IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0775565
(2010-05-07)
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등록번호 |
US-8638200
(2014-01-28)
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발명자
/ 주소 |
- Milne, Gary
- Hensley, Kirk
- Doyle, Peter R.
- Kimm, Gardner
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출원인 / 주소 |
|
인용정보 |
피인용 횟수 :
4 인용 특허 :
257 |
초록
▼
This disclosure describes systems and methods for monitoring and evaluating ventilatory parameters, analyzing those parameters and providing useful notifications and recommendations to clinicians. That is, modern ventilators monitor, evaluate, and graphically represent a myriad of ventilatory parame
This disclosure describes systems and methods for monitoring and evaluating ventilatory parameters, analyzing those parameters and providing useful notifications and recommendations to clinicians. That is, modern ventilators monitor, evaluate, and graphically represent a myriad of ventilatory parameters. However, many clinicians may not easily identify or recognize data patterns and correlations indicative of certain patient conditions, changes in patient condition, and/or effectiveness of ventilatory treatment. Further, clinicians may not readily determine appropriate ventilatory adjustments that may address certain patient conditions and/or the effectiveness of ventilatory treatment. Specifically, clinicians may not readily detect or recognize the presence of Auto-PEEP during volume ventilation of a non-triggering patient. According to embodiments, a ventilator may be configured to monitor and evaluate diverse ventilatory parameters to detect Auto-PEEP and may issue suitable notifications and recommendations to the clinician when Auto-PEEP is implicated. The suitable notifications and recommendations may further be provided in a hierarchical format.
대표청구항
▼
1. A ventilator-implemented method for detecting Auto-PEEP during volume ventilation of a non-triggering patient, the method comprising: receiving one or more ventilatory settings associated with volume ventilation of the non-triggering patient;collecting data associated with ventilatory parameters;
1. A ventilator-implemented method for detecting Auto-PEEP during volume ventilation of a non-triggering patient, the method comprising: receiving one or more ventilatory settings associated with volume ventilation of the non-triggering patient;collecting data associated with ventilatory parameters;processing at least some of the collected ventilatory parameter data, wherein processing the collected ventilatory parameter data includes deriving ventilatory parameter data from at least some of the collected ventilatory parameter data;analyzing the processed ventilatory parameter data, wherein analyzing the processed ventilatory parameter data comprises: determining one or more predetermined thresholds for detecting Auto-PEEP based at least in part on the one or more ventilatory settings; andmonitoring whether the processed ventilatory parameter data breaches the one or more predetermined thresholds;determining, by the ventilator, that Auto-PEEP is implicated for the non-triggering patient upon detecting that the processed ventilatory data breaches the one or more predetermined thresholds;determining a list of entries for mitigating Auto-PEEP based at least in part on identifying the patient as non-triggering; andissuing a smart prompt when Auto-PEEP is implicated, the smart prompt displaying: a notification that Auto-PEEP is implicated; andthe list of entries for mitigating Auto-PEEP, comprising one or more of: decrease respiratory rate;increase flow;adjust ventilatory settings until end-expiratory flow (EEF) approximates zero;investigate reasons for increased resistance; andinvestigate reasons for increased compliance. 2. The method of claim 1, wherein the processed ventilatory parameter data includes expiratory flow data, and wherein analyzing the processed ventilatory parameter data further comprises: receiving one or more predetermined thresholds associated with end-expiratory flow (EEF);detecting that EEF is positive when the EEF breaches the one or more predetermined thresholds; anddetermining that Auto-PEEP is implicated for the non-triggering patient when EEF is positive for a predetermined number of breaths. 3. The method of claim 1, wherein the processed ventilatory parameter data includes respiratory resistance and respiratory compliance data, further comprising: calculating a time required to reach functional residual capacity (FRC);comparing the time required to reach FRC with expiratory time (TE);determining that Auto-PEEP is implicated for the non-triggering patient when the time required to reach FRC is greater than TE. 4. The method of claim 1, wherein the processed ventilatory parameter data includes pressure data, and wherein analyzing the processed ventilatory parameter data further comprises: receiving a positive end-expiratory pressure (PEEP) setting, wherein the PEEP setting is about 0 cm H2O or greater;receiving one or more predetermined thresholds associated with end-expiratory pressure (EEP);detecting that the EEP breaches the one or more predetermined thresholds when the EEP minus the PEEP setting is greater than the one or more predetermined thresholds; anddetermining that Auto-PEEP is implicated for the non-triggering patient when the EEP breaches the one or more predetermined thresholds. 5. The method of claim 1, wherein the processed ventilatory parameter data includes respiratory resistance data, and wherein analyzing the processed ventilatory parameter data further comprises: receiving one or more predetermined thresholds associated with the respiratory resistance data;detecting that respiratory resistance has increased when the respiratory resistance data breaches the one or more predetermined thresholds; anddetermining that Auto-PEEP is implicated for the non-triggering patient when the respiratory resistance has increased. 6. The method of claim 1, wherein the processed ventilatory parameter data includes a pulmonary time constant and an expiratory time (TE), and wherein analyzing the processed ventilatory parameter data further comprises: comparing the pulmonary time constant to the TE; anddetermining that Auto-PEEP is implicated for the non-triggering patient when the TE is less than three pulmonary time constants. 7. A ventilatory system for issuing a smart prompt when Auto-PEEP is implicated during volume ventilation of a non-triggering patient, comprising: at least one processor; andat least one memory, communicatively coupled to the at least one processor and containing instructions that, when executed by the at least one processor, cause a controller to issue a smart prompt, the controller comprising: a user interface for receiving one or more ventilatory settings associated with volume ventilation of the non-triggering patient;an Auto-PEEP detection module for detecting that Auto-PEEP is implicated for the non-triggering patient upon detecting that parameter data breaches one or more predetermined thresholds, wherein the one or more predetermined thresholds are based at least in part on the one or more ventilatory settings;a smart prompt module for: determining a list of entries for mitigating Auto-PEEP based at least in part on identifying the patient as non-triggering; andissuing a smart prompt when Auto-PEEP is implicated, the smart prompt displaying: a notification that Auto-PEEP is implicated; anda list of entries for mitigating Auto-PEEP, the list of entries including one or more primary entries comprising one or more of: decrease respiratory rate; increase flow; adjust ventilatory settings until end-expiratory flow (EEF) approximates zero; investigate reasons for increased resistance; and investigate reasons for increased compliance. 8. The ventilatory system of claim 7, further comprising: determining the notification based at least in part on the parameter data that implicated Auto-PEEP. 9. The ventilatory system of claim 8, wherein the notification-comprises information regarding the parameter data that implicated Auto-PEEP. 10. The ventilatory system of claim 7, wherein the list of entries for mitigating Auto-PEEP are based at least in part on evaluating the parameter data that implicated Auto-PEEP. 11. The ventilatory system of claim 7, wherein the list of entries further includes one or more secondary entries. 12. The ventilatory system of claim 11, wherein the secondary entries include increasing expiratory time (TE) by one or more of: decreasing tidal volume (VT); andchanging to a square flow waveform. 13. A ventilator-implemented method for detecting Auto-PEEP during volume ventilation of a non-triggering patient, the method comprising: collecting data associated with ventilatory parameters;determining one or more predetermined thresholds for detecting Auto-PEEP; anddetermining, by the ventilator, that Auto-PEEP is implicated for the non-triggering patient upon detecting that the processed ventilatory data breaches the one or more predetermined thresholds;determining a list of entries for mitigating Auto-PEEP based at least in part on identifying the patient as non-triggering; andissuing a smart prompt when Auto-PEEP is implicated, the smart prompt displaying: a notification that Auto-PEEP is implicated; andthe list of entries for mitigating Auto-PEEP. 14. The method of claim 13, wherein the ventilatory parameter data includes expiratory flow data, the method further comprising: receiving one or more predetermined thresholds associated with end-expiratory flow (EEF);detecting that EEF is positive when the EEF breaches the one or more predetermined thresholds; anddetermining that Auto-PEEP is implicated for the non-triggering patient when EEF is positive for a predetermined number of breaths. 15. The method of claim 13, wherein the ventilatory parameter data includes respiratory resistance data and respiratory compliance data, the method further comprising: calculating a time required to reach functional residual capacity (FRC);comparing the time required to reach FRC with expiratory time (TE);determining that Auto-PEEP is implicated for the non-triggering patient when the time required to reach FRC is greater than TE. 16. The method of claim 13, wherein the ventilatory parameter data includes pressure data, and wherein analyzing the processed ventilatory parameter data further comprises: receiving a positive end-expiratory pressure (PEEP) setting, wherein the PEEP setting is about 0 cm H2O or greater;receiving one or more predetermined thresholds associated with end-expiratory pressure (EEP);detecting that the EEP breaches the one or more predetermined thresholds when the EEP minus the PEEP setting is greater than the one or more predetermined thresholds; anddetermining that Auto-PEEP is implicated for the non-triggering patient when the EEP breaches the one or more predetermined thresholds. 17. The method of claim 13, wherein the ventilatory parameter data includes respiratory resistance data, the method further comprising: receiving one or more predetermined thresholds associated with the respiratory resistance data;detecting that respiratory resistance has increased when the respiratory resistance data breaches the one or more predetermined thresholds; anddetermining that Auto-PEEP is implicated for the non-triggering patient when the respiratory resistance has increased. 18. The method of claim 13, wherein the ventilatory parameter data includes a pulmonary time constant and an expiratory time (TE), the method further comprising: comparing the pulmonary time constant to the TE; anddetermining that Auto-PEEP is implicated for the non-triggering patient when the TE is less than three pulmonary time constants.
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