IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0130460
(2005-05-16)
|
등록번호 |
US-7270128
(2007-09-18)
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발명자
/ 주소 |
- Berthon Jones,Michael
- Hallett,Michael David
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출원인 / 주소 |
|
대리인 / 주소 |
Gottlieb Rackman & Reisman PC
|
인용정보 |
피인용 횟수 :
57 인용 특허 :
24 |
초록
▼
The invention prevents dynamic airway compression during ventilatory support of a patient. The respiratory airflow is determined by measurement or calculation, and a measure of the degree of dynamic airway compression is derived from the determined airflow. This measure is servo-controlled to be zer
The invention prevents dynamic airway compression during ventilatory support of a patient. The respiratory airflow is determined by measurement or calculation, and a measure of the degree of dynamic airway compression is derived from the determined airflow. This measure is servo-controlled to be zero by increasing expiratory pressure if the measure of the degree of dynamic airway compression is large or increasing, and by reducing expiratory pressure if the measure of the degree of dynamic airway compression is small or zero.
대표청구항
▼
What we claim is: 1. A method for preventing dynamic airway compression during ventilatory support of a patient comprising the steps of: providing an interface to the patient's airway, providing said interface with a supply of breathable gas at a controllable pressure and with an exhaust, determini
What we claim is: 1. A method for preventing dynamic airway compression during ventilatory support of a patient comprising the steps of: providing an interface to the patient's airway, providing said interface with a supply of breathable gas at a controllable pressure and with an exhaust, determining the patient's respiratory airflow, varying the pressure at the patient interface so as to provide ventilatory support to the patient, from at least the respiratory airflow determining the patient's airway conductance separately during the inspiratory and expiratory portions of at least one respiratory cycle and calculating a measure of the degree of dynamic airway compression as a function of the values of the inspiratory conductance and the expiratory conductance, and servo-controlling the measure of the degree of dynamic airway compression by increasing expiratory pressure if said measure is large or increasing, and reducing expiratory pressure if said measure is small or zero, wherein the measure of the degree of dynamic airway compression is calculated as a function of the difference between the inspiratory conductance and the expiratory conductance, or as a function of the ratio of the inspiratory conductance to the expiratory conductance. 2. The method as in claim 1 in which the separate conductances during inspiration and expiration are determined in accordance with the sub-steps of: superimposing a high-frequency oscillation on the patient interface pressure at a determined amplitude, identifying the inspiratory and expiratory portions of a respiratory cycle, measuring the component of the respiratory airflow at said high frequency separately over the inspiratory and expiratory portions of at least one respiratory cycle, and from the high-frequency component airflow measurements and the determined pressure amplitude, calculating the inspiratory airway conductance and the expiratory airway conductance. 3. A method for preventing dynamic airway compression during ventilatory support of a patient comprising the steps of: providing a variable pressure to the patient's airway so as to provide ventilatory support, determining the patient's respiratory airflow, measuring the patient's airway conductance separately during the inspiratory and expiratory portions of at least one respiratory cycle and calculating as a function of the determined respiratory airflow and the values of the inspiratory and expiratory conductances a measure of the degree of the patient's dynamic airway compression, and increasing or decreasing expiratory pressure in accordance with the calculated measure of the degree of dynamic airway compression, wherein the measure of the degree of dynamic airway compression is calculated as a function of the ratio of the inspiratory conductance to the expiratory conductance, or from the expiratory airflow versus time curve. 4. The method as in claim 3 in which, when the measure of the degree of dynamic airway compression is calculated from the expiratory airflow versus time curve, said measure is zero when the expiratory airflow decays exponentially from the moment of the peak expiratory airflow to end expiration, but is large when the expiratory airflow decreases suddenly from the peak expiratory flow and is then steady but non-zero for the remainder of expiration. 5. An apparatus for determining a pressure response to ameliorate dynamic airway compression during ventilatory support comprising: an interface to a patient's airway and an exhaust, a means for supplying breathable gas at a controllable pressure to the interface, a means for deriving an airflow signal from said interface, and a controller means adapted for: (a) controlling a variation of the pressure at the interface to provide ventilatory support to the patient; (b) controlling a determination of a measure of the degree of dynamic airway compression at least from data representing the airflow signal; and (c) servo-controlling the measure of the degree of dynamic airway compression by increasing the controllable pressure during expiration if the measure of the degree of dynamic airway compression is large or increasing, and decreasing the controllable pressure during expiration if the measure of the degree of dynamic airway compression is small or zero, wherein said measure of the degree of dynamic airway compression is derived by measuring the patient's airway conductance separately during the inspiratory and expiratory portions of at least one respiratory cycle, and calculating the measure of the degree of dynamic airway compression as a function of the values of the inspiratory and expiratory conductances. 6. The apparatus of claim 5 in which the measure of the degree of dynamic airway compression is calculated as a function of the difference between the inspiratory conductance and the expiratory conductance. 7. The apparatus of claim 5 in which the measure of the degree of dynamic airway compression is calculated as a function of the ratio of the inspiratory conductance to the expiratory conductance. 8. The apparatus of claim 5 in which the separate conductances during inspiration and expiration are measured by superimposing a high-frequency oscillation on the patient interface pressure at a determined amplitude, identifying the inspiratory and expiratory portions of a respiratory cycle, measuring the component of the respiratory airflow at said high frequency separately over the inspiratory and expiratory portions of at least one respiratory cycle, and from the high-frequency component airflow measurements and the determined pressure amplitude, calculating the inspiratory airway conductance and the expiratory airway conductance. 9. An apparatus for determining a pressure response to ameliorate dynamic airway compression during ventilatory support comprising: an interface to a patient's airway and an exhaust, a means for supplying breathable gas at a controllable pressure to the interface, a transducer for determining an airflow signal from said interface, and a processor with programmed instructions for controlling: (a) a variation of the pressure at the interface to provide ventilatory support to the patient; (b) a determination of a measure of a degree of dynamic airway compression as a function of data representing the airflow signal; and (c) increasing or decreasing expiratory pressure in accordance with the derived measure of the degree of dynamic airway compression, wherein said measure of the degree of dynamic airway compression is derived in accordance with instructions controlling measurement of the patient's airway conductance separately during the inspiratory and expiratory portions of at least one respiratory cycle, and calculation of the measure of the degree of dynamic airway compression as a function of the values of the inspiratory conductance and the expiratory conductance. 10. The apparatus of claim 9 in which the measure of the degree of dynamic airway compression is calculated as a function of the ratio of the inspiratory conductance to the expiratory conductance. 11. The apparatus of claim 9 in which the measure of the degree of dynamic airway compression is derived from the shape of the expiratory airflow versus time curve. 12. The apparatus of claim 11 in which said measure is zero when the expiratory airflow decays exponentially from the moment of the peak expiratory airflow to end expiration, but is large when the expiratory airflow decreases suddenly from the peak expiratory flow and is then steady but non-zero for the remainder of expiration. 13. A storage medium with programmed instructions for use by an electronic processor to control a determination of a pressure response to ameliorate dynamic airway compression during ventilatory support, the instructions controlling the execution of the steps of: (a) varying a pressure value so as to control a provision of ventilatory support; (b) determining a measure of a degree of dynamic airway compression at least from calculated data representing measured airflow; and (c) servo-controlling the measure of the degree of dynamic airway compression by increasing the controllable pressure during expiration if the measure of the degree of dynamic airway compression indicates a need therefor, and decreasing the controllable pressure during expiration if the measure of the degree of dynamic airway compression is small or zero, wherein said measure of the degree of dynamic airway compression is derived in accordance with instructions controlling the sub-steps of: measuring the patient's airway conductance separately during the inspiratory and expiratory portions of at least one respiratory cycle, and calculating the measure of the degree of dynamic airway compression as a function of the values of the inspiratory conductance and the expiratory conductance. 14. The medium of claim 13 in which the measure of the degree of dynamic airway compression is calculated as a function of the difference between the inspiratory conductance and the expiratory conductance. 15. The medium of claim 13 in which the measure of the degree of dynamic airway conductance is calculated as a function of the ratio of the inspiratory conductance to the expiratory conductance. 16. The medium of claim 13 in which the separate conductances during inspiration and expiration are measured in accordance with instructions controlling the sub-steps of: superimposing a high-frequency oscillation on the variable pressure provided to the patient's airway, identifying the inspiratory and expiratory portions of each respiratory cycle, determining a component of the respiratory airflow at said high frequency separately over the inspiratory and expiratory portions of at least one respiratory cycle, and calculating the inspiratory and expiratory airway conductances from the high-frequency component airflow measurements. 17. The medium of claim 13 in which said instructions, during expiration, control an increase in expiratory pressure approximately linearly as a function of expired volume. 18. A method for preventing dynamic airway compression during ventilatory support of a patient comprising the steps of: providing a variable pressure device to supply pressure to the patient's airway so as to provide ventilatory support, providing an automatic apparatus for determining respiratory airflow and quantifying therefrom a degree of dynamic airway compression; determining the patient's respiratory airflow, and increasing or decreasing expiratory pressure automatically in accordance with the quantified degree of dynamic airway compression, wherein expiratory pressure is increased if the quantified degree of dynamic airway compression is large or increasing, and expiratory pressure is reduced if the quantified degree of dynamic airway compression is small or zero. 19. A method as in claim 18 in which the expiratory pressure is increased or decreased by servo-controlling the quantified degree of dynamic airway compression to automatically increase expiratory pressure if the quantified degree of dynamic airway compression is large or increasing, and automatically reduce expiratory pressure if the quantified degree of dynamic airway compression is small or zero. 20. A method as in claim 18 in which the quantified degree of dynamic airway compression is based upon a respiratory airflow determination made across a plurality of respiratory cycles. 21. A method as in claim 18 in which the quantified degree of dynamic airway compression is derived as a function of expiratory conductance. 22. A method as in claim 21 in which the quantified degree of dynamic airway conductance is derived as a further function of inspiratory conductance.
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