MRI Shows Blood Flow Differs in Men and Women

Four-dimensional (4D) flow MRI was used to calculate, A, kinetic energy in the right ventricle (RV) and left ventricle (LV). Time-averaged 4D flow MRI magnitude data were used to segment the RV and LV and, B, flow through the main pulmonary artery and ascending aorta.

Healthy men and women have different blood flow characteristics in their hearts, according to a new study published in the journal Radiology: Cardiothoracic Imaging. Researchers said the results could be used to help create quantitative standards that adjust for gender to provide improved assessment of cardiac performance.

Differences in the hearts of men and women have long been known. For instance, women’s hearts are smaller in size and beat faster than men’s, on average. However, much less is known about the way that blood flows through the hearts of men and women and how that relates to cardiac performance.

For the new study, researchers used a sophisticated imaging technique called 4D flow MRI to study gender differences in the left ventricle, the heart’s main pumping chamber. They derived various blood flow parameters from MRI scans obtained from 20 men and 19 women and correlated them with cardiac function.

The data showed some significant differences between the genders. Kinetic energy, which is one indicator of energy expenditure during contraction and filling of the heart, was significantly higher in the left ventricles of men. Vorticity, a measure of regions of rotating flow that form during different points of the cardiac cycle, was higher in women, as was strain, a measure of left ventricular function.

“Using the MRI data, we found differences in how the heart contracts in men and woman,” said study lead author David R. Rutkowski, Ph.D., postdoctoral researcher at the University of Wisconsin in Madison. “There was greater strain in the left ventricle wall of women and a higher vorticity in the blood volume. We hypothesize that these two things are related.”

Four-dimensional flow MRI data were used to create velocity vector visualizations of left ventricle blood flow throughout the cardiac cycle in healthy volunteers. Through this visualization, areas of vortex formation were observed, as emphasized with arrows.

The study and the methods it employed have a number of potential applications, Dr. Rutkowski noted, including improved understanding of why the hearts of men and women respond differently to physiological stresses and disease. The results also add information that might one day improve clinical assessment of the heart.

“These blood flow metrics would be useful as reference standards because they are derived from healthy people, so we could use these to compare with someone who is unhealthy,” Dr. Rutkowski said.

Dr. Rutkowski emphasized that the ability of 4D flow MRI to provide numbers for various blood flow parameters is especially important.

“There’s been a push in the last couple of decades to make MRI more quantitative,” he said. “So instead of looking at something and saying it looks normal or different, we can get a number to go with that visual information.”

The researchers are currently using 4D flow MRI to look at patients with atrial fibrillation, an irregular heartbeat that can lead to serious complications. Their hope is that MRI will help detect patterns and relationships in the atria, the upper chambers of the heart, similar to those found in the ventricles.

“The goal of our work in general is to move from qualitative MRI to more quantitative MRI,” Dr. Rutkowski said. “Getting blood flow and velocity information is just one more metric that is being developed to make MRI more quantitative.”

No Comments Yet

Leave a Reply

Your email address will not be published.

©2020. Global Health News Wire. Use Our Intel. All Rights Reserved. Washington, D.C.