Medical

Whole-body imaging technology uses contactless tracking of blood flow

Whole-body imaging technology uses contactless tracking of blood flow
Readings are taken at different pulse points are passed back to a computer so the subject's blood circulation can be continuously monitored
Readings are taken at different pulse points are passed back to a computer so the subject's blood circulation can be continuously monitored
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Professor Alexander Wong and Robert Amelard analyze blood-flow data extracted with the new touchless device
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Professor Alexander Wong and Robert Amelard analyze blood-flow data extracted with the new touchless device
Readings are taken at different pulse points are passed back to a computer so the subject's blood circulation can be continuously monitored
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Readings are taken at different pulse points are passed back to a computer so the subject's blood circulation can be continuously monitored

Whether it's a stethoscope, blood pressure cuff or a carefully placed pair of fingers, current approaches to monitoring blood flow typically rely on readings from a single point of the body. Scientists have developed a new technology they say paints a more complete picture. The imaging technique tracks blood flow around the body and does so without needing to make contact with the skin, providing a tool that could prove useful in treating everybody from severe burn victims to the elderly.

Developed by researchers at the University of Waterloo, the device is claimed to be the first portable system capable of monitoring a patient's blood flow at various arterial points at the same time. The system makes use of a non-invasive light-based method for tracking cardiovascular activities called Photoplethysmography (PPG). This technique has been around since the 1930s and evaluates changes in light intensity resulting from changes in local blood volume. But as it requires close proximity to the skin, its use has been mostly limited to short-term at-rest monitoring.

The team sought to adapt PPG for longer distance monitoring, which involved designing an entirely new system aimed at pulling hemodynamic waveforms without making contact with the skin. It relies on a patent-pending technology called Coded Hemodynamic Imaging, which works essentially as an array of virtual sensors that measure blood flow through different parts of the body.

"By way of comparison, think of measuring the traffic flow across an entire city rather than through one intersection," explains Robert Amelard, PhD candidate in systems design engineering at Waterloo University.

Readings taken at different pulse points are passed back to a computer so the subject's blood circulation can be continuously monitored. By imaging entire bodies, and even of different patients at the same time, the researchers say the system can enable new advanced monitoring techniques that haven't been possible previously.

"Since the device can also scan multiple patients individually at once and from a distance, consider the potential in mass emergency scenarios or long-term care homes," says Professor Alexander Wong. "This technology provides for a more predictive approach to monitor vitals and the potential for its use is extensive, such as indicating arterial blockages that might otherwise go undetected, or warning older adults who risk falling as a result of getting dizzy when they stand."

The team says its testing shows for the first time that long distance, non-contact heart rate monitoring is feasible using PPG imaging.

The results of the study are published in the journal Scientific Reports.

The short video below shows the the Coded Hemodynamic Imaging system monitoring blood flow in a patient's upper body, slowed to one sixth of normal speed.

Source: University of Waterloo

Coded Hemodynamic Imaging System

1 comment
1 comment
Mr. Hensley Garlington
That is very awesome!