed in the SER group, and OCT-measured minimum lumen area (4.13±2.61 versus 5.58±2.46 mm2; P=0.001) was significantly smaller in the SER group compared with the non-SER group. Multivariate analysis identified lipidic plaque (odds ratio: 5.99; 95% confidence interval: 2.89-12.81; P<0.001) and minimum lumen area (odds ratio: 0.64; 95% confidence interval: 0.42-0.96; P=0.029) as independent predictors of binary SER. Receiver-operating characteristic analysis demonstrated that lipid arc of 185° (sensitivity: 71%; specificity: 72%; area under the curve: 0.761) and minimum lumen area of 4.10 mm2 (sensitivity: 67%; specificity: 77%; area under the curve: 0.787) were optimal cutoff values for predicting ischemia-driven SER. CONCLUSIONS: The present OCT study demonstrated that lipidic plaque and minimum lumen area in the stent edge segments at post stenting were associated with late SER after everolimus-eluting stent implantation. OCT provides valuable information to determine an appropriate landing zone for stent implantation.
Authors: Makoto Araki; Seung-Jung Park; Harold L Dauerman; Shiro Uemura; Jung-Sun Kim; Carlo Di Mario; Thomas W Johnson; Giulio Guagliumi; Adnan Kastrati; Michael Joner; Niels Ramsing Holm; Fernando Alfonso; William Wijns; Tom Adriaenssens; Holger Nef; Gilles Rioufol; Nicolas Amabile; Geraud Souteyrand; Nicolas Meneveau; Edouard Gerbaud; Maksymilian P Opolski; Nieves Gonzalo; Guillermo J Tearney; Brett Bouma; Aaron D Aguirre; Gary S Mintz; Gregg W Stone; Christos V Bourantas; Lorenz Räber; Sebastiano Gili; Kyoichi Mizuno; Shigeki Kimura; Toshiro Shinke; Myeong-Ki Hong; Yangsoo Jang; Jin Man Cho; Bryan P Yan; Italo Porto; Giampaolo Niccoli; Rocco A Montone; Vikas Thondapu; Michail I Papafaklis; Lampros K Michalis; Harmony Reynolds; Jacqueline Saw; Peter Libby; Giora Weisz; Mario Iannaccone; Tommaso Gori; Konstantinos Toutouzas; Taishi Yonetsu; Yoshiyasu Minami; Masamichi Takano; O Christopher Raffel; Osamu Kurihara; Tsunenari Soeda; Tomoyo Sugiyama; Hyung Oh Kim; Tetsumin Lee; Takumi Higuma; Akihiro Nakajima; Erika Yamamoto; Krzysztof L Bryniarski; Luca Di Vito; Rocco Vergallo; Francesco Fracassi; Michele Russo; Lena M Seegers; Iris McNulty; Sangjoon Park; Marc Feldman; Javier Escaned; Francesco Prati; Eloisa Arbustini; Fausto J Pinto; Ron Waksman; Hector M Garcia-Garcia; Akiko Maehara; Ziad Ali; Aloke V Finn; Renu Virmani; Annapoorna S Kini; Joost Daemen; Teruyoshi Kume; Kiyoshi Hibi; Atsushi Tanaka; Takashi Akasaka; Takashi Kubo; Satoshi Yasuda; Kevin Croce; Juan F Granada; Amir Lerman; Abhiram Prasad; Evelyn Regar; Yoshihiko Saito; Mullasari Ajit Sankardas; Vijayakumar Subban; Neil J Weissman; Yundai Chen; Bo Yu; Stephen J Nicholls; Peter Barlis; Nick E J West; Armin Arbab-Zadeh; Jong Chul Ye; Jouke Dijkstra; Hang Lee; Jagat Narula; Filippo Crea; Sunao Nakamura; Tsunekazu Kakuta; James Fujimoto; Valentin Fuster; Ik-Kyung Jang Journal: Nat Rev Cardiol Date: 2022-04-21 Impact factor: 49.421
Authors: Chinmay Khandkar; Mahesh V Madhavan; James C Weaver; David S Celermajer; Keyvan Karimi Galougahi Journal: Cells Date: 2021-04-10 Impact factor: 6.600