Non-invasive Assessment of Sublingual Microcirculation Using Flow Derived from Green Light PPG: Evaluation and Reference Values

Overview

Journal J Biomed Opt

Specialties Biomedical Engineering
Ophthalmology

Date 2024 Jan 8

PMID 38188965

Authors

Rafael Uribe Acevedo

Laura Osorio Sanchez

Sebastian Vergara Londono

Elisa Mejia-Mejia

Robinson Torres Villa

Yesid Montoya Goez

Affiliations

Soon will be listed here.

Abstract

Significance: The study of sublingual microcirculation offers valuable insights into vascular changes and overcomes some limitations of peripheral microcirculation assessment. Videomicroscopy and pulse oximetry have been used to assess microcirculation, providing insights into organ perfusion beyond macrohemodynamics parameters. However, both techniques have important limitations that preclude their use in clinical practice.

Aim: To address this, we propose a non-invasive approach using photoplethysmography (PPG) to assess microcirculation.

Approach: Two experiments were performed on different samples of 31 subjects. First, multi-wavelength, finger PPG signals were compared before and while applying pressure on the sensor to determine if PPG signals could detect changes in peripheral microcirculation. For the second experiment, PPG signals were acquired from the ventral region of the tongue, aiming to assess the microcirculation through features calculated from the PPG signal and its first derivative.

Results: In experiment 1, 13 out of 15 features extracted from green PPG signals showed significant differences () before and while pressure was applied to the sensor, suggesting that green light could detect flow distortion in superficial capillaries. In experiment 2, 15 features showed potential application of PPG signal for sublingual microcirculation assessment.

Conclusions: The PPG signal and its first derivative have the potential to effectively assess microcirculation when measured from the fingertip and the tongue. The assessment of sublingual microcirculation was done through the extraction of 15 features from the green PPG signal and its first derivative. Future studies are needed to standardize and gain a deeper understanding of the evaluated features.

Citing Articles

Arteriolar Elasticity Measurement in the Fingertip Based on Photoplethysmographic Volume-Oscillometry: A New Approach to the Assessment of Vasomotor Functions in the Microvasculature.

Yamakoshi K, Rolfe P, Yamakoshi T Cardiovasc Eng Technol. 2025; .

PMID: 39825176 DOI: 10.1007/s13239-025-00772-3.

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