Portable isocapnia circuit and isocapnia method
First Claim
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1. A method of providing constant PCO2 to a patient wearing a breathing port having an inspiratory side and an expiratory side, the method comprising:
- aspirating atmospheric air from the inspiratory side to a patient when the patient inhales through the inspiratory side;
accumulating the gas exhaled by the patient in an expiratory gas reservoir connected to the expiratory side, through which the patient exhales; and
allowing the gas exhaled by the patient and stored in the expiratory gas reservoir to flow into the inspiratory side to mix with the aspirated atmospheric air when a minute ventilation of the patient exceeds the atmospheric air aspirated to the inspiratory side.
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Abstract
A portable isocapnia circuit and an isocapnia method. A breathing port of the circuit allows a subject to inhale and exhale. Connected to the breathing port, a bifurcate conduit has a first conduit branch and a second conduit branch. The first conduit branch has an atmospheric air inlet, from which the atmospheric air is provided for inhalation, an inspiratory check valve to allow a one-way flow of the atmospheric air, and an atmospheric air aspirator. The second conduit branch has a one-way expiratory check valve and a expiratory gas reservoir. A one-way check valve is used to interconnect the first and second conduit branch, from which the expiratory gas stored in the expiratory gas reservoir flows to the first conduit branch to mix with the atmospheric air when the minute ventilation exceeds the atmospheric air.
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Citations
10 Claims
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1. A method of providing constant PCO2 to a patient wearing a breathing port having an inspiratory side and an expiratory side, the method comprising:
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aspirating atmospheric air from the inspiratory side to a patient when the patient inhales through the inspiratory side;
accumulating the gas exhaled by the patient in an expiratory gas reservoir connected to the expiratory side, through which the patient exhales; and
allowing the gas exhaled by the patient and stored in the expiratory gas reservoir to flow into the inspiratory side to mix with the aspirated atmospheric air when a minute ventilation of the patient exceeds the atmospheric air aspirated to the inspiratory side.
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2. An isocapnia circuit, comprising:
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a breathing port, through which a subject inhales and exhales;
an inspiratory port, communicating to the breathing port with an inspiratory valve that allows air flowing to the breathing port and prevents air flowing from the breathing port to the inspiratory port, the inspiratory port having an atmospheric air aspirator to aspirate the atmospheric air therein;
an expiratory port, communicating to the breathing port with an expiratory valve that allows air flowing from the breathing port to the expiratory port and prevents air flowing to the breathing port, the expiratory port having an expiratory gas reservoir to store gas exhaled by the subject flowing across the expiratory valve; and
a bypass conduit, communicating the inspiratory and expiratory ports with a bypass valve, the bypass valve allows a one-way flow of air from the expiratory port to the inspiratory port with a pressure differential applied thereto. - View Dependent Claims (3, 4, 5, 6, 7)
alveolar gas reservoir, connecting the expiratory port and the expiratory gas reservoir, around one end of which the expiratory gas reservoir being sealed, the alveolar gas reservoir has the other end extending into the expiratory the gas reservoir; and
an exhaust tubing, from which the gas within the expiratory gas reservoir exhausts.
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4. The isocapnia circuit as claimed in claim 3, wherein the alveolar gas reservoir has a diameter larger than that of the exhaust tubing.
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5. The isocapnia circuit as claimed in claim 2, wherein the expiratory gas reservoir has a capacity in excess of a volume of a user'"'"'s breath.
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6. The isocapnia as claimed in claim 2, wherein the atmospheric air aspirator further comprises:
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a first end plate, where the inspiratory port opens to;
a collapsible plicate tube;
a second end rigid plate, with the collapsible tube accommodated between the first end plate and the second end rigid plate;
an inspiratory port nozzle located between the inspiratory valve and the first end plate, where the inspiratory port opens to the atmospheric air;
a first tube, attached to the inspiratory port nozzle;
an end plate nozzle, from which the collapsible tube opens to the atmospheric air;
a second tube, attached to the end plate nozzle; and
a protuberance, attached on the first end plate and pointing at the end plate nozzle to close an opening of the collapsible plicate tube while collapsed.
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7. The isocapnia circuit as claimed in claim 6, wherein the atmospheric air aspirator further comprises a spring to recoil the collapsible plicate tube.
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8. An isocapnia circuit, comprising:
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a breathing port, through which a subject exhales and inhales;
a bifurcated conduit adjacent and connected to the breathing port, including a first conduit branch and a second conduit branch, the first conduit branch further including;
an atmospheric air inlet; and
an inspiratory check valve located between the breathing port and the atmospheric air inlet and an expiratory check valve located in the second conduit branch, wherein the inspiratory and expiratory check valves are both one-way passage valves;
an atmospheric air aspirator connected to the first conduit branch, having a collapsible container formed to recoil to an open position;
a flexible expiratory gas reservoir, having an entrance tubing through which the flexible expiratory gas reservoir is connected to the second conduit, and an exit tubing open to the atmospheric air; and
a bypass conduit, communicating between the first and the second conduit branches, having a one-way check valve therein.
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9. An isocapnia circuit, comprising:
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a breathing port, through which a subject exhales and inhales;
a bifurcated conduit adjacent and connected to the breathing port, including a first conduit branch and a second conduit branch, the first conduit branch further including;
a fresh gas inlet; and
a one way inspiratory check valve, located between the breathing port and the fresh gas inlet, the second conduit branch further including a one way expiratory check valve located between the breathing port and an exhaust outlet;
an atmospheric air aspirator connected to the first conduit branch, having a collapsible container formed to recoil to an open position;
a flexible expiratory gas reservoir, having an entrance tubing through which the flexible expiratory gas reservoir is connected to the second conduit, and an exit tubing open to the atmospheric air; and
a bypass conduit communicating between the first and the second conduit branches, having a one-way check valve therein, and responding to a predetermined pressure, to draw expired gas into the first branch to maintain a substantially constant PCO2 level in the subject independent of minute ventilation. - View Dependent Claims (10)
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Specification
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Current AssigneeAlex Stenzler, Alex Vesely, Hiroshi Sasano, Joseph Fisher, Steve Iscoe
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Original AssigneeAlex Stenzler, Alex Vesely, Hiroshi Sasano, Joseph Fisher, Steve Iscoe
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InventorsStenzler, Alex, Sasano, Hiroshi, Iscoe, Steve, Vesely, Alex, Fisher, Joseph
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Primary Examiner(s)Lo, Weilun
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Assistant Examiner(s)MITCHELL, TEENA KAY
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Application NumberUS10/093,797Publication NumberTime in Patent Office543 DaysField of Search128/204.18, 128/204-1-2, 128/204.26, 128/204.28, 128/204.29, 128/205.11, 128/205-3-2, 128/205.24, 128/200.22, 128/200.24, 128/203.12, 128/203.13, 128/203.28, 128/205.18, 128/910US Class Current128/205.11CPC Class CodesA61M 16/0045 Means for re-breathing exha...A61M 16/08 Bellows; Connecting tubes h...A61M 16/12 by mixing different gases
