CA2649691A1 - Method and system for controlling breathing - Google Patents

Method and system for controlling breathing Download PDF

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Publication number
CA2649691A1
CA2649691A1 CA002649691A CA2649691A CA2649691A1 CA 2649691 A1 CA2649691 A1 CA 2649691A1 CA 002649691 A CA002649691 A CA 002649691A CA 2649691 A CA2649691 A CA 2649691A CA 2649691 A1 CA2649691 A1 CA 2649691A1
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Prior art keywords
patient
gas
air
volume
carbon dioxide
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CA002649691A
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French (fr)
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CA2649691C (en
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Robert W. Daly
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PERIODIC BREATHING FOUNDATION LLC
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Individual
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    • A61M16/0057Pumps therefor
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    • A61M16/0069Blowers or centrifugal pumps the speed thereof being controlled by respiratory parameters, e.g. by inhalation
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    • A61B5/08Detecting, measuring or recording devices for evaluating the respiratory organs
    • A61B5/083Measuring rate of metabolism by using breath test, e.g. measuring rate of oxygen consumption
    • A61B5/0836Measuring rate of CO2 production
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    • A61M16/021Devices for influencing the respiratory system of patients by gas treatment, e.g. mouth-to-mouth respiration; Tracheal tubes operated by electrical means
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    • A61M16/0875Connecting tubes
    • AHUMAN NECESSITIES
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    • AHUMAN NECESSITIES
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    • A61M16/00Devices for influencing the respiratory system of patients by gas treatment, e.g. mouth-to-mouth respiration; Tracheal tubes
    • A61M16/20Valves specially adapted to medical respiratory devices
    • AHUMAN NECESSITIES
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    • A61M16/20Valves specially adapted to medical respiratory devices
    • A61M16/201Controlled valves
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    • AHUMAN NECESSITIES
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    • A61M16/208Non-controlled one-way valves, e.g. exhalation, check, pop-off non-rebreathing valves
    • A61M16/209Relief valves
    • AHUMAN NECESSITIES
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    • AHUMAN NECESSITIES
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    • AHUMAN NECESSITIES
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    • A61M2016/0027Accessories therefor, e.g. sensors, vibrators, negative pressure pressure meter
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    • A61M2016/0036Accessories therefor, e.g. sensors, vibrators, negative pressure with a flowmeter electrical in the breathing tube and used in both inspiratory and expiratory phase
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
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    • Y10S128/00Surgery
    • Y10S128/911Unilimb inhalation-exhalation breathing tubes
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S128/00Surgery
    • Y10S128/914Rebreathing apparatus for increasing carbon dioxide content in inhaled gas

Abstract

The present invention relates to a method and a system (100) for controlling breathing of a patient (101). A system for controlling breathing of a patient includes a respiratory conduit (120). The respiratory conduit is configured to be coupled to a patient interface device (102) and is further configured to be coupled to a pressurized air generating device (130). The respiratory conduit includes at least two air flow control devices, positioned between the patient interface device and the pressurized air generating device. The respiratory conduit includes at least two volumes, wherein one volume (111) is positioned between a first air flow control device (108, 131) and a second air flow control device (112, 133) and another volume (113) is positioned between a second air flow control device and a third air flow control device (114, 135).

Claims (109)

1. A method of controlling breathing of a patient, wherein air is supplied to the patient using a patient interface device coupled to an air supply device using a respiratory conduit that includes multiple controllable openings and volume connectors positioned along the length of the respiratory conduit, comprising:

determining a rate of production of gas generated by the patient;
measuring a rate of flow and a concentration of gas at each of the multiple controllable openings;

adjusting sizes of the multiple controllable openings based on said measuring;
and adjusting sizes of said multiple volume connectors based on at least one of said determining and said measuring;

wherein air supplied to the patient includes a mixture of air supplied by the air supply device and a gas generated by the patient.
2. The method according to claim 1, further comprising:

determining an increase in a pressure of gas in the arterial blood of the patient, wherein said determining includes measuring said pressure of gas contained in the arterial blood of the patient using time-based monitoring selected from the group consisting of end-tidal gas monitoring, transcutaneous gas monitoring, and arterial blood gas analysis; and calculating a desired changes in pressure of said gas in the arterial blood of the patient based on said measuring.
3. The method according to claim 1, wherein said gas is carbon dioxide.
4. The method according to claim 1, further comprising modifying sizes of the multiple controllable openings and the multiple volume connectors, wherein said modifying includes monitoring an amount of said gas escaping from each of the multiple controllable openings and the multiple volume connectors; and measuring a rate of flow and a concentration of gas at each of the multiple controllable openings;

adjusting sizes of said multiple volume connectors based on at least one of said determining and said measuring;

wherein gas supplied to the patient is a mixture of gas supplied by the gas supply device and gas produced by the patient during breathing.
5. The method according to claim 4, wherein said modifying is performed as a result of a collapse of the patient breathing airway.
6. The method according to claim 5, further comprising adjusting pressure of air supplied to the patient during breathing until the patient breathing airway is no longer collapsed.
7. The method according to claim 1, wherein said calculating further comprises estimating the amount of said gas produced by the patient using at least one characteristic selected from a group consisting of: age, gender, body mass, percent lean body mass and the partial pressure of said gas in the arterial blood of the patient.
8. The method according to claim 1, wherein said calculating further comprises determining the sizes of the multiple controllable openings and multiple volume connectors using a predetermined simulation of normal breathing of the patient.
9. The method according to claim 1, wherein a rate of air flow through one of the multiple controllable openings is based on a rate of flow through at least one other one of the multiple controllable openings.
10. The method according claim 9, wherein said determining further comprises calculating a minimum, a maximum, and a mean amount of gas escaping from each of the multiple controllable openings during breathing; and based on said calculating, adjusting a size of at least one of the multiple controllable openings and at least one size of each of the volume connectors.
11. The method according to claim 1, wherein a rate of flow of a gas through at least a first air controllable opening and at least a second controllable opening is calculated based on an expected rate of production of said gas by the patient, expected respiration rate of the patient, expected depth of respiration by the patient, and an expected concentration of said gas in the air expired by the patient.
12. The method according to claim 1, wherein a volume of expired gas by the patient that is re-breathed by the patient is continuously adjusted based on a volume of gas allowed to escape from said multiple controllable openings and a volume of gas contained in said multiple volume connectors.
13. An apparatus for controlling flow of carbon dioxide to a patient during breathing, comprising a carbon dioxide mixing device coupled to the patient interface device;

the carbon dioxide mixing device is configured to be coupled to a pressurized air supply device;

the carbon dioxide mixing device includes multiple ventilation orifices interchangeably connected with multiple dead spaces, wherein said multiple ventilation orifices control supply of carbon dioxide to the patient and volume of carbon dioxide in said multiple dead spaces;

a means for measuring airflow through each of said multiple ventilation orifices;
a means of detecting a concentration of carbon dioxide in the measured airflow;

a means of adjusting airflow through each of said multiple ventilation orifices based on said detection of said content of carbon dioxide; and a means of adjusting sizes of said multiple dead spaces based on said detection of said concentration of carbon dioxide and said adjusting of said airflow through each of said multiple ventilation orifices.
14. A method for controlling flow of carbon dioxide to a patient during breathing, using an air supply device coupled to a patient interface device placed on the patient, the patient interface device is coupled to a carbon dioxide mixing device, which is coupled to the air supply device, the carbon dioxide mixing device includes multiple ventilation orifices interchangeably connected with multiple dead spaces, wherein said multiple ventilation orifices control supply of carbon dioxide to the patient and volume of carbon dioxide in said multiple dead spaces, comprising measuring airflow through each of said multiple ventilation orifices;
detecting a content of carbon dioxide in the measured airflow;

adjusting airflow through each of said multiple ventilation orifices based on said detecting of said concentration of carbon dioxide; and adjusting sizes of said multiple dead spaces based on said detection of said concentration of carbon dioxide and said adjusting of said airflow through each of said multiple ventilation orifices.
15. The method according to claim 14, wherein said adjusting sizes step further comprises adjusting sizes of said multiple dead spaces and said multiple ventilation orifices based on a relationship between ~ co2 and ~ E, wherein ~ CO2Z is a rate of excretion of carbon dioxide by the patient per minute; ~ E is a total rate of ventilation per minute by the patient;
wherein a curve representing said relationship between ~ CO, and ~ E contains at least two discontinuities;

said discontinuities are determined using the lengths of a hypoventilatory traverse segment caused by a placement of at least a first ventilation orifice in said carbon dioxide mixing device;

a first respiratory plateau segment caused by a placement of at least a first dead space in said carbon dioxide mixing device;

a eucapnic traverse segment caused by a placement of at least a second ventilation orifice in said carbon dioxide mixing device;

a second respiratory plateau segment caused by a placement of at least a second dead space in said carbon dioxide mixing device; and a hyperventilatory traverse segment caused by a placement of at least a third ventilation orifice in said carbon dioxide mixing device.
16. The method according to claim 15, wherein said hypoventilatory traverse segment has a slope defined by a relationship between volume of air breathed by the patient during a breathing interval and an amount of carbon dioxide exhaled by the patient in said breathing interval.
17. The method according to claim 15, wherein during said eucapnic traverse segment, an additional volume of carbon dioxide escapes from at least a second ventilation orifice of said carbon dioxide mixing device, wherein said additional volume is determined based on the volume of carbon dioxide that escaped from at least a first ventilation orifice.
18. The method according to claim 15, wherein during said hyperventilatory traverse segment, an additional volume of carbon dioxide escapes from at least a third ventilation orifices of said carbon dioxide mixing device, wherein said additional volume is determined based on a volume of carbon dioxide that escaped from at least first and second ventilation orifices.
19. The method according to claim 14, further comprising determining a target mean arterial concentration of carbon dioxide based on said adjusting sizes step.
20. The method according to claim 14, wherein said adjusting sizes step is automatic.
21. The method according to claim 14, wherein said adjusting sizes step is manual.
22. A method for controlling breathing of a patient using a respiratory conduit configured to be coupled to a patient interface device and a pressurized air generating device, wherein the conduit includes at least two air flow control devices positioned between the patient interface device and the pressurized air generating device and at least two volumes, wherein a first volume is positioned between a first air flow device and a second air flow device, and a second volume is positioned between the second air flow device and a third air flow device, the method comprising receiving gas in the conduit, wherein the gas originates from an expiratory breath of the patient; and allowing escape of gas from the at least two air flow control devices;

wherein a portion of the received gas escapes from the first air flow control device and another portion of the received gas travels through the first volume to the second air flow control device;

wherein a part of the another portion of the received gas escapes from the second air low control device and another part of the another portion of the received gas travels through the second volume to the third air flow control device; and wherein the another part of the another portion of the received gas escapes from the third air flow control device.
23. A method for controlling breathing of a patient, comprising determining a rate of excretion of gas by the patient as a function of a rate of ventilation of a patient during hypoventilation by the patient, wherein the determining is made until a maximum concentration of the excreted gas is reached;

based on the determining, maintaining the rate of excretion of the gas by the patient at a predetermined level;

stabilizing the rate of excretion of the gas by the patient as a function of the rate of ventilation of the patient based on an expected rate of excretion of the gas by the patient, wherein the stabilizing is performed until a maximum concentration of the gas is reached;

inhibiting an excretion of the gas by the patient during hyperventilation of the patient;
and increasing the excretion of the gas by the patient to control breathing of the patient during the hyperventilation of the patient.
24. A method of controlling breathing of a patient, wherein air is supplied to the patient using a patient interface device coupled to an air supply device using a respiratory conduit that includes at least one valve configured to withdraw air from at least one openings disposed within at least one volume connector, wherein said valves and said volume connectors are positioned along the length of the respiratory conduit, comprising:

determining a rate of production of gas generated by the patient;

measuring a rate of flow and a concentration of gas at each of the controllable openings;

adjusting the flow rate through the multiple openings based on said measuring;
and adjusting sizes of said multiple volume connectors based on at least one of said determining and said measuring;

wherein air supplied to the patient includes a mixture of air supplied by the air supply device and a gas generated by the patient.
25. The method according to claim 24, further comprising:

determining an increase in a pressure of gas in the arterial blood of the patient, wherein said determining includes measuring said pressure of gas contained in the arterial blood of the patient using time-based monitoring selected from the group consisting of: end-tidal gas monitoring, transcutaneous gas monitoring, and arterial blood gas analysis; and calculating a desired changes in pressure of said gas in the arterial blood of the patient based on said measuring.
26. The method according to claim 24, further comprising adjusting the flow of air through the multiple openings and the multiple volume connectors, wherein said adjusting includes monitoring an amount of said gas escaping from each of the multiple openings and the multiple volume connectors; and measuring a rate of flow and a concentration of gas at each of the multiple openings;

adjusting sizes of said multiple volume connectors based on at least one of said determining and said measuring;

wherein gas supplied to the patient is a mixture of gas supplied by the gas supply device and gas produced by the patient during breathing.
27. The method according to claim 26, wherein said calculating further comprises estimating the amount of said gas produced by the patient using at least one characteristic selected from a group consisting of: age, gender, body mass, percent lean body mass and the partial pressure of said gas in the arterial blood of the patient.
28. The method according to claim 27, wherein said calculating further comprises determining the sizes of the multiple openings and multiple volume connectors using a predetermined simulation of normal breathing of the patient.
29. The method according to claim 24, wherein a rate of air flow through one of the multiple openings is based on a rate of flow through at least one other one of the multiple openings.
30. The method according claim 29, wherein said determining further comprises calculating an amount of gas escaping from each of the multiple openings during some period of time; and based on said calculating, adjusting a size of at least one of the multiple openings and at least one size of each of the volume connectors.
31. The method according to claim 24, wherein a rate of flow of a gas through at least a first air opening and at least a second opening is calculated based on an expected rate of production of said gas by the patient, expected respiration rate of the patient, expected depth of respiration by the patient, and an expected concentration of said gas in the air expired by the patient.
32. The method according to claim 31, wherein a volume of expired gas by the patient that is re-breathed by the patient is continuously adjusted based on a volume of gas allowed to escape from said multiple openings and a volume of gas contained in said multiple volume connectors.
33. A method of controlling breathing of a patient, wherein air is supplied to the patient using a patient interface device coupled to an air supply device using a respiratory conduit that includes at least two air flow control devices, positioned between the patient interface device and a pressurized air generating device, and at least two volumes, wherein at least one volume is configured to allow withdrawal of air from at least one location within the volume using at least one of the air flow control devices, comprising:

determining an average concentration of gas in the air flowing out of the second air flow control device;

comparing the average concentration of gas to a predetermined setpoint value of concentration of gas;

computing the difference between the average concentration and the predetermined setpoint value of concentration;

controlling the breathing of the patient by adjusting flow of air through the first air flow control device until the computed difference is substantially eliminated.
34. The method according to claim 33, further comprising determining concentration of gas flowing through at least one airflow control device;
and adjusting the flow of air through at least another airflow control device based on the concentration of gas flowing through the at least one airflow control device.
35. The method according to claim 34, further comprising determining whether the concentration of gas flowing through the at least one airflow control device exceeds the predetermined setpoint value; and increasing a flow of air through at least another airflow control device.
36. The method according to claim 34, further comprising determining whether the concentration of gas flowing through the at least one airflow control device is below the predetermined setpoint value; and decreasing a flow of air through the at least another airflow control device.
37. The method according to claim 33, wherein the predetermined setpoint value is calculated for the patient.
38. The method according to claim 33, further comprising periodically monitoring concentration of gas flowing through at least one airflow control device;

computing a value for the end-tidal concentration of CO2 in said gas flowing through the at least another airflow device, which represents an estimate of the partial pressure of said CO2 in the arterial blood of the patient;

comparing said end-tidal CO2 value to a predetermined range of acceptable end-tidal CO2 values; and adjusting the predetermined setpoint for concentration of gas flowing through the at least one airflow control device based on said comparing.
39. The method according to claim 38, further comprising determining whether the computed end-tidal CO2 value is lower than the range of acceptable end-tidal CO2 values; and increasing the predetermined setpoint value of concentration of gas flowing through the at least one airflow control device.
40. The method according to claim 38, further comprising determining whether the computed end-tidal CO2 value is higher than the range of acceptable end-tidal CO2 values; and decreasing the predetermined setpoint value of concentration of gas flowing through the at least one airflow control device.
41. The method according to claim 33, further comprising determining whether the patient is in a particular sleep stage;
adjusting at least one parameter based on the particular sleep stage.
42. A system for controlling breathing of a patient, comprising a respiratory conduit;

said respiratory conduit is configured to be coupled to a patient interface device;
said respiratory conduit is further configured to be coupled to a pressurized air generating device;

said respiratory conduit includes at least two air flow control devices, positioned between said patient interface device and said pressurized air generating device; and said respiratory conduit includes at least two volumes, wherein one volume is positioned between a first air flow control device and a second air flow control device and another volume is positioned between a second air flow control device and a third air flow control device.
43. The system according to claim 42, wherein said volumes are partial dead space volumes configured to accumulate at least a portion of breath expired by the patient.
44. The system according to claim 42, wherein said patient interface device is selected from a group consisting of a nasal mask, an oral mask, an orofacial mask, a nasal prong device, an intra-oral device, and an endotracheal tube.
45. The system according to claim 44, wherein said patient interface device is configured to create a substantially sealed connection between said respiratory conduit and a breathing airway passage of the patient.
46. The system according to claim 42, wherein said respiratory conduit includes an auxiliary air flow control device located substantially adjacent to said patient interface device configured to control flow of air to the airway of the patient.
47. The system according to claim 45, wherein said auxiliary air flow control device is controlled by the patient.
48. The system according to claim 42, wherein said respiratory conduit includes an anti-asphyxiation valve configured to create an access to air and to bypass said respiratory conduit, if said pressurized air generating device fails, and located substantially adjacent to said patient interface device.
49. The system according to claim 42, wherein said air flow control devices are configured to adjust said rate of gas flow through said air flow control devices based on at least one physiological variable of the patient.
50. The system according to claim 42, wherein said air flow control devices and said volumes are configured to control a rate of excretion of gas from said respiratory conduit; and a concentration of said gas in the blood of the patient.
51. The system according to claim 50, wherein said air flow control devices and said volumes are configured to allow a range of amounts of said gas readily excreted from said respiratory conduit to be equal to a range of production of said gas by the patient.
52. The system according to claim 42, wherein said gas is carbon dioxide.
53. The system according to claim 42, wherein said first air flow control device is configured to allow an escape of an amount of said gas that is lower than or equal to the amount of said gas produced by the patient at a time.
54. The system according to claim 53, wherein said second air flow control device is configured to allow an escape of an amount of said gas that is based on said amount of gas allowed to escape from said first air flow control device, and a maximum total amount of gas produced by the patient at a time.
55. The system according to claim 54, wherein said third air flow control device is configured to allow an escape of air that is based on said amount of air allowed to escape from said first and said second air flow control devices to prevent re-breathing of excess amount of said gas by the patient.
56. The system according to claim 42, wherein said respiratory conduit is configured to be rotatably coupled to said patient interface device.
57. The system according to claim 42, wherein said respiratory conduit includes a protective cover configured to prevent damage to said respiratory conduit.
58. The system according to claim 42, further comprising a collector configured to be coupled to said respiratory conduit and further configured to collect condensation during breathing of the patient.
59. A method for stabilizing breathing of a patient, comprising controlling a level of carbon dioxide in a blood of the patient using the system of claim 42.
60. A method for stabilizing breathing of a patient, comprising increasing a level of oxygen in a blood of the patient using the system of claim 42.
61. A system for controlling breathing of a patient, comprising:

a respiratory conduit configured to be coupled a patient interface device;

said respiratory conduit is configured to be coupled to a pressurized air supply device, wherein said pressurized air supply device supplies air to the patient;

wherein said respiratory conduit includes a first valve located substantially adjacent to said patient interface device, said first valve includes a first opening configured to control an escape of gas;

a second valve including a second opening configured to control an escape of gas;

a first volume connector coupled to said first valve and said second valve, said first volume connector is configured to contain a mixture of said air as supplied by said pressurized air supply device and said gas as generated by the patient;

a third valve including a third fixed opening configured to control an escape of air;

a second volume connector coupled to said second valve and said third valve, wherein said second volume connector is configured to contain a mixture of said air as supplied by said pressurized air supply device and said gas as generated by the patient; and a third connector coupled to said third valve and said air supply device.
62. The system according to claim 61, wherein said patient interface device is configured to create a substantially sealed connection to a breathing airway of the patient and said respiratory conduit.
63. The system according to claim 61, wherein said patient interface device includes a first opening configured to control escape of air from said patient interface device.
64. The system according to claim 61, wherein an amount of gas contained in said second volume connector is substantially equal to an amount of said gas expired by the patient during a single breath minus an amount of gas accumulated in the first volume connector.
65. The system according to claim 61, wherein an amount of gas allowed to escape from said first valve is determined by the amount of air allowed to escape from said first valve, the amount of air and said gas contained in said first connector, the amount of air and said gas allowed to escape from the second valve, and the amount of air and said gas contained in said second connector.
66. The system according to claim 61, wherein an amount of gas allowed to escape from said second valve is determined by the amount of air allowed to escape from said first valve, the volume of said first connector, the amount of air allowed to escape from said second valve, and the amount of air and said gas contained in said second connector.
67. The system according to claim 61, wherein an amount of air allowed to escape from said third valve is determined by the total amount of said air allowed to escape from said first and second valves, and air supplied by said pressurized air supply device, and the amount of air configured to expel an excessive amount of said gas from said respiratory conduit.
68. The system according to claim 61, wherein at least a portion of an amount of gas that does not escape from said first valve is re-breathed by the patient.
69. The system according to claim 61, wherein at least a portion of an amount of gas that does not escape from said second valve is re-breathed by the patient.
70. The system according to claim 61, wherein at least a portion of an amount of gas that exceeds the amount of gas accumulated in said first volume connector plus the amount of gas accumulated in said second volume connector is completely expelled from said respiratory conduit through said third valve.
71. The system according to claim 61, wherein said respiratory conduit includes an auxiliary air flow control device located substantially adjacent to said patient interface device.
72. The system according to claim 61, wherein said respiratory conduit includes an anti-asphyxiation valve configured to control flow of air into the airway of the patient.
73. A method for stabilizing breathing of a patient, comprising controlling a level of carbon dioxide in a blood of the patient using the system of claim 61.
74. A method for stabilizing breathing of a patient, comprising increasing a level of oxygen in a blood of the patient using the system of claim 61.
75. A system for controlling breathing of a patient, comprising:

a respiratory conduit configured to be coupled to a patient interface device of the patient;

said respiratory conduit is configured to be coupled to a pressurized air supply device, wherein said pressurized air supply device supplies air to the patient at the other end;
wherein said respiratory conduit includes a first valve located adjacent said patient interface device and includes a first opening configured to control escape of said gas during the breathing process;

a second valve that includes a second opening configured to control escape of gas during the breathing process;

a first volume connector connecting said first valve and said second valve and configured to control supply of gas to the patient during the breathing process;

a third valve that includes a third opening configured to control escape of gas during the breathing process;

a second volume connector connecting said second valve and said third valve and configured to control supply of gas to said first volume connector; and a third connector connecting said second valve and said air supply device.
76. The system according to claim 75, wherein said patient interface device is configured to create a substantially sealed connection between said respiratory conduit and a patient breathing airway.
77. The system according to claim 75, wherein said patient interface device includes a first opening configured to control escape of air from said patient interface device.
78. A method for stabilizing breathing of a patient, comprising controlling a level of carbon dioxide in a blood of the patient using the system of claim 75.
79. A method for stabilizing breathing of a patient, comprising increasing a level of oxygen in a blood of the patient using the system of claim 75.
80. A system for controlling breathing of a patient, comprising a respiratory conduit;

said respiratory conduit is configured to be coupled to a patient interface device;
said respiratory conduit is further configured to be coupled to a pressurized air generating device;

said respiratory conduit includes at least two air flow control devices, positioned between said patient interface device and said pressurized air generating device; and said respiratory conduit includes at least two volumes, wherein one volume is positioned between a first air flow control device and a second air flow control device and another volume is positioned between a second air flow control device and a third air flow control device;

wherein said second airflow control device configured to control evacuation of air from an airflow control conduit that is further configured to include multiple openings.
81. The system according to claim 80, wherein said airflow control conduit is configured to be at least partially disposed within said other volume.
82. The system according to claim 80, wherein said airflow control conduit includes a control valve configured to adjust airflow through each one of said multiple openings.
83. A method for controlling flow of carbon dioxide to a patient, comprising controlling a level of carbon dioxide in blood of the patient using the system of claim 80;

wherein said controlling includes:

measuring airflow through at least one of said airflow control devices;
detecting a content of carbon dioxide in the measured airflow;

adjusting airflow through at least one other one of said airflow control devices based on said detecting of said concentration of carbon dioxide; and adjusting sizes of said volumes based on said detection of said concentration-of carbon dioxide and said adjusting of said airflow through at least one of said air flow control devices.
84. The system according to claim 83, wherein said adjusting sizes step further comprises adjusting sizes of said volumes and said airflow through at least one of said airflow control devices based on a relationship between ~ co2 and ~ E, wherein ~ co2 is a rate of excretion of carbon dioxide by the patient per minute; V E is a total rate of ventilation per minute by the patient.
85. The system according to claim 84, wherein a curve representing said relationship between V co2 and V E contains at least two discontinuities;

said discontinuities are determined using the lengths of a hypoventilatory traverse segment caused by a placement of said first airflow control device in the system;

a first respiratory plateau segment caused by a placement of said volume in the system;

at least one eucapnic traverse segment caused by a placement of said multiple openings in said second airflow control device;

a second respiratory plateau segment caused by a placement of said another volume in the system; and a hyperventilatory traverse segment caused by a placement of said third airflow control device in the system.
86. The system according to claim 85, wherein-said hypoventilatory traverse segment has a slope defined by a relationship between volume of air breathed by the patient during a breathing interval and an amount of carbon dioxide exhaled by the patient in said breathing interval.
87. The system according to claim 85, wherein during said eucapnic traverse segment, an additional volume of carbon dioxide escapes from at least one of said multiple openings of said second airflow control device, wherein said additional volume is determined based on the volume of carbon dioxide that escaped from said first airflow control device.
88. The system according to claim 85, wherein during said hyperventilatory traverse segment, an additional volume of carbon dioxide escapes from said third airflow control device, wherein said additional volume is determined based on a volume of carbon dioxide that escaped from at least said first and second airflow control devices.
89. The system according to claim 84, wherein said controlling further includes determining a target mean arterial concentration of carbon dioxide based on said adjusting sizes step.
90. The system according to claim 84, wherein said adjusting sizes step is automatic.
91. The system according to claim 84, wherein said adjusting sizes step is manual.
92. The system according to claim 80, wherein said volumes are partial dead space volumes configured to accumulate at least a portion of breath expired by the patient.
93. The system according to claim 80, wherein said patient interface device is selected from a group consisting of a nasal mask, an oral mask, an orofacial mask, a nasal prong device, an intra-oral device, and an endotracheal tube.
94. The system according to claim 93, wherein said patient interface device is configured to create a substantially sealed connection between said respiratory conduit and a breathing airway passage of the patient.
95. The system according to claim 80, wherein said respiratory conduit includes an auxiliary air flow control device located substantially adjacent to said patient interface device configured to control flow of air to the airway of the patient.
96. The system according to claim 95, wherein said auxiliary air flow control device is controlled by the patient.
97. The system according to claim 80, wherein said respiratory conduit includes an anti-asphyxiation valve configured to create an access to air and to bypass said respiratory conduit, if said pressurized air generating device fails, and located substantially adjacent to said patient interface device.
98. The system according to claim 80, wherein said air flow control devices are configured to adjust said rate of gas flow through said air flow control devices based on at least one physiological variable of the patient.
99. The system according to claim 80, wherein said air flow control devices and said volumes are configured to control a rate of excretion of gas from said respiratory conduit; and a concentration of said gas in the blood of the patient.
100. The system according to claim 99, wherein said air flow control devices and said volumes are configured to allow a range of amounts of said gas readily excreted from said respiratory conduit to be equal to a range of production of said gas by the patient.
101. The system according to claim 80, wherein said gas is carbon dioxide.
102. The system according to claim 80, wherein said first air flow control device is configured to allow an escape of an amount of said gas that is lower than or equal to the amount of said gas produced by the patient at a time.
103. The system according to claim 102, wherein said second air flow control device is configured to allow an escape of an amount of said gas that is based on said amount of gas allowed to escape from said first air flow control device, and a maximum total amount of gas produced by the patient at a time.
104. The system according to claim 102, wherein said third air flow control device is configured to allow an escape of air that is based on said amount of air allowed to escape from said first and said second air flow control devices to prevent re-breathing of excess amount of said gas by the patient.
105. The system according to claim 80, wherein said respiratory conduit is configured to be rotatably coupled to said patient interface device.
106. The system according to claim 80, wherein said respiratory conduit includes a protective cover configured to prevent damage to said respiratory conduit.
107. The system according to claim 80, further comprising a collector configured to be coupled to said respiratory conduit and further configured to collect condensation during breathing of the patient.
108. A system for controlling breathing of a patient, comprising:

a respiratory conduit configured to be coupled to a patient interface device of the patient;

said respiratory conduit is configured to be coupled to a pressurized air supply device, wherein said pressurized air supply device supplies air to the patient at the other end;
wherein said respiratory conduit includes a first valve located adjacent said patient interface device and includes a first opening configured to control escape of said gas during the breathing process;

a second valve configured to withdraw air from at least one location within said respiratory conduit during the breathing process;

a first volume connector connecting said first valve and said second valve and configured to control supply of gas to the patient during the breathing process;

a third valve that includes a third opening configured to control escape of gas during the breathing process;

a second volume connector connecting said second valve and said third valve and configured to allow withdrawal of air from said at least one location within said second volume; and a third connector connecting said second valve and said air supply device.
109. A system for controlling breathing of a patient, comprising a respiratory conduit;

said respiratory conduit is configured to be coupled to a patient interface device;
said respiratory conduit is further configured to be coupled to a pressurized air generating device;

said respiratory conduit includes at least two volumes, positioned between said patient interface device and said pressurized air generating device; and said respiratory conduit includes at least two air flow control devices, wherein said at least one airflow control device is configured to withdraw air from at least one location within said respiratory conduit.
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