Pre- to postnatal reduction in ultrasound attenuation coefficient of the liver.

A recent study showed the ultrasound attenuation coefficient of fetal liver between 26 and 40 weeks of gestation to be 26% higher than after birth. To test the hypothesis that ultrasound attenuation is sensitive to fetal liver glycogen concentration, the livers of 24 fetuses were examined at 5 MHz just prior to and just after birth. The mean pre- to post-delivery reduction in attenuation coefficient was 0.08 dB cm-1 MHz-1 +/- 0.02 (SEM), or 17% of the post-delivery mean. This is consistent with the increase in attenuation measured by others in liver homogenate when glycogen was added. An increase in measurement accuracy, correlation with glycogen content, and, possibly, control for biological variability will be required to make predictions in individual cases, as opposed to these averages. A simple test of glycogen content would be of value scientifically and in prenatal and postnatal management.

Ultrasound attenuation coefficient in the fetal liver as a function of gestational age.

An apparent increase in the ultrasound attenuation coefficient per unit frequency, alpha f, of fetal liver as a function of gestational age has been observed. Measurements were made in utero with a 25 megasample/sec RF digitizer and a real time ultrasound system with a 5 MHz scan head. A precise measurement of alpha f was employed in which the intercept was tied to 0 at a frequency of 0. In 178 examinations of normal pregnancies, the linear regression of the alpha f increased 26% between 26 and 40 weeks gestation. This statistically significant increase (p less than 0.0001) is consistent with several observations, those of Parker et al. of increased attenuation in liver when glycogen is added, the increasing glycogen storage in the liver before birth, and our own pre- and postnatal measurements reported elsewhere. A noninvasive assay for glycogen content would have important applications in medicine and biomedical science. However, an increase in measurement accuracy and precise correlation with glycogen content will be required to make meaningful predictions in individual cases, as opposed to the present statistical trends.

Interobserver and intraobserver variations in sonographic renal length measurements in children.

Sonographic measurement of renal length is used commonly to evaluate growth of the kidneys in children. However, no previous studies have been performed to determine the degree of interobserver and intraobserver variability in such determinations. We measured the interobserver and intraobserver error in sonographic measurements of renal length obtained independently by three experienced imagers in 21 children (41 kidneys). The mean interobserver variation between any two imagers ranged from 3.87 to 5.49 mm. The mean intraobserver variation was 0.87 to 3.61 mm. The observed variability in sonographic measurement of renal length is comparable to the expected annual increase in length of the kidneys during childhood (2.2-5.7 mm per year). Therefore, caution is suggested when using sonography to evaluate renal growth in children during a year's time.