Transcutaneous oxygen and local perfusion measurement
First Claim
1. In a transcutaneous gas measurement probe including first and second electrodes, means for maintaining an electrolytic solution in contact with said first and second electrodes, means permeable to the gas to be measured in contact with said electrolytic solution and adapted to contact the surface at which said gas is transcutaneous, and means for maintaining said probe at substantially constant temperature, the improvement wherein said temperature maintaining means comprisesa semi-conductor device mounted in thermal transmitting relationship to said probe,heater circuit means connected to said semi-conductor device for applying a controlled amount of current thereto for maintaining the temperature of said probe at a substantially constant predetermined temperature,a first voltage producing means connected in parallel with said semi-conductor device for producing a first voltage having a magnitude proportional to the voltage across said semi-conductor device,a second voltage producing means operatively connected to said semi-conductor device so as to conduct a current passing through said semi-conductor device for producing a second voltage having a magnitude proportional to said current,a multiplier circuit having a first input operatively connected to said first voltage producing means and a second input operatively connected to said second voltage producing means and an output at which there is produced a product voltage having a magnitude proportional to the product of the magnitudes of the first and second voltages.
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Accused Products
Abstract
An apparatus and method for measuring and monitoring blood oxygen content and local perfusion factor. A transcutaneous gas measurement probe is heated by application of an electric current to a semi-conductor device housed therein. The heat developed in a semi-conductor device heats the probe to a constant temperature under the control of a temperature monitoring and regulating circuit and the amount of power applied to the semi-conductor device is measured by multiplying the current conducted through the semiconductor device by the voltage across it to provide a measurement of local perfusion factor. An alerting device is provided to signal when blood oxygen content and local perfusion factor are outside a predetermined acceptable range.
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Citations
8 Claims
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1. In a transcutaneous gas measurement probe including first and second electrodes, means for maintaining an electrolytic solution in contact with said first and second electrodes, means permeable to the gas to be measured in contact with said electrolytic solution and adapted to contact the surface at which said gas is transcutaneous, and means for maintaining said probe at substantially constant temperature, the improvement wherein said temperature maintaining means comprises
a semi-conductor device mounted in thermal transmitting relationship to said probe, heater circuit means connected to said semi-conductor device for applying a controlled amount of current thereto for maintaining the temperature of said probe at a substantially constant predetermined temperature, a first voltage producing means connected in parallel with said semi-conductor device for producing a first voltage having a magnitude proportional to the voltage across said semi-conductor device, a second voltage producing means operatively connected to said semi-conductor device so as to conduct a current passing through said semi-conductor device for producing a second voltage having a magnitude proportional to said current, a multiplier circuit having a first input operatively connected to said first voltage producing means and a second input operatively connected to said second voltage producing means and an output at which there is produced a product voltage having a magnitude proportional to the product of the magnitudes of the first and second voltages.
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5. Apparatus for measuring and monitoring blood gas content comprising
a transcutaneous gas measurement probe including first and second electrodes, said first electrode being formed of a thermally conductive material and having a mass substantially greater than the mass of said second electrode, a diaphragm permeable to the gas to be measured and enclosing a region between said first and second electrodes and adapted to confine an electrolytic solution therein, means for applying a voltage across said first and second electrodes, a semi-conductor device thermally conductively coupled to said first electrode, a temperature sensor element thermally conductively coupled to said first electrode, said temperature sensor element having an output voltage with a magnitude proportional to the temperature of said first electrode, means for selectively applying an electric current to said semi-conductor device, said selective applying means being responsive to said temperature sensor output voltage for applying said current only when said temperature sensor output voltage is below a predetermined level, means for providing a first voltage proportional to the voltage across said semi-conductor device, means for producing a second voltage having a magnitude proportional to the current flowing through said semi-conductor device, means for producing a product voltage having a magnitude equal to the product of said first and second voltage magnitudes, and means for displaying a magnitude dependent on said poduct voltage magnitude.
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8. A method for measuring local perfusion factor in a living body comprising
applying a probe heated by an electrically energized semi-conductor device to the skin surface of the body, obtaining an electrical signal having a magnitude indicative of the temperature of said probe, applying an electric current to the semi-conductor device in response to said temperature indicative signal for maintaining the probe at a predetermined constant temperature, measuring the power applied to said probe for maintaining said constant temperature by multiplying the magnitude of the current applied to heat said semi-conductor device by the magnitude of the voltage developed across said semi-conductor device.
Specification