Davis D, Ramamoorthy L, Pottakkat B (2020) Impact of stoma on lifestyle and health-related quality of life in patients living with stoma: a cross-sectional study. J Educ Health Promot 9:328–328
Article PubMed PubMed Central Google Scholar
La Regina D, Di Giuseppe M, Lucchelli M, Saporito A, Boni L, Efthymiou C, Cafarotti S, Marengo M, Mongelli F (2019) Financial impact of anastomotic leakage in colorectal surgery. J Gastrointest Surg 23:580–586
Noh GT, Ann YS, Cheong C, Han J, Cho MS, Hur H, Min BS, Lee KY, Kim NK (2016) Impact of anastomotic leakage on long-term oncologic outcome and its related factors in rectal cancer. Medicine (Baltimore) 95:e4367
Liu RQ, Elnahas A, Tang E, Alkhamesi NA, Hawel J, Alnumay A, Schlachta CM (2022) Cost analysis of indocyanine green fluorescence angiography for prevention of anastomotic leakage in colorectal surgery. Surg Endosc 36:9281–9287
Tang G, Du D, Tao J, Wei Z (2022) Effect of indocyanine green fluorescence angiography on anastomotic leakage in patients undergoing colorectal surgery: a meta-analysis of randomized controlled trials and propensity-score-matched studies. Front Surg 9:815753
Article PubMed PubMed Central Google Scholar
Watanabe J, Takemasa I, Kotake M, Noura S, Kimura K, Suwa H, Tei M, Takano Y, Munakata K, Matoba S, Yamagishi S, Yasui M, Kato T, Ishibe A, Shiozawa M, Ishii Y, Yabuno T, Nitta T, Saito S, Saigusa Y, Watanabe M (2023) Blood perfusion assessment by indocyanine green fluorescence imaging for minimally invasive rectal cancer surgery (EssentiAL trial): a randomized clinical trial. Ann Surg 278:e688–e694
Dip F, Boni L, Bouvet M, Carus T, Diana M, Falco J, Gurtner GC, Ishizawa T, Kokudo N, Lo Menzo E, Low PS, Masia J, Muehrcke D, Papay FA, Pulitano C, Schneider-Koraith S, Sherwinter D, Spinoglio G, Stassen L, Urano Y, Vahrmeijer A, Vibert E, Warram J, Wexner SD, White K, Rosenthal RJ (2022) Consensus conference statement on the general use of near-infrared fluorescence imaging and indocyanine green guided surgery: results of a modified Delphi study. Ann Surg 275:685–691
Hardy NP, Dalli J, Khan MF, Andrejevic P, Neary PM, Cahill RA (2021) Inter-user variation in the interpretation of near infrared perfusion imaging using indocyanine green in colorectal surgery. Surg Endosc 35:7074–7081
Dalli J, Loughman E, Hardy N, Sarkar A, Khan MF, Khokhar HA, Huxel P, O’Shea DF, Cahill RA (2021) Digital dynamic discrimination of primary colorectal cancer using systemic indocyanine green with near-infrared endoscopy. Sci Rep 11:11349
Article CAS PubMed PubMed Central Google Scholar
Joosten JJ, Bloemen PR, Van Den Elzen RM, Dalli J, Cahill RA, Van Berge Henegouwen MI, Hompes R, De Bruin DM (2023) Investigating and compensating for periphery-center effect among commercial near infrared imaging systems using an indocyanine green phantom. Appl Sci 13:2042
Dalli J, Jindal A, Gallagher G, Epperlein JP, Hardy NP, Re M, O’Donoghue K, Cantillon-Murphy P, Mac Aonghusa PG, Cahill RA (2023) Evaluating clinical near-infrared surgical camera systems with a view to optimizing operator and computational signal analysis. J Biomed Opt 28:035002
Article CAS PubMed PubMed Central Google Scholar
Dalli J, Hardy N, Mac Aonghusa PG, Epperlein JP, Cantillon Murphy P, Cahill RA (2021) Challenges in the interpretation of colorectal indocyanine green fluorescence angiography—a video vignette. Colorectal Dis 23:1289–1290
Kim GY, Bae KS, Noh GJ, Min WK (2009) Estimation of indocyanine green elimination rate constant k and retention rate at 15 min using patient age, weight, bilirubin, and albumin. J Hepatobiliary Pancreat Surg 16:521
Vos JJ, Scheeren TWL, Wietasch GJK (2010) Pulse dye densitometry and indocyanine green plasma disappearance: the issue of “normal” values. Anesth Analg 111:1075–1076
Harper D, Chandler B (2015) Splanchnic circulation. BJA Educ 16:66–71
Dalli J, Joosten JJ, Jindal A, Hardy NP, Camilleri-Brennan J, Andrejevic P, Hompes R, Cahill RA (2023) Impact of standardising indocyanine green fluorescence angiography technique for visual and quantitative interpretation on interuser variability in colorectal surgery. Surg Endosc 38:1306–1315
Dalli J, Shanahan S, Hardy NP, Chand M, Hompes R, Jayne D, Ris F, Spinelli A, Wexner S, Cahill RA (2022) Deconstructing mastery in colorectal fluorescence angiography interpretation. Surg Endosc 36:8764–8773
Article PubMed PubMed Central Google Scholar
Soares AS, Clancy NT, Bano S, Raza I, Diana M, Lovat LB, Stoyanov D, Chand M (2022) Interobserver variability in the assessment of fluorescence angiography in the colon. Surg Innov 30:45–49
Lütken CD, Achiam MP, Osterkamp J, Svendsen MB, Nerup N (2021) Quantification of fluorescence angiography: toward a reliable intraoperative assessment of tissue perfusion—a narrative review. Langenbecks Arch Surg 406:251–259
Son GM, Kwon MS, Kim Y, Kim J, Kim SH, Lee JW (2019) Quantitative analysis of colon perfusion pattern using indocyanine green (ICG) angiography in laparoscopic colorectal surgery. Surg Endosc 33:1640–1649
Wada T, Kawada K, Takahashi R, Yoshitomi M, Hida K, Hasegawa S, Sakai Y (2017) ICG fluorescence imaging for quantitative evaluation of colonic perfusion in laparoscopic colorectal surgery. Surg Endosc 31:4184–4193
Park S-H, Park H-M, Baek K-R, Ahn H-M, Lee IY, Son GM (2020) Artificial intelligence based real-time microcirculation analysis system for laparoscopic colorectal surgery. World J Gastroenterol 26:6945–6962
Article CAS PubMed PubMed Central Google Scholar
Ris F, Hompes R, Cunningham C, Lindsey I, Guy R, Jones O, George B, Cahill RA, Mortensen NJ (2014) Near-infrared (NIR) perfusion angiography in minimally invasive colorectal surgery. Surg Endosc 28:2221–2226
Article PubMed PubMed Central Google Scholar
Diana M, Agnus V, Halvax P, Liu YY, Dallemagne B, Schlagowski AI, Geny B, Diemunsch P, Lindner V, Marescaux J (2015) Intraoperative fluorescence-based enhanced reality laparoscopic real-time imaging to assess bowel perfusion at the anastomotic site in an experimental model. Br J Surg 102:e169-176
Article CAS PubMed Google Scholar
Epperlein JP, Hardy NP, Aonghusa PM, Cahill RA (2022) Extracting, visualizing, and learning from dynamic data: perfusion in surgical video for tissue characterization. IEEE
Goncalves LN, Van Den Hoven P, Van Schaik J, Leeuwenburgh L, Hendricks CHF, Verduijn PS, Van Der Bogt KEA, Van Rijswijk CSP, Schepers A, Vahrmeijer AL, Hamming JF, Van Der Vorst JR (2021) Perfusion parameters in near-infrared fluorescence imaging with indocyanine green: a systematic review of the literature. Life 11:433
Article CAS PubMed PubMed Central Google Scholar
Gasperi AD, Mazza E, Prosperi M (2016) Indocyanine green kinetics to assess liver function: ready for a clinical dynamic assessment in major liver surgery? World J Hepatol 8:355
Article PubMed PubMed Central Google Scholar
Larsen PO, Nerup N, Andersen J, Dohrn N, Klein MF, Brisling S, Salomon S, Andersen PV, Möller S, Svendsen MBS, Rahr HB, Iversen LH, Gögenur I, Qvist N, Ellebaek MB (2023) Anastomotic perfusion assessment with indocyanine green in robot-assisted low-anterior resection, a multicenter study of interobserver variation. Surg Endosc 37:3602–3609
Article PubMed PubMed Central Google Scholar
Cahill RA, O’Shea DF, Khan MF, Khokhar HA, Epperlein JP, Mac Aonghusa PG, Nair R, Zhuk SM (2020) Artificial intelligence indocyanine green (ICG) perfusion for colorectal cancer intra-operative tissue classification. Br J Surg 108:5–9
Zhuk S, Epperlein JP, Nair R, Tirupathi S, Mac Aonghusa P, O’Shea DF, Cahill R (2020) Perfusion quantification from endoscopic videos: learning to read tumor signatures. In: Martel AL, Abolmaesumi P, Stoyanov D, Mateus D, Zuluaga MA, Zhou SK, Racoceanu D, Joskowicz L (eds) Medical image computing and computer assisted intervention—MICCAI 2020. Springer, Cham, pp 711–721
Savitzky A, Golay MJE (1964) Smoothing and differentiation of data by simplified least squares procedures. Anal Chem 36:1627–1639
Jaccard P (1912) The distribution of the flora in the alpine zone.1. New Phytol 11:37–50
Schober P, Boer C, Schwarte LA (2018) Correlation coefficients: appropriate use and interpretation. Anesth Analg 126:1763–1768
Jafari MD, Pigazzi A, McLemore EC, Mutch MG, Haas E, Rasheid SH, Wait AD, Paquette IM, Bardakcioglu O, Safar B, Landmann RG, Varma MG, Maron DJ, Martz J, Bauer JJ, George VV, Fleshman JWJ, Steele SR, Stamos MJ (2021) Perfusion assessment in left-sided/low anterior resection (PILLAR III): a randomized, controlled, parallel, multicenter study assessing perfusion outcomes with PINPOINT near-infrared fluorescence imaging in low anterior resection. Dis Colon Rectum 64:995–1002
De Nardi P, Elmore U, Maggi G, Maggiore R, Boni L, Cassinotti E, Fumagalli U, Gardani M, De Pascale S, Parise P, Vignali A, Rosati R (2020) Intraoperative angiography with indocyanine green to assess anastomosis perfusion in patients undergoing laparoscopic colorectal resection: results of a multicenter randomized controlled trial. Surg Endosc 34:53–60
Armstrong G, Croft J, Corrigan N, Brown JM, Goh V, Quirke P, Hulme C, Tolan D, Kirby A, Cahill R, O’Connell PR, Miskovic D, Coleman M, Jayne D (2018) IntAct: intra-operative fluorescence angiography to prevent anastomotic leak in rectal cancer surgery: a randomized controlled trial. Colorectal Dis 20:O226–O234
Article CAS PubMed PubMed Central Google Scholar
Perfusiontech (2023) Perfusion Tech
D’Urso A, Agnus V, Barberio M, Seeliger B, Marchegiani F, Charles A-L, Geny B, Marescaux J, Mutter D, Diana M (2021) Computer-assisted quantification and visualization of bowel perfusion using fluorescence-based enhanced reality in left-sided colonic resections. Surg Endosc 35:4321–4331
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