Breathing assistance systems with lung recruitment maneuvers
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F16K-031/02
A61M-016/00
A62B-007/00
출원번호
US-0409406
(2009-03-23)
등록번호
US-8640699
(2014-02-04)
발명자
/ 주소
Baker, Jr., Clark R.
출원인 / 주소
Covidien LP
인용정보
피인용 횟수 :
0인용 특허 :
155
초록▼
The disclosure provides a method for controlling the delivery of a breathing gas to a patient including automatic lung recruitment maneuvers. The method may include regulating the FiO2 and the PEEP of the breathing gas delivered to the patient, determining a blood oxygenation level of the patient, a
The disclosure provides a method for controlling the delivery of a breathing gas to a patient including automatic lung recruitment maneuvers. The method may include regulating the FiO2 and the PEEP of the breathing gas delivered to the patient, determining a blood oxygenation level of the patient, automatically adjusting the FiO2 of the breathing gas delivered to the patient based on at least the blood oxygenation level of the patient, and in response to determining that the FiO2 of the breathing gas delivered to the patient exceeds a pre-determined value: automatically initiating a lung recruitment maneuver; and automatically increasing the PEEP of the breathing gas delivered to the patient.
대표청구항▼
1. A method for controlling a delivery of a breathing gas to a patient using a processor, the method including: regulating a fractional inspired oxygen (FiO2) and a positive end expiratory pressure (PEEP) of the breathing gas delivered to the patient;determining a blood oxygenation level of the pati
1. A method for controlling a delivery of a breathing gas to a patient using a processor, the method including: regulating a fractional inspired oxygen (FiO2) and a positive end expiratory pressure (PEEP) of the breathing gas delivered to the patient;determining a blood oxygenation level of the patient;automatically adjusting the FiO2 of the breathing gas delivered to the patient based on the blood oxygenation level of the patient; andin response to determining that the FiO2 of the breathing gas delivered to the patient exceeds a pre-determined value: automatically initiating a lung recruitment maneuver to achieve a lung recruitment;after completion of the lung recruitment maneuver: setting a post-recruitment maneuver PEEP at a higher level than a PEEP level setting prior to the lung recruitment maneuver;periodically determining, at a first specified frequency, whether to adjust the FiO2 of the delivered breathing gas; andperiodically determining, at a second specified frequency, whether to reduce the PEEP;wherein the second defined frequency of PEEP reduction determinations is lower than the first defined frequency of FiO2 adjustment determinations such that the FiO2 is allowed to reach equilibrium between successive PEEP reduction determinations. 2. The method of claim 1, wherein the blood oxygenation level is determined by measuring saturation of peripheral oxygen (SpO2) in the patient. 3. The method of claim 1, wherein the lung recruitment maneuver includes: inflating lungs of the patient at a relatively high pressure; andmaintaining the inflation of the lungs for a duration long enough to distend collapsed aveoli. 4. The method of claim 1, wherein the lung recruitment maneuver includes: inflating lungs of the patient at a relatively high pressure, the pressure preset by a user; andmaintaining the inflation of the lungs for a duration long enough to distend collapsed aveoli, the duration preset by the user. 5. The method of claim 1, wherein the lung recruitment maneuver includes: inflating lungs of the patient at a relatively high pressure, the pressure determined by a ventilation parameter; andmaintaining the inflation of the lungs for a duration long enough to distend collapsed aveoli, the duration determined by the ventilation parameter. 6. The method of claim 1, further comprising inhibiting the adjustment of the fractional inspired oxygen of the breathing gas delivered to the patient during the lung recruitment maneuver. 7. The method of claim 1, wherein maintaining a duration of the lung recruitment after completion of the lung recruitment maneuver comprises automatically adjusting the PEEP of the breathing gas delivered to the patient based on variations in the fractional inspired oxygen of the breathing gas delivered to the patient. 8. The method of claim 1, wherein maintaining a duration of the lung recruitment after completion of the lung recruitment maneuver comprises automatically adjusting the PEEP of the breathing gas delivered to the patient based on both: variations in the FiO2 of the breathing gas delivered to the patient; anda ventilation parameter including one cardiovascular indicator of the patient. 9. The method of claim 1, further comprising: regulating a third gas delivery parameter of the breathing gas delivered to the patient;automatically adjusting the third gas delivery parameter of the breathing gas delivered to the patient based on the blood oxygenation level of the patient; andadjusting the pre-determined value for automatic initiation of the lung recruitment maneuver based on the value of the third gas delivery parameter of the breathing gas delivered to the patient. 10. A breathing assistance system configured to deliver a breathing gas toward a patient, the system comprising: a gas delivery control system configured to regulate a fractional inspired oxygen (FiO2) and a positive end expiratory pressure (PEEP) of the breathing gas delivered to the patient;a parameter module configured to determine a blood oxygenation level of the patient;wherein the gas delivery control system: automatically adjusts the FiO2 of the breathing gas delivered to the patient based at least on the blood oxygenation level of the patient;automatically initiates a lung recruitment maneuver to achieve a lung recruitment when the FiO2 of the breathing gas exceeds a pre-determined value; andafter completion of the lung recruitment maneuver: sets a post-recruitment maneuver PEEP at a higher level than a PEEP level setting prior to the lung recruitment maneuver;periodically determines, at a first specified frequency, whether to adjust the FiO2 of the delivered breathing gas; andperiodically determines, at a second specified frequency, whether to reduce the PEEP;wherein the second defined frequency of PEEP reduction determinations is lower than the first defined frequency of FiO2 adjustment determinations such that the FiO2 is allowed to reach equilibrium between successive PEEP reduction determinations. 11. The system of claim 10, wherein the parameter module is configured to measure saturation of peripheral oxygen (SpO2) in the patient. 12. The system of claim 10, wherein the lung recruitment maneuver includes: inflating lungs of the patient at a relatively high pressure; andmaintaining the inflation of the lungs for a duration long enough to distend collapsed aveoli. 13. The system of claim 10, wherein the lung recruitment maneuver includes: inflating lungs of the patient at a relatively high pressure, the pressure preset by a user; andmaintaining the inflation of the lungs for a duration long enough to distend collapsed aveoli, the duration preset by the user. 14. The system of claim 10, wherein the lung recruitment maneuver includes: inflating lungs of the patient at a relatively high pressure, the pressure determined by a ventilation parameter; andmaintaining the inflation of the lungs for a duration long enough to distend collapsed aveoli, the duration determined by the ventilation parameter. 15. The system of claim 10, further comprising the gas delivery control system configured to inhibit the adjustment of the FiO2 of the breathing gas delivered to the patient during the lung recruitment maneuver. 16. The system of claim 10, wherein maintaining a duration of the lung recruitment after completion of the lung recruitment maneuver comprises automatically adjusting the PEEP of the breathing gas delivered to the patient based on variations in the FiO2 of the breathing gas delivered to the patient. 17. The system of claim 10, wherein maintaining a duration of the lung recruitment after completion of the lung recruitment maneuver comprises automatically adjusting the PEEP of the breathing gas delivered to the patient based on both: variations in the FiO2 of the breathing gas delivered to the patient; anda ventilation parameter including one cardiovascular indicator of the patient. 18. The system of claim 10, further comprising: the gas delivery control system configured to regulate a third parameter of the breathing gas delivered to the patient;the gas delivery control system configured to automatically adjust the third parameter of the breathing gas delivered to the patient based on the blood oxygenation level of the patient; andthe gas delivery control system configured to adjust the pre-determined value for automatic initiation of the lung recruitment maneuver based on the value of the third parameter of the breathing gas delivered to the patient. 19. A computer-readable storage medium storing a set of instructions executable on a processor, the set of instructions comprising: instructions for regulating a fractional inspired oxygen (FiO2) and a positive end expiratory pressure (PEEP) of a breathing gas delivered to a patient;instructions for determining a blood oxygenation level of the patient;instructions for automatically adjusting the FiO2 of the breathing gas delivered to the patient based on the blood oxygenation level of the patient; andinstructions for, in response to determining that the FiO2 of the breathing gas delivered to the patient exceeds a pre-determined value: automatically initiating a lung recruitment maneuver to achieve a lung recruitment; andafter completion of the lung recruitment maneuver: setting a post-recruitment maneuver PEEP at a higher level than a PEEP level setting prior to the lung recruitment maneuver;periodically determining, at a first specified frequency, whether to adjust the FiO2of the delivered breathing gas; andperiodically determining, at a second specified frequency, whether to reduce the PEEP;wherein the second defined frequency of PEEP reduction determinations is lower than the first defined frequency of FiO2 adjustment determinations such that the FiO2 is allowed to reach equilibrium between successive PEEP reduction determinations. 20. A breathing assistance system, comprising: means for regulating a fractional inspired oxygen (FiO2) and a positive end expiratory pressure (PEEP) of a breathing gas delivered to a patient;means for determining a blood oxygenation level of the patient;means for automatically adjusting the FiO2 of the breathing gas delivered to the patient based on the blood oxygenation level of the patient; andmeans for, in response to determining that the FiO2 of the breathing gas delivered to the patient exceeds a pre-determined value: automatically initiating a lung recruitment maneuver to achieve a lung recruitment;after completion of the lung recruitment maneuver: setting a post-recruitment maneuver PEEP at a higher level than a PEEP level setting prior to the lung recruitment maneuver;periodically determining, at a first specified frequency, whether to adjust the FiO2 of the delivered breathing gas; andperiodically determining, at a second specified frequency, whether to reduce the PEEP;wherein the second defined frequency of PEEP reduction determinations is lower than the first defined frequency of determinations such that the FiO2 is allowed to reach equilibrium between successive PEEP reduction determinations.
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