Intra-instrument Channel Workable, Optical-resolution Photoacoustic and Ultrasonic Mini-probe System for Gastrointestinal Endoscopy

Overview

Journal Photoacoustics

Date 2022 Mar 22

PMID 35313458

Authors

Minjae Kim

Kang Won Lee

KiSik Kim

Oleksandra Gulenko

Cheol Lee

Bora Keum

Hoon Jai Chun

Hyuk Soon Choi

Chae Un Kim

Joon-Mo Yang

Affiliations

Soon will be listed here.

Abstract

There has been a long-standing expectation that the optical-resolution embodiment of photoacoustic tomography could have a substantial impact on gastrointestinal endoscopy by enabling microscopic visualization of the vasculature based on the endogenous contrast mechanism. Although multiple studies have demonstrated the in vivo imaging capability of a developed imaging device over the last decade, the implementation of such an endoscopic system that can be applied immediately when necessary via the instrument channel of a video endoscope has been a challenge. In this study, we developed a 3.38-mm diameter catheter-based, integrated optical-resolution photoacoustic and ultrasonic mini-probe system and successfully demonstrated its intra-instrument channel workability for the standard 3.7-mm diameter instrument channel of a clinical video endoscope based on a swine model. Through the instrument channel, we acquired the first in vivo dual-mode photoacoustic and ultrasonic endoscopic images from the esophagogastric junction of a swine. Further, in a rat colorectum in vivo imaging experiment, we visualized hierarchically developed mesh-like capillary networks with a hole size as small as ~50 µm, which suggests the potential level of image details that could be photoacoustically provided in clinical settings in the future.

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