Literature DB >> 27545317

Autofluorescence hyperspectral imaging of radiofrequency ablation lesions in porcine cardiac tissue.

Daniel A Gil1,2, Luther M Swift1, Huda Asfour1, Narine Muselimyan1, Marco A Mercader3, Narine A Sarvazyan1.   

Abstract

Radiofrequency ablation (RFA) is a widely used treatment for atrial fibrillation, the most common cardiac arrhythmia. Here, we explore autofluorescence hyperspectral imaging (aHSI) as a method to visualize RFA lesions and interlesional gaps in the highly collagenous left atrium. RFA lesions made on the endocardial surface of freshly excised porcine left atrial tissue were illuminated by UV light (365 nm), and hyperspectral datacubes were acquired over the visible range (420-720 nm). Linear unmixing was used to delineate RFA lesions from surrounding tissue, and lesion diameters derived from unmixed component images were quantitatively compared to gross pathology. RFA caused two consistent changes in the autofluorescence emission profile: a decrease at wavelengths below 490 nm (ascribed to a loss of endogenous NADH) and an increase at wavelengths above 490 nm (ascribed to increased scattering). These spectral changes enabled high resolution, in situ delineation of RFA lesion boundaries without the need for additional staining or exogenous markers. Our results confirm the feasibility of using aHSI to visualize RFA lesions at clinically relevant locations. If integrated into a percutaneous visualization catheter, aHSI would enable widefield optical surgical guidance during RFA procedures and could improve patient outcome by reducing atrial fibrillation recurrence.
© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.

Entities:  

Keywords:  cardiac arrhythmia; hyperspectral imaging; radiofrequency ablation; surgical guidance

Mesh:

Year:  2016        PMID: 27545317      PMCID: PMC5511096          DOI: 10.1002/jbio.201600071

Source DB:  PubMed          Journal:  J Biophotonics        ISSN: 1864-063X            Impact factor:   3.207


  42 in total

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2.  Real-time monitoring of cardiac radio-frequency ablation lesion formation using an optical coherence tomography forward-imaging catheter.

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3.  Autofluorescence removal, multiplexing, and automated analysis methods for in-vivo fluorescence imaging.

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Journal:  J Biomed Opt       Date:  2005 Jul-Aug       Impact factor: 3.170

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5.  Visualization of epicardial cryoablation lesions using endogenous tissue fluorescence.

Authors:  Luther Swift; Daniel A B Gil; Rafael Jaimes; Matthew Kay; Marco Mercader; Narine Sarvazyan
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6.  Updated worldwide survey on the methods, efficacy, and safety of catheter ablation for human atrial fibrillation.

Authors:  Riccardo Cappato; Hugh Calkins; Shih-Ann Chen; Wyn Davies; Yoshito Iesaka; Jonathan Kalman; You-Ho Kim; George Klein; Andrea Natale; Douglas Packer; Allan Skanes; Federico Ambrogi; Elia Biganzoli
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7.  Microphotometric determination of hematocrit in small vessels.

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9.  Locations of ectopic beats coincide with spatial gradients of NADH in a regional model of low-flow reperfusion.

Authors:  Matthew Kay; Luther Swift; Brian Martell; Ara Arutunyan; Narine Sarvazyan
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Review 10.  Anatomical Basis for the Cardiac Interventional Electrophysiologist.

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  16 in total

Review 1.  A Percutaneous Catheter for In Vivo Hyperspectral Imaging of Cardiac Tissue: Challenges, Solutions and Future Directions.

Authors:  Kenneth Armstrong; Cinnamon Larson; Huda Asfour; Terry Ransbury; Narine Sarvazyan
Journal:  Cardiovasc Eng Technol       Date:  2020-07-14       Impact factor: 2.495

2.  Spectroscopic photoacoustic imaging of radiofrequency ablation in the left atrium.

Authors:  Sophinese Iskander-Rizk; Pieter Kruizinga; Antonius F W van der Steen; Gijs van Soest
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3.  Optimization of wavelength selection for multispectral image acquisition: a case study of atrial ablation lesions.

Authors:  Huda Asfour; Shuyue Guan; Narine Muselimyan; Luther Swift; Murray Loew; Narine Sarvazyan
Journal:  Biomed Opt Express       Date:  2018-04-16       Impact factor: 3.732

4.  Application of unsupervised learning to hyperspectral imaging of cardiac ablation lesions.

Authors:  Shuyue Guan; Huda Asfour; Narine Sarvazyan; Murray Loew
Journal:  J Med Imaging (Bellingham)       Date:  2018-12-15

5.  Real-time optical spectroscopic monitoring of nonirrigated lesion progression within atrial and ventricular tissues.

Authors:  Rajinder P Singh-Moon; Xinwen Yao; Vivek Iyer; Charles Marboe; William Whang; Christine P Hendon
Journal:  J Biophotonics       Date:  2018-12-26       Impact factor: 3.207

6.  Balloon catheter-based radiofrequency ablation monitoring in porcine esophagus using optical coherence tomography.

Authors:  William C Y Lo; Néstor Uribe-Patarroyo; Katharina Hoebel; Kathy Beaudette; Martin Villiger; Norman S Nishioka; Benjamin J Vakoc; Brett E Bouma
Journal:  Biomed Opt Express       Date:  2019-03-28       Impact factor: 3.732

7.  Monitoring of irrigated lesion formation with single fiber based multispectral system using machine learning.

Authors:  Soo Young Park; Rajinder P Singh-Moon; Haiqiu Yang; Christine P Hendon
Journal:  J Biophotonics       Date:  2022-06-15       Impact factor: 3.390

8.  Cardiac endocardial left atrial substrate and lesion depth mapping using near-infrared spectroscopy.

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9.  Anatomical and Optical Properties of Atrial Tissue: Search for a Suitable Animal Model.

Authors:  Narine Muselimyan; Mohammed Al Jishi; Huda Asfour; Luther Swift; Narine A Sarvazyan
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10.  Hyperspectral imaging for label-free in vivo identification of myocardial scars and sites of radiofrequency ablation lesions.

Authors:  Luther M Swift; Huda Asfour; Narine Muselimyan; Cinnamon Larson; Kenneth Armstrong; Narine A Sarvazyan
Journal:  Heart Rhythm       Date:  2017-12-12       Impact factor: 6.343
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