29 January 2008

Non-invasive Brain Oximeter--Let There Be Light

Neurosurgical intensive care units and emergency rooms have long needed a quick, non-invasive way of measuring the state of the brain. CT scans and MRI's are expensive, time-consuming, and cannot be kept at the bedside. A new type of brain oximeter takes advantage an interesting pheonmenon--ultrasonic light tagging.
Information on oxygenation in specific regions of the brain would be valuable to neurologists monitoring a brain-injured patient, as it could be used to search for localized hematomas and give immediate notice of hemorrhagic strokes. When a stroke occurs, an area of the brain is deprived of blood and thus oxygen, but there is no immediate way to detect the attack's occurrence.

CT and MRI scans give a snapshot of tissue damage, but they can't be used for continuous monitoring. It can also be very difficult to conduct such scans on unconscious patients hooked up to life-support devices.

....OrNim's new device uses a technique called ultrasonic light tagging to isolate and monitor an area of tissue the size of a sugar cube located between 1 and 2.5 centimeters under the skin. The probe, which rests on the scalp, contains three laser light sources of different wavelengths, a light detector, and an ultrasonic emitter.

The laser light diffuses through the skull and illuminates the tissue underneath it. The ultrasonic emitter sends highly directional pulses into the tissue. The pulses change the optical properties of the tissue in such a way that they modulate the laser light traveling through the tissue. In effect, the ultrasonic pulses "tag" a specific portion of tissue to be observed by the detector. Since the speed of the ultrasonic pulses is known, a specific depth can be selected for monitoring.

The modulated laser light is picked up by the detector and used to calculate the tissue's color. Since color is directly related to blood oxygen saturation (for example, arterial blood is bright red, while venous blood is dark red), it can be used to deduce the tissue's oxygen saturation. The measurement is absolute rather than relative, because color is an indicator of the spectral absorption of hemoglobin and is unaffected by the scalp.

Deeper areas could be illuminated with stronger laser beams, but light intensity has to be kept at levels that will not injure the skin. Given the technology's current practical depth of 2.5 centimeters, it is best suited for monitoring the upper layers of the brain. Smith suggests that the technology could be used to monitor specific clusters of blood vessels.

While the technology is designed to monitor a specific area, it could also be used to monitor an entire hemisphere of the brain. Measuring any area within the brain could yield better information about whole-brain oxygen saturation than a pulse oximeter elsewhere on the body would. Hilton Kaplan, a researcher at the University of Southern California's Medical Device Development Facility, says, "If this technology allows us to actually measure deep inside, then that's a big improvement over the limitations of decades of cutaneous versions."

Michal Balberg, the CEO and cofounder of OrNim, thinks that it may ultimately be feasible to deploy arrays of probes on the head to get a topographic map of brain oxygenation. In time, brain oxygenation may be considered a critical parameter that should be monitored routinely.
Technology Review

One more step to Dr. McCoy's scanner wand.

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