Comparison of Hyperspectral Imaging and Microvascular Doppler for Perfusion Monitoring of Free Flaps in an In Vivo Rodent Model

To reduce microvascular free flap failure (MFF), monitoring is crucial for the early detection of malperfusion and allows timely salvage. Therefore, the aim of this study was to evaluate hyperspectral imaging (HSI) in comparison to micro-Doppler sonography (MDS) to monitor MFF perfusion in an in vivo rodent model. Bilateral groin flaps were raised on 20 Sprague–Dawley rats. The femoral artery was transected on the trial side and re-anastomosed. Flaps and anastomoses were assessed before, during, and after the period of ischemia every ten minutes for overall 60 min using HSI and MDS. The contralateral sides’ flaps served as controls. Tissue-oxygenation saturation (StO2), near-infrared perfusion index (NPI), hemoglobin (THI), and water distribution (TWI) were assessed by HSI, while blood flow was assessed by MDS. HSI correlates with the MDS signal in the case of sufficient and completely interrupted perfusion. HSI was able to validly and reproducibly detect tissue perfusion status using StO2 and NPI. After 40 min, flap perfusion decreased due to the general aggravation of hemodynamic circulatory situation, which resulted in a significant drop of StO2 (p < 0.005) and NPI (p < 0.005), whereas the Doppler signal remained unchanged. In accordance, HSI might be suitable to detect MFF general complications in an early stage and further decrease MFF failure rates, whereas MDS may only be used for direct complications at the anastomose site.

[1]  E. C. Lai,et al.  Comparing tissue oximetry to doppler monitoring in 1367 consecutive breast free flaps , 2022, Microsurgery.

[2]  A. Cai,et al.  Intra- and Early Postoperative Evaluation of Malperfused Areas in an Irradiated Random Pattern Skin Flap Model Using Indocyanine Green Angiography and Near-Infrared Reflectance-Based Imaging and Infrared Thermography , 2022, Journal of personalized medicine.

[3]  R. R. van der Hulst,et al.  Near-Infrared Spectroscopy (NIRS) versus Hyperspectral Imaging (HSI) to Detect Flap Failure in Reconstructive Surgery: A Systematic Review , 2022, Life.

[4]  B. Al-Nawas,et al.  New Approach to the Old Challenge of Free Flap Monitoring—Hyperspectral Imaging Outperforms Clinical Assessment by Earlier Detection of Perfusion Failure , 2021, Journal of personalized medicine.

[5]  B. Al-Nawas,et al.  Hyperspectral imaging and artificial intelligence to detect oral malignancy – part 1 - automated tissue classification of oral muscle, fat and mucosa using a light-weight 6-layer deep neural network , 2021, Head & Face Medicine.

[6]  Y. Ducic,et al.  Implantable Doppler Removal After Free Flap Monitoring Among Head and Neck Microvascular Surgeons , 2021, The Laryngoscope.

[7]  N. Banhidy,et al.  Quantifying the Limitations of Clinical and Technology-based Flap Monitoring Strategies using a Systematic Thematic Analysis , 2021, Plastic and reconstructive surgery. Global open.

[8]  D. Thiem,et al.  Is Hyperspectral Imaging Suitable for Assessing Collateral Circulation Prior Radial Forearm Free Flap Harvesting? Comparison of Hyperspectral Imaging and Conventional Allen’s Test , 2021, Journal of personalized medicine.

[9]  G. Osterhoff,et al.  Hyperspectral Imaging (HSI) as a new diagnostic tool in free flap monitoring for soft tissue reconstruction: a proof of concept study , 2021, BMC Surgery.

[10]  Hung-Chi Chen,et al.  Three salvage strategies in microvascular fibula osteocutaneous flap for mandible reconstruction with vascular compromise and establishment of an algorithm , 2021, Microsurgery.

[11]  K. Fung,et al.  Implantable Doppler Ultrasound Monitoring in Head and Neck Free Flaps: Balancing the Pros and Cons , 2020, The Laryngoscope.

[12]  M. Wax,et al.  Factors impacting successful salvage of the failing free flap , 2020, Head & neck.

[13]  Yunghan Au,et al.  Hyperspectral imaging in wound care: A systematic review , 2020, International wound journal.

[14]  B. Al-Nawas,et al.  Hyperspectral analysis for perioperative perfusion monitoring—a clinical feasibility study on free and pedicled flaps , 2020, Clinical Oral Investigations.

[15]  N. Krezdorn,et al.  Cook–Swartz Doppler Probe Surveillance for Free Flaps—Defining Pros and Cons , 2020, The Surgery Journal.

[16]  R. Schmelzeisen,et al.  Retrospective evaluation of diagnostic accuracy of free flap monitoring with the Cook-Swartz-Doppler probe in head and neck reconstruction. , 2019, Journal of cranio-maxillo-facial surgery : official publication of the European Association for Cranio-Maxillo-Facial Surgery.

[17]  E. Rosenthal,et al.  Outcomes and cost implications of microvascular reconstructions of the head and neck , 2019, Head & neck.

[18]  M. Montella,et al.  A rat model of acute kidney injury through systemic hypoperfusion evaluated by micro-US, color and PW-Doppler , 2018, La radiologia medica.

[19]  M. Bater,et al.  Free Flap Head and Neck Reconstruction with an Emphasis on Postoperative Care , 2018, Facial Plastic Surgery.

[20]  Peer W Kämmerer,et al.  Hyperspectral imaging in perfusion and wound diagnostics – methods and algorithms for the determination of tissue parameters , 2018, Biomedizinische Technik. Biomedical engineering.

[21]  Axel Kulcke,et al.  A compact hyperspectral camera for measurement of perfusion parameters in medicine , 2018, Biomedizinische Technik. Biomedical engineering.

[22]  Amadeus Holmer,et al.  Hyperspectral imaging for monitoring of perfusion failure upon microvascular anastomosis in the rat hind limb. , 2018, Microvascular research.

[23]  M. Heiland,et al.  Free flap surgery in Europe: an interdisciplinary survey. , 2017, International journal of oral and maxillofacial surgery.

[24]  Hajime Matsumine,et al.  Hyperspectral Imaging Provides Early Prediction of Random Axial Flap Necrosis in a Preclinical Model , 2017, Plastic and reconstructive surgery.

[25]  Catherine S. Chang,et al.  Complications and Cost Analysis of Intraoperative Arterial Complications in Head and Neck Free Flap Reconstruction , 2017, Journal of Reconstructive Microsurgery.

[26]  Yuan-Yu Hsueh,et al.  Implantable Doppler Probes for Postoperatively Monitoring Free Flaps: Efficacy. A Systematic Review and Meta-analysis , 2016, Plastic and reconstructive surgery. Global open.

[27]  Hagen Malberg,et al.  Oxygenation and perfusion monitoring with a hyperspectral camera system for chemical based tissue analysis of skin and organs , 2016, Physiological measurement.

[28]  Zhao-feng Han,et al.  A comparison of the Cook-Swartz Doppler with conventional clinical methods for free flap monitoring: A systematic review and a meta-analysis. , 2016, International journal of surgery.

[29]  Frank Hölzle,et al.  Microsurgical reconstruction of the head and neck region: Current concepts of maxillofacial surgery units worldwide. , 2015, Journal of cranio-maxillo-facial surgery : official publication of the European Association for Cranio-Maxillo-Facial Surgery.

[30]  K. Jenderka,et al.  Verfahren der Dopplersonographie , 2015, Der Radiologe.

[31]  Michael P. Chae,et al.  Current Evidence for Postoperative Monitoring of Microvascular Free Flaps: A Systematic Review , 2015, Annals of plastic surgery.

[32]  Roxana Savastru,et al.  Characterization of burns using hyperspectral imaging technique - a preliminary study. , 2015, Burns : journal of the International Society for Burn Injuries.

[33]  T. Mücke,et al.  Microsurgical reconstruction of the head and neck--current concepts of maxillofacial surgery in Europe. , 2014, Journal of cranio-maxillo-facial surgery : official publication of the European Association for Cranio-Maxillo-Facial Surgery.

[34]  Y. Kuo,et al.  Free tissue transfers in head and neck reconstruction: Complications, outcomes and strategies for management of flap failure: Analysis of 2019 flaps in single institute , 2014, Microsurgery.

[35]  J. Wallmichrath,et al.  The free groin flap in the rat: a model for improving microsurgical skills and for microvascular perfusion studies , 2014, Journal of plastic surgery and hand surgery.

[36]  Joseph Meyerson,et al.  A review of devices used in the monitoring of microvascular free tissue transfers , 2013, Expert review of medical devices.

[37]  M. Rollins,et al.  Factors Affecting the Performance of 5 Cerebral Oximeters During Hypoxia in Healthy Volunteers , 2013, Anesthesia and analgesia.

[38]  Hin-Lun Liu Microvascular Anastomosis of Submillimeter Vessels—A Training Model in Rats , 2013, Journal of Hand and Microsurgery.

[39]  P. Pohlenz,et al.  Microvascular free flaps in head and neck surgery: complications and outcome of 1000 flaps. , 2012, International journal of oral and maxillofacial surgery.

[40]  T. Mücke,et al.  Autonomization of epigastric flaps in rats , 2011, Microsurgery.

[41]  T. Mücke,et al.  Reliability of Near-Infrared Angiography and Micro-Doppler Sonography for Evaluating Microvascular Anastomoses , 2010, Plastic and reconstructive surgery.

[42]  Aksone Nouvong,et al.  Hyperspectral Imaging in Diabetic Foot Wound Care , 2010, Journal of diabetes science and technology.

[43]  T. Mücke,et al.  Microsurgically Induced Aneurysm Models in Rats, Part II: Clipping, Shrinking and Micro-Doppler Sonography , 2008, Minimally invasive neurosurgery : MIN.

[44]  Rong A. Wang,et al.  The effect of gradual or acute arterial occlusion on skeletal muscle blood flow, arteriogenesis, and inflammation in rat hindlimb ischemia. , 2005, Journal of vascular surgery.

[45]  E. Wahlberg,et al.  A Rat Model for Severe Limb Ischemia at Rest , 2003, European Surgical Research.

[46]  T. Nakatsuka,et al.  Analytic review of 2372 free flap transfers for head and neck reconstruction following cancer resection. , 2003, Journal of reconstructive microsurgery.

[47]  J. Bailes,et al.  Intraoperative microvascular Doppler sonography in aneurysm surgery. , 1997, Neurosurgery.

[48]  T R Nelson,et al.  The Doppler signal: where does it come from and what does it mean? , 1988, AJR. American journal of roentgenology.

[49]  Neil F. Jones,et al.  Direct Monitoring of Microvascular Anastomoses with the 20‐MHz Ultrasonic Doppler Probe: An Experimental and Clinical Study , 1988, Plastic and reconstructive surgery.

[50]  P. Burns,et al.  The physical principles of Doppler and spectral analysis , 1987, Journal of clinical ultrasound : JCU.

[51]  D. H. King,et al.  Arterial assessment by Doppler-shift ultrasound. , 1974, Proceedings of the Royal Society of Medicine.

[52]  B. Strauch,et al.  Transfer of Composite Graft with Immediate Suture Anastomosis of Its Vascular Pedicle Measuring Less Than 1 mm. in External Diameter Using Microsurgical Techniques , 1967, Plastic and reconstructive surgery.

[53]  S. Delorme,et al.  [Principles of Doppler sonography]. , 2015, Der Radiologe.

[54]  Guolan Lu,et al.  Medical hyperspectral imaging: a review , 2014, Journal of biomedical optics.

[55]  M. Darmon,et al.  Doppler-Based Renal Resistive Index: A Comprehensive Review , 2010 .

[56]  T. Mücke,et al.  Intraoral coverage of defects with the superficial epigastric fat flap in rats , 2008, Microsurgery.

[57]  C. Oates The Doppler shift & speed of sound in blood , 1989 .

[58]  C. Oates The Doppler shift and speed of sound in blood. , 1989, Ultrasound in Medicine and Biology.

[59]  R. Greenhalgh,et al.  An implanted ultrasound Doppler probe for microvascular monitoring: an experimental study. , 1986, British journal of plastic surgery.

[60]  F. Segal,et al.  A CHARACTERIZATION OF FIBRANT SEGAL CATEGORIES , 2006, math/0603400.