Indocyanine Green Fluorescence for Free-Flap Perfusion Imaging Revisited: Advanced Decision Making by Virtual Perfusion Reality in Visionsense Fusion Imaging Angiography

Amir Khosrow Bigdeli; Emre Gazyakan; Volker Juergen Schmidt; Frederick Jochen Hernekamp; Leila Harhaus; Thomas Henzler; Thomas Kremer; Ulrich Kneser; Christoph Hirche

doi:10.1177/1553350615610651

Indocyanine Green Fluorescence for Free-Flap Perfusion Imaging Revisited: Advanced Decision Making by Virtual Perfusion Reality in Visionsense Fusion Imaging Angiography

Surg Innov. 2016 Jun;23(3):249-60. doi: 10.1177/1553350615610651. Epub 2015 Oct 15.

Authors

Amir Khosrow Bigdeli¹, Emre Gazyakan¹, Volker Juergen Schmidt¹, Frederick Jochen Hernekamp¹, Leila Harhaus¹, Thomas Henzler², Thomas Kremer¹, Ulrich Kneser¹, Christoph Hirche³

Affiliations

¹ University of Heidelberg, Heidelberg, Germany.
² Medical Faculty Mannheim, University of Heidelberg, Mannheim, Germany.
³ University of Heidelberg, Heidelberg, Germany Christoph.Hirche@bgu-ludwigshafen.de.

PMID: 26474605
DOI: 10.1177/1553350615610651

Abstract

Background: Near-infrared indocyanine green video angiography (ICG-NIR-VA) has been introduced for free-flap surgery and may provide intraoperative flap designing as well as postoperative monitoring. Nevertheless, the technique has not been established in clinical routine because of controversy over benefits. Improved technical features of the novel Visionsense ICG-NIR-VA surgery system are promising to revisit the field of application. It features a unique real-time fusion image of simultaneous NIR and white light visualization, with highlighted perfusion, including a color-coded perfusion flow scale for optimized anatomical understanding.

Methods: In a feasibility study, the Visionsense ICG-NIR-VA system was applied during 10 free-flap surgeries in 8 patients at our center. Indications included anterior lateral thigh (ALT) flap (n = 4), latissimus dorsi muscle flap (n = 1), tensor fascia latae flap (n = 1), and two bilateral deep inferior epigastric artery perforator flaps (n = 4). The system was used intraoperatively and postoperatively to investigate its impact on surgical decision making and to observe perfusion patterns correlated to clinical monitoring.

Results: Visionsense ICG-NIR-VA aided assessing free-flap design and perfusion patterns in all cases and correlated with clinical observations. Additional interventions were performed in 2 cases (22%). One venous anastomosis was revised, and 1 flap was redesigned. Indicated by ICG-NIR-VA, 1 ALT flap developed partial flap necrosis (11%).

Conclusions: The Visionsense ICG-NIR-VA system allowed a virtual view of flap perfusion anatomy by fusion imaging in real-time. The system improved decision making for flap design and surgical decisions. Clinical and ICG-NIR-VA parameters correlated. Its future implementation may aid in improving outcomes for free-flap surgery, but additional experience is needed to define its final role.

Keywords: 3D anatomy; ICG; Visionsense; angiography; free flap; fusion image; indocyanine green; microsurgery.

MeSH terms

Aged
Feasibility Studies
Female
Fluorescein Angiography*
Follow-Up Studies
Free Tissue Flaps / blood supply*
Free Tissue Flaps / transplantation
Graft Rejection
Graft Survival
Humans
Indocyanine Green*
Male
Middle Aged
Myocutaneous Flap / blood supply
Myocutaneous Flap / transplantation
Optical Imaging / methods*
Perfusion Imaging / methods*
Plastic Surgery Procedures / adverse effects
Plastic Surgery Procedures / methods*
Sampling Studies

Substances

Indocyanine Green