Non-invasive Monitoring of Blood Oxygenation in Human Placentas Via Concurrent Diffuse Optical Spectroscopy and Ultrasound Imaging

Overview

Journal Nat Biomed Eng

Publisher Springer Nature

Specialty Biomedical Engineering

Date 2022 Aug 15

PMID 35970929

Authors

Lin Wang

Jeffrey M Cochran

Tiffany Ko

Wesley B Baker

Kenneth Abramson

Lian He

David R Busch

Venki Kavuri

Rebecca L Linn

Samuel Parry

Arjun G Yodh

Nadav Schwartz

Affiliations

Soon will be listed here.

Abstract

Direct assessment of blood oxygenation in the human placenta can provide information about placental function. However, the monitoring of placental oxygenation involves invasive sampling or imaging techniques that are poorly suited for bedside use. Here we show that placental oxygen haemodynamics can be non-invasively probed in real time and up to 4.2 cm below the body surface via concurrent frequency-domain diffuse optical spectroscopy and ultrasound imaging. We developed a multimodal instrument to facilitate the assessment of the properties of the anterior placenta by leveraging image-reconstruction algorithms that integrate ultrasound information about the morphology of tissue layers with optical information on haemodynamics. In a pilot investigation involving placentas with normal function (15 women) or abnormal function (9 women) from pregnancies in the third trimester, we found no significant differences in baseline haemoglobin properties, but statistically significant differences in the haemodynamic responses to maternal hyperoxia. Our findings suggest that the non-invasive monitoring of placental oxygenation may aid the early detection of placenta-related adverse pregnancy outcomes and maternal vascular malperfusion.

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