Assessment of Graft Perfusion and Oxygenation for Improved Outcome in Esophageal Cancer Surgery (EDOBS)

• ClinicalTrials.gov Identifier: NCT03587532
• Recruitment Status: Recruiting
• First Posted: July 16, 2018
• Last Update Posted: December 28, 2023
• Sponsor: University Hospital, Ghent
• Collaborator: Kom Op Tegen Kanker
• Information provided by (Responsible Party): University Hospital, Ghent

Study Description

Brief Summary:

After the esophagectomy, the stomach is most commonly used to restore continuity of the upper gastro-intestinal tract. The esophagogastric anastomosis is prone to serious complications such as anastomotic leakage (AL) The reported incidence of AL after esophagectomy ranges from 5%-20%. The AL associated mortality ranges from 18-40% compared with an overall in-hospital mortality of 4-6%. The main cause of AL is tissue hypoxia, which results from impaired perfusion of the pedicle stomach graft. Clinical judgment is unreliable in determining anastomotic perfusion. Therefore, an objective, validated, and reproducible method to evaluate tissue perfusion at the anastomotic site is urgently needed. Indocyanine green angiography (ICGA) is a near infrared fluorescent (NIRF) perfusion imaging using indocyanine green (ICG). ICGA is a safe, easy and reproducible method for graft perfusion analysis, but it is not yet calibrated. The purpose of this study is to evaluate the feasibility of quantification of ICGA to assess graft perfusion and its influence on AL in patients after minimally invasive Ivor Lewis esophagectomy (MIE) for cancer.

Condition or disease	Intervention/treatment	Phase
Anastomotic Leak; Esophageal Cancer	Diagnostic Test: Indocyanine green angiography; Diagnostic Test: Hemodynamic evaluation; Diagnostic Test: Biological and pathological markers of ischemia	Not Applicable

Detailed Description:

Background: The incidence of adenocarcinoma of the esophagus is rapidly increasing, resulting in 480 000 newly diagnosed patients annually in the world1. Surgery remains the cornerstone of therapy for curable esophageal cancer (EC) patients. After the esophagectomy, the stomach is most commonly used to restore continuity of the upper gastro-intestinal tract. The esophagogastric anastomosis is prone to serious complications such as anastomotic leakage (AL), fistula, bleeding, and stricture. The reported incidence of AL after esophagectomy ranges from 5%-20% 2-6. The AL associated mortality ranges from 18-40% compared with an overall in-hospital mortality of 4-6% 2, 7, 8. The main cause of AL is tissue hypoxia, which results from impaired perfusion of the pedicle stomach graft. Clinical judgment is unreliable in determining anastomotic perfusion. Therefore, an objective, validated, and reproducible method to evaluate tissue perfusion at the anastomotic site is urgently needed. Near infrared fluorescent (NIRF) perfusion imaging using indocyanine green (ICG) is an emerging modality based on excitation and resulting fluorescence in the near-infrared range (λ = 700-900 nm).

Aims:

• To perform intraoperative ICG based NIRF angiography of the stomach graft during minimally invasive esophagectomy in EC patients, and to calculate tissue blood flow and volume using curve analysis and advanced compartmental modeling;
• To validate imaging based perfusion parameters by comparison with hemodynamic parameters, blood and tissue expression of hypoxia induced markers, and tissue mitochondrial respiration rate
• To evaluate the ability of NIRF based perfusion measurement to predict anastomotic leakage.

Methods: Patients (N=70) with resectable EC will be recruited to undergo minimally invasive Ivor Lewis esophagectomy according to the current standard of care. ICG based angiography will be performed after creation of the stomach graft and after thoracic pull-up of the graft. Dynamic digital images will be obtained starting immediately after intravenous bolus administration of 0.5 mg/kg of ICG. The resulting images will be subjected to curve analysis (time to peak, washout time) and to compartmental analysis based on the AATH kinetic model (adiabatic approximation to tissue homogeneity, which allows to calculate blood flow, blood volume, vascular heterogeneity, and vascular leakage). The calculated perfusion parameters will be compared to intraoperative hemodynamic data (PiCCO catheter) to evaluate how patient hemodynamics affect graft perfusion. To verify whether graft perfusion truly represents tissue oxygenation, perfusion parameters will be compared with systemic lactate as well as serosal lactate from the stomach graft. In addition, perfusion parameters will be compared to tissue expression of hypoxia related markers and mitochondrial chain respiratory rate as measured in tissue samples from the stomach graft.

Finally, the ability of functional, histological, and cellular perfusion and oxygenation parameters to predict anastomotic leakage and postoperative morbidity in general will be evaluated using the appropriate univariate and multivariate statistical analyses.

Relevance: The results of this project may lead to a novel, reproducible, and minimally invasive method to objectively assess perioperative anastomotic perfusion during EC surgery. Such a tool may help to reduce the incidence of AL and its associated severe morbidity and mortality

Study Design

• Study Type: Interventional (Clinical Trial)
• Estimated Enrollment: 70 participants
• Allocation: N/A
• Intervention Model: Single Group Assignment
• Masking: None (Open Label)
• Primary Purpose: Diagnostic
• Official Title: Assessment of Graft Perfusion and Oxygenation for Improved Outcome in Esophageal Cancer Surgery
• Actual Study Start Date: December 13, 2021
• Estimated Primary Completion Date: December 31, 2024
• Estimated Study Completion Date: December 31, 2024

Arms and Interventions

Arm

Intervention/treatment

Experimental: Indocyanine Green Angiography; ICG based angiography after creation of the stomach graft and after thoracic pull-up of the graft. Dynamic digital images will be obtained starting immediately after intravenous bolus administration of 0.5 mg/kg of ICG.

Diagnostic Test: Indocyanine green angiography; ICGA will be performed twice during standard esophagectomy: 30 minutes after the stomach graft creation and immediately before the esophagogastric anastomosis. stock dose of 25 mg ICG (Pulsion Medical Systems, Germany) will be diluted to 5 mg/mL with sterile water. An IV bolus of 0.5 mg/kg of ICG will be injected via a central venous catheter. Video data will be obtained with a charge-coupled device (CCD) camera fitted with a light-emitting diode emitting at a wavelength of 760mm (Visera® elite II, Olympus medical system corp, Tokyo, Japan). Images will be recorded starting immediately prior to injection until 3 minutes afterwards.; Other Name: near infrared fluorescent imaging; Diagnostic Test: Hemodynamic evaluation; Advanced continuous hemodynamic monitoring during surgery will be performed using a PiCCO® (Pulse index Continuous Cardiac Output, Pulsion Medical Systems, Germany) catheter.; Diagnostic Test: Biological and pathological markers of ischemia; Systemic and local capillary lactate on blood samples; Mitochondrial Respiratory activity analyses on biopsies at 3 region of interest (ROI); Pathological analyses of the biopsies at 3 ROI

Outcome Measures

Primary Outcome Measures :

1. An ICGA based cutoff point to predict anastomotic leakage and graft necrosis after esophageal reconstructive surgery. [ Time Frame: within 3 months after intervention ]
   quantitative analysis of the ICGA images. T inflow will be calculated based on time fluorescence curves, and correlated with anastomotic leakage and graft necrosis. This cutoff value will be an ICGA fluorescent intensity time measurement expressed in seconds.

Secondary Outcome Measures :

1. The evaluation of ICGA as a quantitative perfusion imaging modality during gastric tube reconstruction. [ Time Frame: within 3 months after intervention ]
   First, intensity over time curves will be analysed in the regions of interest to generate quantitative values for maximal fluorescence intensity (I max), inflow time (T inflow), and outflow time (T outflow). For every patient a time intensity curve will be created and From that curve 3 quantitaive time measures will be extracted: for maximal fluorescence intensity (I max), inflow time (T inflow), and outflow time (T outflow). These 3 times will be expressed in seconds
2. Systemic lactate as a Biological Markers of hypoxia and ischemia [ Time Frame: within 24 hours after intervention ]
   Peroperative blood samples will be collected and analyzed
3. Capillary lactate as a Biological Markers of hypoxia and ischemia [ Time Frame: within 24 hours after intervention ]
   Peroperative blood samples will be collected and analyzed
4. Basal oxygen consumption (V0) as a Biological Markers of hypoxia and ischemia [ Time Frame: within 24 hours after intervention ]
   Peroperative biopsies will be collected and analyzed
5. Max respiratory oxygen consumption (Vmax) as a Biological Markers of hypoxia and ischemia [ Time Frame: within 24 hours after intervention ]
   Peroperative biopsies will be collected and analyzed
6. Severity of inflammation score as a pathological Markers of hypoxia and ischemia [ Time Frame: within 10 days after intervention ]

   Peroperative biopsies will be collected and analyzed. Four sections of the embedded material are examined using a Haematoxylin-eosin staining. A semiquantitive scoring based on presence of fibroblasts, polynuclear neutrophils, lymphocytes and macrophages will be used to evaluate the severity of the inflammation. Scoring system.

   Score 0 = normal mucosa Score 1: partial epithelial edema and necrosis Score 2: diffuse swelling and necrosis of the epithelium Score 3: necrosis with submucosal neutrophil infiltration Score 4: widespread necrosis and massive neutrophil infiltration and bleeding

7. HIF 1 alpha as a pathological Markers of hypoxia and ischemia [ Time Frame: within 10 days after intervention ]
   Peroperative biopsies will be collected and analyzed
8. Minor and major adverse events up to 30 days postoperative associated with esophagectomy [ Time Frame: within 1 year after intervention ]
   All adverse events will be classified by the Clavien Dindo score and based on the ECCG international consensus for complications associated with esophagectomy guidelines.The list is a predefined by the ECCG and can be found in reference 32.
9. Product related adverse endpoints [ Time Frame: within 24 hours after intervention ]
   • Anaphylactic adverse events (AE): discomfort, flushing, tachycardia, hypotension, dyspnoea, bronchial spasm, blushing, cardiac arrest, laryngeal spasm, and facial oedema.
   • Urticarial AE: pruritus, urticaria
   • Nausea.
   • hypereosinophilia
10. Intensive Care Unit (ICU) stay [ Time Frame: within 1 year after intervention ]
    duration of intensive care stay expressed in days
11. in hospital stay [ Time Frame: within 1 year after intervention ]
    duration of the in hospital stay expressed in days
12. cardiac output [ Time Frame: within 24 hours after the intervention ]
    Advanced continuous hemodynamic monitoring during surgery will be performed using a PiCCO® (Pulse index Continuous Cardiac Output, Pulsion Medical Systems, Germany). This will provide specific perfusion measurements as cardiac output expressed in liters per minute from the Pulse contour analysis and Thermo dilution analysis.
13. Stroke Volume [ Time Frame: within 24 hours after the intervention ]
    Advanced continuous hemodynamic monitoring during surgery will be performed using a PiCCO® (Pulse index Continuous Cardiac Output, Pulsion Medical Systems, Germany). This will provide specific perfusion measurements as Stroke Volume (SV) expressed in milliliter and stroke volume variation (SVV) to predict Volume responsivity by Pulse contour analysis and Thermo dilution analysis.
14. pulse pressure [ Time Frame: within 24 hours after the intervention ]
    Advanced continuous hemodynamic monitoring during surgery will be performed using a PiCCO® (Pulse index Continuous Cardiac Output, Pulsion Medical Systems, Germany). This will provide specific perfusion measurements as pulse pressure (PP) expressed in millimeters of mercury (mmHg) and pulse pressure variation (PPV) to predict volume responsivity by Pulse contour analysis.

Eligibility Criteria

• Ages Eligible for Study: 18 Years to 85 Years (Adult, Older Adult)
• Sexes Eligible for Study: All
• Accepts Healthy Volunteers: No

Criteria

Inclusion Criteria:

Pre- and intraoperatively

• Subjects ≥ 18 years and ≤ 75 years who are willing to participate and provide written informed consent prior to any study-related procedures.
• Subjects scheduled for elective minimally invasive Ivor Lewis esophagectomy
• Intrathoracic circular stapled esophago-gastric anastomosis

Exclusion Criteria:

Preoperatively

• Known hypersensitivity to ICG
• Female patients who are pregnant or nursing
• Participation in other studies involving investigational drugs or devices.
• Use of Avastin™ (bevacizumab) or other anti vascular endothelial growth factor (VEGF) agents within 30 days prior to surgery

Intra-operatively

• Intra-operative findings that may preclude conduct of the study procedures
• Anastomosis performed differently than the standard of care
• Excessive bleeding (>500 ml) prior to anastomosis

Contacts and Locations

Contacts

Contact: Elke Van Daele, MD; +323320829; elke.vandaele@uzgent.be

Contact: Yves Van Nieuwenhove, MD, PhD; +3293324893; Yves.Vannieuwenhove@uzgent.be

Locations

Belgium

University Hospital; Recruiting

Ghent, Belgium, 9000

Contact: Elke Van Daele, MD +32 9 332 08 29 elke.vandaele@uzgent.be

Sponsors and Collaborators

University Hospital, Ghent

Kom Op Tegen Kanker

Investigators

• Study Director: Yves Yves.Vannieuwenhove@uzgent.be, MD, PhD; University Hospital, Ghent

More Information

Additional Information:

Cancer Statistics, GLOBOCAN 2012: Estimated Cancer Incidence, Mortality and Prevalence Worldwide in 2012. International Agency for Research on Cancer, WHO. 

Publications:

Kassis ES, Kosinski AS, Ross P Jr, Koppes KE, Donahue JM, Daniel VC. Predictors of anastomotic leak after esophagectomy: an analysis of the society of thoracic surgeons general thoracic database. Ann Thorac Surg. 2013 Dec;96(6):1919-26. doi: 10.1016/j.athoracsur.2013.07.119. Epub 2013 Sep 24.

Biere SS, Maas KW, Cuesta MA, van der Peet DL. Cervical or thoracic anastomosis after esophagectomy for cancer: a systematic review and meta-analysis. Dig Surg. 2011;28(1):29-35. doi: 10.1159/000322014. Epub 2011 Feb 4.

Sauvanet A, Mariette C, Thomas P, Lozac'h P, Segol P, Tiret E, Delpero JR, Collet D, Leborgne J, Pradere B, Bourgeon A, Triboulet JP. Mortality and morbidity after resection for adenocarcinoma of the gastroesophageal junction: predictive factors. J Am Coll Surg. 2005 Aug;201(2):253-62. doi: 10.1016/j.jamcollsurg.2005.02.002.

Sunpaweravong S, Ruangsin S, Laohawiriyakamol S, Mahattanobon S, Geater A. Prediction of major postoperative complications and survival for locally advanced esophageal carcinoma patients. Asian J Surg. 2012 Jul;35(3):104-9. doi: 10.1016/j.asjsur.2012.04.029. Epub 2012 Jun 6.

Haga Y, Wada Y, Takeuchi H, Ikejiri K, Ikenaga M. Prediction of anastomotic leak and its prognosis in digestive surgery. World J Surg. 2011 Apr;35(4):716-22. doi: 10.1007/s00268-010-0922-5.

Rutegard M, Lagergren P, Rouvelas I, Lagergren J. Intrathoracic anastomotic leakage and mortality after esophageal cancer resection: a population-based study. Ann Surg Oncol. 2012 Jan;19(1):99-103. doi: 10.1245/s10434-011-1926-6. Epub 2011 Jul 19.

Van Daele E, Van de Putte D, Ceelen W, Van Nieuwenhove Y, Pattyn P. Risk factors and consequences of anastomotic leakage after Ivor Lewis oesophagectomydagger. Interact Cardiovasc Thorac Surg. 2016 Jan;22(1):32-7. doi: 10.1093/icvts/ivv276. Epub 2015 Oct 3.

Wright CD, Kucharczuk JC, O'Brien SM, Grab JD, Allen MS; Society of Thoracic Surgeons General Thoracic Surgery Database. Predictors of major morbidity and mortality after esophagectomy for esophageal cancer: a Society of Thoracic Surgeons General Thoracic Surgery Database risk adjustment model. J Thorac Cardiovasc Surg. 2009 Mar;137(3):587-95; discussion 596. doi: 10.1016/j.jtcvs.2008.11.042. Erratum In: J Thorac Cardiovasc Surg. 2009 Jun;137(6):1581.

Junemann-Ramirez M, Awan MY, Khan ZM, Rahamim JS. Anastomotic leakage post-esophagogastrectomy for esophageal carcinoma: retrospective analysis of predictive factors, management and influence on longterm survival in a high volume centre. Eur J Cardiothorac Surg. 2005 Jan;27(1):3-7. doi: 10.1016/j.ejcts.2004.09.018.

Markar SR, Arya S, Karthikesalingam A, Hanna GB. Technical factors that affect anastomotic integrity following esophagectomy: systematic review and meta-analysis. Ann Surg Oncol. 2013 Dec;20(13):4274-81. doi: 10.1245/s10434-013-3189-x. Epub 2013 Aug 14.

Alander JT, Kaartinen I, Laakso A, Patila T, Spillmann T, Tuchin VV, Venermo M, Valisuo P. A review of indocyanine green fluorescent imaging in surgery. Int J Biomed Imaging. 2012;2012:940585. doi: 10.1155/2012/940585. Epub 2012 Apr 22.

Milstein DMJ, Ince C, Gisbertz SS, Boateng KB, Geerts BF, Hollmann MW, van Berge Henegouwen MI, Veelo DP. Laser speckle contrast imaging identifies ischemic areas on gastric tube reconstructions following esophagectomy. Medicine (Baltimore). 2016 Jun;95(25):e3875. doi: 10.1097/MD.0000000000003875. Erratum In: Medicine (Baltimore). 2016 Jul 29;95(30):e87a5.

Linder G, Hedberg J, Bjorck M, Sundbom M. Perfusion of the gastric conduit during esophagectomy. Dis Esophagus. 2017 Jan 1;30(1):143-149. doi: 10.1111/dote.12537.

Pham TH, Perry KA, Enestvedt CK, Gareau D, Dolan JP, Sheppard BC, Jacques SL, Hunter JG. Decreased conduit perfusion measured by spectroscopy is associated with anastomotic complications. Ann Thorac Surg. 2011 Feb;91(2):380-5. doi: 10.1016/j.athoracsur.2010.10.006.

Tsekov C, Belyaev O, Tcholakov O, Tcherveniakov A. Intraoperative Doppler assessment of gastric tube perfusion in esophagogastroplasty. J Surg Res. 2006 May;132(1):98-103. doi: 10.1016/j.jss.2005.07.037. Epub 2005 Sep 12.

Koyanagi K, Ozawa S, Oguma J, Kazuno A, Yamazaki Y, Ninomiya Y, Ochiai H, Tachimori Y. Blood flow speed of the gastric conduit assessed by indocyanine green fluorescence: New predictive evaluation of anastomotic leakage after esophagectomy. Medicine (Baltimore). 2016 Jul;95(30):e4386. doi: 10.1097/MD.0000000000004386.

Zehetner J, DeMeester SR, Alicuben ET, Oh DS, Lipham JC, Hagen JA, DeMeester TR. Intraoperative Assessment of Perfusion of the Gastric Graft and Correlation With Anastomotic Leaks After Esophagectomy. Ann Surg. 2015 Jul;262(1):74-8. doi: 10.1097/SLA.0000000000000811.

Yukaya T, Saeki H, Kasagi Y, Nakashima Y, Ando K, Imamura Y, Ohgaki K, Oki E, Morita M, Maehara Y. Indocyanine Green Fluorescence Angiography for Quantitative Evaluation of Gastric Tube Perfusion in Patients Undergoing Esophagectomy. J Am Coll Surg. 2015 Aug;221(2):e37-42. doi: 10.1016/j.jamcollsurg.2015.04.022. Epub 2015 Apr 30. No abstract available.

Campbell C, Reames MK, Robinson M, Symanowski J, Salo JC. Conduit Vascular Evaluation is Associated with Reduction in Anastomotic Leak After Esophagectomy. J Gastrointest Surg. 2015 May;19(5):806-12. doi: 10.1007/s11605-015-2794-3. Epub 2015 Mar 20.

Kamiya K, Unno N, Miyazaki S, Sano M, Kikuchi H, Hiramatsu Y, Ohta M, Yamatodani T, Mineta H, Konno H. Quantitative assessment of the free jejunal graft perfusion. J Surg Res. 2015 Apr;194(2):394-399. doi: 10.1016/j.jss.2014.10.049. Epub 2014 Nov 5.

Kumagai Y, Ishiguro T, Haga N, Kuwabara K, Kawano T, Ishida H. Hemodynamics of the reconstructed gastric tube during esophagectomy: assessment of outcomes with indocyanine green fluorescence. World J Surg. 2014 Jan;38(1):138-43. doi: 10.1007/s00268-013-2237-9.

Diana M, Agnus V, Halvax P, Liu YY, Dallemagne B, Schlagowski AI, Geny B, Diemunsch P, Lindner V, Marescaux J. Intraoperative fluorescence-based enhanced reality laparoscopic real-time imaging to assess bowel perfusion at the anastomotic site in an experimental model. Br J Surg. 2015 Jan;102(2):e169-76. doi: 10.1002/bjs.9725.

Diana M, Halvax P, Dallemagne B, Nagao Y, Diemunsch P, Charles AL, Agnus V, Soler L, Demartines N, Lindner V, Geny B, Marescaux J. Real-time navigation by fluorescence-based enhanced reality for precise estimation of future anastomotic site in digestive surgery. Surg Endosc. 2014 Nov;28(11):3108-18. doi: 10.1007/s00464-014-3592-9. Epub 2014 Jun 10.

Diana M, Dallemagne B, Chung H, Nagao Y, Halvax P, Agnus V, Soler L, Lindner V, Demartines N, Diemunsch P, Geny B, Swanstrom L, Marescaux J. Probe-based confocal laser endomicroscopy and fluorescence-based enhanced reality for real-time assessment of intestinal microcirculation in a porcine model of sigmoid ischemia. Surg Endosc. 2014 Nov;28(11):3224-33. doi: 10.1007/s00464-014-3595-6. Epub 2014 Jun 17.

Publications automatically indexed to this study by ClinicalTrials.gov Identifier (NCT Number):

Van Daele E, Van Nieuwenhove Y, Ceelen W, Vanhove C, Braeckman BP, Hoorens A, Van Limmen J, Varin O, Van de Putte D, Willaert W, Pattyn P. Assessment of graft perfusion and oxygenation for improved outcome in esophageal cancer surgery: Protocol for a single-center prospective observational study. Medicine (Baltimore). 2018 Sep;97(38):e12073. doi: 10.1097/MD.0000000000012073.

• Responsible Party: University Hospital, Ghent
• ClinicalTrials.gov Identifier: NCT03587532
• Other Study ID Numbers: EC/2018/0671
• First Posted: July 16, 2018
• Last Update Posted: December 28, 2023
• Last Verified: December 2023

• Studies a U.S. FDA-regulated Drug Product: No
• Studies a U.S. FDA-regulated Device Product: No
• Product Manufactured in and Exported from the U.S.: No

Keywords provided by University Hospital, Ghent:

esophagectomy; indocyanine green; near infrared fluorescence

Additional relevant MeSH terms:

Esophageal Neoplasms; Anastomotic Leak; Gastrointestinal Neoplasms; Digestive System Neoplasms; Neoplasms by Site; Neoplasms; Head and Neck Neoplasms; Digestive System Diseases; Esophageal Diseases; Gastrointestinal Diseases; Postoperative Complications; Pathologic Processes