Body Weight-based Iodinated Contrast Immersion Timing for Human Fetal Postmortem Microfocus Computed Tomography

Overview

Journal BJR Open

Publisher Oxford University Press

Specialty Radiology

Date 2024 Feb 14

PMID 38352185

Authors

Ian C Simcock

Susan C Shelmerdine

John Ciaran Hutchinson

Neil J Sebire

Owen J Arthurs

Affiliations

Soon will be listed here.

Abstract

Objectives: The aim of this study was to evaluate the length of time required to achieve full iodination using potassium tri-iodide as a contrast agent, prior to human fetal postmortem microfocus computed tomography (micro-CT) imaging.

Methods: Prospective assessment of optimal contrast iodination was conducted across 157 human fetuses (postmortem weight range 2-298 g; gestational age range 12-37 weeks), following micro-CT imaging. Simple linear regression was conducted to analyse which fetal demographic factors could produce the most accurate estimate for optimal iodination time.

Results: Postmortem body weight ( = 0.6435) was better correlated with iodination time than gestational age ( = 0.1384), producing a line of best fit, = [0.0304 × body weight (g)] - 2.2103. This can be simplified for clinical use whereby immersion time (days) = [0.03 × body weight (g)] - 2.2. Using this formula, for example, a 100-g fetus would take 5.2 days to reach optimal contrast enhancement.

Conclusions: The simplified equation can now be used to provide estimation times for fetal contrast preparation time prior to micro-CT imaging and can be used to manage service throughput and parental expectation for return of their fetus.

Advances In Knowledge: A simple equation from empirical data can now be used to estimate preparation time for human fetal postmortem micro-CT imaging.

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