Nasal respiratory devices for positive end-expiratory pressure
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F16K-031/02
F15C-001/08
A62B-009/00
A62B-007/04
A62B-007/10
A62B-009/02
A61M-016/00
A61M-015/08
A61G-010/00
출원번호
UP-0811401
(2007-06-07)
등록번호
US-7806120
(2010-10-26)
발명자
/ 주소
Loomas, Bryan
Doshi, Rajiv
Pierce, Ryan Kendall
Howard, Robert A.
Hatanaka, Motohide
출원인 / 주소
Ventus Medical, Inc.
대리인 / 주소
Shay Glenn LLP
인용정보
피인용 횟수 :
43인용 특허 :
115
초록▼
Described herein are nasal respiratory devices, in particular, nasal respiratory devices configured to achieve positive end-expiratory pressure (PEEP) in a subject wearing the device. PEEP devices may have a threshold pressure for opening during expiration. In some variations, these devices have a t
Described herein are nasal respiratory devices, in particular, nasal respiratory devices configured to achieve positive end-expiratory pressure (PEEP) in a subject wearing the device. PEEP devices may have a threshold pressure for opening during expiration. In some variations, these devices have a threshold pressure for closing during expiration.
대표청구항▼
What is claimed is: 1. A compact nasal respiratory device for inducing positive end-expiratory pressure that is configured to be comfortably worn over a subject's nose while sleeping, the device comprising: a passageway; an airflow resistor in communication with the passageway, wherein the airflow
What is claimed is: 1. A compact nasal respiratory device for inducing positive end-expiratory pressure that is configured to be comfortably worn over a subject's nose while sleeping, the device comprising: a passageway; an airflow resistor in communication with the passageway, wherein the airflow resistor is configured to have a non-zero threshold pressure for opening during expiration so that the airflow resistor is closed during expiration when the pressure across the airflow resistor is below the threshold pressure for opening, but the airflow resistor opens during expiration when the pressure across the airflow resistor exceeds the threshold pressure for opening during expiration; and a holdfast configured to secure the entire device at least partially within or against the subject's nasal cavity without covering the subject's mouth. 2. The respiratory device of claim 1, wherein the threshold pressure for opening during expiration is less than about 20 cm H2O. 3. The respiratory device of claim 1, wherein the threshold pressure for opening during expiration is less than about 10 cm H2O. 4. The respiratory device of claim 1, wherein the threshold pressure for opening during expiration is more than about 1 cm H2O. 5. The respiratory device of claim 1, wherein the threshold pressure for opening during expiration is between about 4 cm H2O and about 20 cm H2O. 6. The respiratory device of claim 1, wherein the airflow resistor further comprises a non-zero threshold pressure for closing, such that the airflow resistor closes during expiration when the pressure across the airflow resistor falls below the threshold pressure for closing. 7. The respiratory device of claim 6, wherein the threshold pressure for closing during expiration is greater than about 4 cm H2O. 8. The respiratory device of claim 6, wherein the threshold pressure for closing during expiration is greater than about 10 cm H2O. 9. The respiratory device of claim 6, wherein the threshold pressure for closing during expiration is between about 0.5 cm H2O and about 20 cm H2O. 10. The respiratory device of claim 6, wherein the threshold pressure for closing during expiration is approximately the same as the threshold pressure for opening during expiration. 11. The respiratory device of claim 6, wherein the threshold pressure for closing during expiration is different from the threshold pressure for opening during expiration. 12. The device of claim 1, further comprising a valve configured to open during inspiration and close during expiration. 13. The device of claim 12, wherein the airflow resistor is configured to close a first pathway during expiration, and further wherein the valve is configured to close a second pathway during inspiration. 14. A compact nasal respiratory device for inducing positive end-expiratory pressure that is configured to be comfortably worn over the subject's nose while sleeping, the device comprising: a passageway; an airflow resistor in communication with the passageway, wherein the airflow resistor comprises a biased valve having a non-zero threshold pressure for opening during expiration, so that the airflow resistor is closed during expiration when the pressure across the valve is below the threshold pressure for opening, but the valve opens during expiration when the pressure across the valve exceeds the threshold pressure for opening during expiration; and a holdfast configured to secure the entire device at least partially within or against the subject's nasal cavity or both nasal cavities but not the subject's mouth. 15. The device of claim 14, wherein the airflow resistor comprises a second valve. 16. The device of claim 14, wherein the biased valve comprises a nested valve. 17. The device of claim 14, wherein the biased valve comprises a bistable valve. 18. A compact nasal respiratory device for inducing positive end-expiratory pressure that is configured to be comfortably worn over the subject's nose while sleeping, the device comprising: a passageway; an airflow resistor in communication with the passageway, the airflow resistor including a first valve configured to open during inspiration and close during expiration, and a second valve configured to open during expiration and close during inspiration; wherein the second valve is configured so that it does not open until the pressure across the second valve exceeds a non-zero threshold pressure for opening; and a holdfast configured to secure the entire device at least partially within or against the subject's nasal cavity without covering the subject's mouth. 19. The nasal respiratory device of claim 18, wherein the second valve is nested with the first valve. 20. The nasal respiratory device of claim 18, wherein the first valve comprises a flap valve. 21. The nasal respiratory device of claim 18, wherein the second valve comprises a biased valve. 22. The nasal respiratory device of claim 18, wherein the second valve comprises a bistable valve. 23. The respiratory device of claim 1, 14, or 18, wherein the passageway fits within an average nare. 24. A compact nasal respiratory device for inducing positive end-expiratory pressure that is configured to be comfortably worn over the subject's nose while sleeping, the device comprising: a first passageway and a second passageway; an airflow resistor comprising a first valve in communication with the first passageway and a second valve in communication with the second passageway, wherein the first valve is configured to open during inspiration and close during expiration, and the second valve is configured to close during inspiration and open during expiration when the pressure across the second valve exceeds a non-zero threshold pressure for opening; and a holdfast configured to secure the entire device at least partially within or against the subject's nasal cavity but not the subject's mouth. 25. The nasal respiratory device of claim 24, wherein the first valve comprises a flap valve. 26. The nasal respiratory device of claim 24, wherein the second valve comprises a biased valve. 27. The nasal respiratory device of claim 24, wherein the second valve comprises a bistable valve. 28. The respiratory device of claim 24, wherein the first and second passageways are shorter than the length of an average nare. 29. The respiratory device of claim 1, 14, 18, or 24, further comprising a nasal airflow monitor within or near the respiratory device to measure nasal airflow. 30. The respiratory device of claim 1, 14, 18, or 24, wherein the resistance provided by the airflow resistor is adjustable. 31. The respiratory device of claim 1, 14, 18, or 24, further comprising a leak path configured to be open during expiration. 32. The respiratory device of claim 1, 14, 18, or 24, wherein the holdfast is an adhesive holdfast. 33. The respiratory device of claim 1, 14, 18, or 24, wherein the holdfast is a shapeable holdfast. 34. A method of treating a disorder using a compact nasal device configured to be comfortably worn by a sleeping subject, the method comprising: securing an entire nasal respiratory device in, over, or at least partially within a subject's nasal cavity without covering the subject's mouth, wherein the airflow resistor is configured to have a non-zero threshold pressure for opening during expiration so that the airflow resistor is closed during expiration when the pressure across the airflow resistor is below the threshold pressure for opening, but the airflow resistor opens during expiration when the pressure across the airflow resistor exceeds the threshold pressure for opening during expiration; and allowing the subject to breathe at least partly through the nasal respiratory device. 35. The method of claim 34, wherein the disorder treated is selected from the group consisting of: respiratory disorders, sleep disorders, gastroenterologic disorders, and cardiovascular disorders. 36. The method of claim 34, wherein the nasal respiratory device is secured at least partially within the subject's nasal cavity. 37. The method of claim 34, wherein the nasal respiratory device is secured at least partially over the subject's nasal cavity.
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