3D Ultrasound Yield Accurate Volumetric Blood Flow Measurements Non-Invasively

Now we just need followup for strokes and blood flow in the brain. Then we could get an objective 3d map of brain damage, the starting point of deciding exactly what hyperacute protocols need to be done in the first week and after that the therapy protocols to fix the documented damage.  This is incredibly important to be followed up, of course nothing will happen. WE HAVE NO STROKE STRATEGY AND NO STROKE LEADERSHIP.

Doing this on a daily basis could give us exact estimates of the neuronal cascade of death and how long it continues. Because right now our doctors are doing nothing in the first week because no one knows the death rate of neurons in that time frame. Hell I lost 5.4 billion neurons that first week, damned hard to recover from that. I think each lost neuron is worth $1,000. So my hospital should pay me 5.4 trillion dollars for incompetently doing nothing to save those neurons. Money is the only thing that might get your hospital off its' ass and actually try to solve stroke. 

Politeness will never solve anything in stroke. Yes, I'm a bomb thrower and proud of it. Someday a stroke 'leader' will ream me out for making them look bad by being truthful , I look forward to that day.

The latest here: 

3D Ultrasound Yield Accurate Volumetric Blood Flow Measurements Non-Invasively

Monitoring color flow gain in 3D quantitative blood flow measurements provides accurate and reliable information.

Estimating blood flow across a variety of systems and facilities with a 3D ultrasound approach is both effective and non-invasive, according to newly published research.
Being able to accurately and quickly assess blood flow measurements and blood flow to organs, such as the heart and brain, is critical in emergency situations. These measurements also play a role in chronic disease management, such as monitoring blood flow to the hands and feet in patients with diabetes. But, getting reliable measurements is difficult.
“Right now, we just don’t have anything better to quantify blood flow,” said Oliver D. Kripfgans, Ph.D., associate professor of radiology at Michigan Medicine and lead study author of the article published in Radiology.
Current tactics, including blood pressure measurements and 2D ultrasound, such as spectral Doppler, provide surrogate measures rather than actual volumetric flow. They are also error prone and can vary significantly between facilities and operators.

Volume flow as a function of color flow gain (at a single testing site). For each row the color flow c-plane and the computed volume flow are shown as a function of color flow gain. The c-plane is shown for four representative gain levels, whereas the computed volume flow is shown for 12–17 steps across the available gain settings. Flow was computed with (solid circles on the graphs) and without (hollow circles on the graphs) partial volume correction. Partial volume correction accounts for pixels that are only partially inside the lumen. Therefore, high gain (ie, blooming) does not result in overestimation of flow. Systems 1 and 2 converge to true flow after the lumen is filled with color pixel. System 3 is nearly constant regarding gain and underestimates the flow by approximately 17%. Shown are mean flow estimated from 20 volumes, and the error bars show standard deviation. Courtesy: Radiology

To fix this problem, Kripfgans’ team has spent several years developing a 3D approach that could yield quantitative measurements. For this study, the team partnered with volunteers from the Quantitative Imaging Biomarkers Alliance (QIBA), a healthcare research alliance launched by the Radiological Society of North America to improve current biomarkers and investigate new ones.
Together, the group tested their 3D strategy on three clinical scanners using a custom flow phantom, a device that mimics human blood flow. In seven different labs, they altered eight distinct testing conditions, including changing flow rate, imaging depth, and other parameters, to evaluate the approach’s efficacy and reliability. For each scanner, they monitored and recorded 3D quantitative blood flow measurement dependence on color gain. This tactic, the team said, decreased user and scanner measurement variability.
According to Kripfgans, their analysis revealed that blood flow volume that is estimated by 3D color-flow ultrasound is accurate. The findings, he said, were reproduced across all seven labs.
“We had less than 10-percent error or variation,” he explained. “For some of the systems, we were down to only 3-percent to 5-percent difference between labs. These are fantastic results that show that, from a technology point-of-view, some systems could be ready to go to the clinic.”
Because the system is easy to use, it reduces the variation between operators and facilities that routinely pop up with existing blood flow assessment tactics, he said. The range of tested flows means that the 3D approach could have a wide range of clinical applications, including peripheral vascular flow and cerebral blood flow estimation other than perfusion and cardiac output. And, blood flow estimation could allow for:

• More accurate measurements in hemodialysis arteriovenous fistulas and grafts
• Evaluating stenosis and function in transjugular intrahepatic portosystemic shunts
• Potential umbilical cord blood flow

Alongside these possible clinical applications, having QIBA involved, with its goal of accelerating the development and adoption of hardware and software standards to facilitate accurate and reproducible quantitative imaging method results, will make implementation of the 3D approach in patient care much easier, he said.
“Because of QIBA and this study, I’m confident that this 3D ultrasound technology is on a path to the clinic,” Kripfgans said