A stationary probe directs a continuous 4MHz beam of ultrasound waves at blood f
A stationary probe directs a continuous 4MHz beam of ultrasound waves at blood flowing in the descending aorta. The shift in the frequency of the reflected ultrasound waves caused by the moving blood cells are translated by the CardioQ™ into a real time display of the velocity of the blood against time. Analysis of the waveform provides information on a range of cardiac parameters to be derived.
A stationary probe directs a continuous 4MHz beam of ultrasound waves at blood f
A stationary probe directs a continuous 4MHz beam of ultrasound waves at blood flowing in the descending aorta. The shift in the frequency of the reflected ultrasound waves caused by the moving blood cells are translated by the CardioQ™ into a real time display of the velocity of the blood against time. Analysis of the waveform provides information on a range of cardiac parameters to be derived.
A stationary probe directs a continuous 4MHz beam of ultrasound waves at blood f
A stationary probe directs a continuous 4MHz beam of ultrasound waves at blood flowing in the descending aorta. The shift in the frequency of the reflected ultrasound waves caused by the moving blood cells are translated by the CardioQ™ into a real time display of the velocity of the blood against time. Analysis of the waveform provides information on a range of cardiac parameters to be derived.
A stationary probe directs a continuous 4MHz beam of ultrasound waves at blood f
A stationary probe directs a continuous 4MHz beam of ultrasound waves at blood flowing in the descending aorta. The shift in the frequency of the reflected ultrasound waves caused by the moving blood cells are translated by the CardioQ™ into a real time display of the velocity of the blood against time. Analysis of the waveform provides information on a range of cardiac parameters to be derived.
A stationary probe directs a continuous 4MHz beam of ultrasound waves at blood f
A stationary probe directs a continuous 4MHz beam of ultrasound waves at blood flowing in the descending aorta. The shift in the frequency of the reflected ultrasound waves caused by the moving blood cells are translated by the CardioQ™ into a real time display of the velocity of the blood against time. Analysis of the waveform provides information on a range of cardiac parameters to be derived.
0.2 micron air eliminating filter with low protein binding Supor membrane for up
0.2 micron air eliminating filter with low protein binding Supor membrane for up to 24 hours use. Without attached extension tubing.
0.2 micron air eliminating filter with low protein binding Supor membrane for up
0.2 micron air eliminating filter with low protein binding Supor membrane for up to 24 hours use.
14" STANDARDBORE EXTENSION SET WITH 0.2 MICRON FILTER AND Y-SITE (APPROX. PRIMIN
14" STANDARDBORE EXTENSION SET WITH 0.2 MICRON FILTER AND Y-SITE (APPROX. PRIMING VOLUME 4.9 mL)
A plethysmograph sensor that attaches to a plethysmograph instrument, used to me
A plethysmograph sensor that attaches to a plethysmograph instrument, used to measure volume changes in a limb or digit. The sensor has a tube filled with electrically resistive fluid (indium-gallium), and is wrapped around the circumference of the limb or digit. The plethysmograph instrument measures the resistance changes of the sensor that occur when the resistive fluid column length changes according to circumference changes that occur with vascular flow changes.
A plethysmograph sensor that attaches to a plethysmograph instrument, used to me
A plethysmograph sensor that attaches to a plethysmograph instrument, used to measure volume changes in a limb or digit. The sensor has a tube filled with electrically resistive fluid (mercury), and is wrapped around the circumference of the limb or digit. The plethysmograph instrument measures the resistance changes of the sensor that occur when the resistive fluid column length changes according to circumference changes that occur with vascular flow changes.
The brand name for this component is IBC FloProbe and is part of the AcuFlo syst
The brand name for this component is IBC FloProbe and is part of the AcuFlo system of products. This component is used in conjunction with the Medtronic Biomedicus Flow Pump System during open heart procedures. The IBC FloProbe is a direct product substitution for the Medtronic/Biomedicus Bioprobe, DP38.
The brand name for this component is IBC FloProbe and is part of the AcuFlo syst
The brand name for this component is IBC FloProbe and is part of the AcuFlo system of products. This component is used in conjunction with the Medtronic Biomedicus Flow Pump System during open heart procedures. The IBC FloProbe is a direct product substitution for the Medtronic/Biomedicus Bioprobe, DP38P.