Respiratory calorimeter
First Claim
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1. An indirect calorimeter operative to measure the respiratory oxygen consumption per unit time of a subject, comprising:
- a respiratory connector operative to be supported in contact with a subject so as to pass respiratory gases as the subject breathes into said respiratory connector;
a flow meter operative to generate signals as a function of the volume of gases passed through the flow meter;
a capnometer operative to generate signals as a function of the instantaneous carbon dioxide content of gases passed through the capnometer;
an electronic computer operative to receive signals from the flow meter and the capnometer; and
conduits interconnecting the respiratory connector, the flow meter and the capnometer so that the subject'"'"'s inhalations and exhalations pass through the flow meter and the subject'"'"'s exhalations pass through the capnometer;
the computer being operative to receive the signals from the capnometer and the flow meter to calculate the subject'"'"'s oxygen consumption over the period of the test.
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Abstract
An indirect calorimeter for measuring the subject'"'"'s oxygen consumption per unit time employs a mouthpiece through which the subject breathes for a period of time. Conduits connect the mouthpiece to a flow meter and a capnometer so that the subject'"'"'s inhalations and exhalations pass through the flow meter and the exhalations also pass through the capnometer. Electrical signals from the flow meter and capnometer are provided to a computer which calculates the CO2 exhaled by the subject during the test by integrating the instantaneous CO2 content of an exhalation as measured by the capnometer over the volume as measured by the flow meter and subtracts that quantity from the exhaled volume and subtracts their difference from the inhaled volume.
In alternative embodiments the system can also measure the subject'"'"'s Cardiac Output and Delivered Oxygen.
323 Citations
18 Claims
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1. An indirect calorimeter operative to measure the respiratory oxygen consumption per unit time of a subject, comprising:
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a respiratory connector operative to be supported in contact with a subject so as to pass respiratory gases as the subject breathes into said respiratory connector;
a flow meter operative to generate signals as a function of the volume of gases passed through the flow meter;
a capnometer operative to generate signals as a function of the instantaneous carbon dioxide content of gases passed through the capnometer;
an electronic computer operative to receive signals from the flow meter and the capnometer; and
conduits interconnecting the respiratory connector, the flow meter and the capnometer so that the subject'"'"'s inhalations and exhalations pass through the flow meter and the subject'"'"'s exhalations pass through the capnometer;
the computer being operative to receive the signals from the capnometer and the flow meter to calculate the subject'"'"'s oxygen consumption over the period of the test.- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
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3. The indirect calorimeter of claim 1 wherein the flow meter is the unidirectional type and the calorimeter includes directional valves interconnected with the conduits to cause both the inhalations and the exhalations to pass through the flow meter in the same direction.
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4. The indirect calorimeter of claim 1 wherein the flow meter is bidirectional.
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5. The indirect calorimeter of claim 1 wherein the flow meter comprises two unidirectional flow meters interconnected so that the subject'"'"'s inhalations pass through one flow meter and the subject'"'"'s exhalations pass through the other flow meter.
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6. The indirect calorimeter of claim 1 further including temperature conditioning means connected in said conduits so as to alter the temperature of respiratory gases flowing through it to generally equalize the temperature of the inhalations and exhalations passing through the flow meter.
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7. The indirect calorimeter of claim 1 further including humidity conditioning means connected in said conduits so as to pass respiratory gases to generally equalize the humidity of the inhalations and exhalations passed through the flow meter.
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8. The indirect calorimeter of claim 1 further including a source of respiratory gases and switch means moveable between a first position wherein an inhalation draws through the respiratory connector gases which are substantially from said source of respiratory gases, and a second position wherein an inhalation provides to the respiratory connector an initial quantity of gases representing the gases expired during the previous exhalation and the balance of the gases during said inhalation constitute gases from said respiratory connector, and wherein said means for receiving the signals from the flow meter and the capnometer operate to compute the subject'"'"'s Cardiac Output based upon signals generated while said switch means was initially in said first position and then subsequently in said second position.
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9. The indirect calorimeter of claim 8 wherein said means for receiving signals from the flow sensor and the capnometer calculates and stores, while said switch means is in the first position, the subject'"'"'s oxygen consumption, CO2 expiration and the end-tidal CO2 and while the switch is in the second position calculates the end-tidal CO2 and total expired CO2 and calculates Cardiac Output by the equation:
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where Δ
VCO2 equals the difference in the total volume of exhaled CO2, per breath, during the two periods and Δ
etCO2 constitutes the difference in the end-tidal CO2, per breath, during the two periods.
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10. The indirect calorimeter of claim 9 wherein the end-tidal CO2 content of an exhalation is detected using a zero crossing algorithm.
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11. An indirect calorimeter operative to measure the respiratory oxygen consumption per unit time of a subject, comprising:
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a source of respiratory gases;
a respiratory connector operative to be supported in contact with the subject so as to pass respiratory gases as the subject breathes into said respiratory connector;
a flow meter operative to generate signals as a function of the volume of the gases passed through the flow meter;
a capnometer operative to generate a signal as a function of the instantaneous CO2 content of the gases passed through the capnometer;
conduits interconnecting said source of respiratory gases, said respiratory connector, flow meter and capnometer operative, upon the subject inhaling, to cause respiratory gas from said source to pass through said flow meter to the respiratory connection, and upon the subject exhaling to pass the exhaled gas through the capnometer and the flow meter, and means for receiving the resultant signals from the flow meter and the capnometer and for calculating the volume of CO2 exhaled by the subject over a period of time as the integral of the instantaneous flow meter signals multiplied by the capnometer signals over that period and for calculating the oxygen consumption over the period by subtracting the volume of exhaled respiratory gases over the period less the calculated volume of CO2 expired over the period from the volume of gases inhaled during the period. - View Dependent Claims (12, 13)
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14. The indirect calorimeter of clam 12 where the valve means comprises four one-way valves, a first connected between the source of respiratory gases and inlet to the flow meter to allow gases from the respiratory source to pass through the flow meter from the respiratory source, a second connected in conduits extending from the output of the respiratory source to the respiratory connector to allow inhaled gases from the respiratory source to pass to the respiratory connector after passing through the flow meter, a third in a conduit extending from said respiratory connector to the inlet of the flow meter operative to allow gases exhaled through the respiratory connector to pass through the flow meter, and a fourth disposed in a conduit extending from the output of said flow meter to said source of respiratory gases to allow exhaled gases from the flow meter to return to the source of respiratory gases.
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15. The method of measuring the respiratory oxygen consumption of a subject per unit time, comprising measuring the volume of respiratory gases inhaled and exhaled by the subject over a period of time using a flow meter and the volume of carbon dioxide in the exhaled gas as computed by integrating over the measurement period the instantaneous carbon dioxide percentage of the exhaled gas as measured by a capnometer, multiplied by the volume of exhaled gases passing through the flow meter at the same time, and implementing the calculation VO2=Vi−
- (Ve−
VCO2) where VO2 equals the oxygen consumption;
Vi equals the inhaled volume;
Ve equals the exhaled volume and VCO2 equals the exhaled CO2. - View Dependent Claims (16, 17, 18)
- (Ve−
Specification
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Current AssigneeMicrolife Medical Home Solutions Inc.
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Original AssigneeJames R. Mault
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InventorsMault, James R.
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Primary Examiner(s)Hindenburg, Max
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Assistant Examiner(s)ASTORINO, MICHAEL C
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Application NumberUS09/008,435Time in Patent Office1,383 DaysField of Search600/529-538, 128/200.24US Class Current600/531CPC Class CodesA61B 5/029 Measuring or recording bloo...A61B 5/083 Measuring rate of metabolis...
