阅读说明：本技术 口腔用具和阀布置 (Oral appliance and valve arrangement ) 是由 戴维·奥格尔 克里斯托弗·帕特里克·哈特 尼尔·安德森 本杰明·洛 乔纳森·舒 于 2019-03-12 设计创作，主要内容包括：一种呼吸辅助设备,包括口腔用具和阀布置。该口腔用具具有用具主体,该用具主体被成形为至少部分地定位在使用者的口腔内。该阀布置包括阀体和阀构件。阀体包括与使用者气道流体连通的阀气道,并且阀构件定位在该阀气道中,至少部分地由于穿过阀气道的气流而可在第一位置和第二位置之间移动。该阀构件在该第二位置中至少部分地阻塞该阀气道,使得在吸气和呼气期间存在差异阻力。(A breathing assistance apparatus comprising an oral appliance and a valve arrangement. The oral appliance has an appliance body shaped to be positioned at least partially within the mouth of a user. The valve arrangement comprises a valve body and a valve member. The valve body includes a valve air passage in fluid communication with the user air passage, and a valve member is positioned in the valve air passage movable between a first position and a second position due at least in part to air flow through the valve air passage. The valve member at least partially obstructs the valve airway in the second position such that there is differential resistance during inhalation and exhalation.)

1. A breathing assistance apparatus comprising:

a) an oral appliance having an appliance body shaped to be positioned at least partially within an oral cavity of a user; and the number of the first and second groups,

b) A valve arrangement comprising:

i) a valve body including a valve airway in fluid communication with a user airway; and the number of the first and second groups,

ii) a valve member located in the valve air passage, the valve member being movable between a first position and a second position at least partially due to airflow through the valve air passage, and wherein the valve member at least partially obstructs the valve air passage in the second position such that there is differential resistance during inhalation and exhalation.

2. The apparatus of claim 1, comprising:

a) an appliance airway that allows airflow into and/or out of a user's mouth; and the number of the first and second groups,

b) airflow is allowed to flow into and/or out of the nasal airways of the nasal cavity of the user.

3. The apparatus according to claim 1 or 2, wherein the valve arrangement generates positive airway pressure in the user's airway by at least one of:

a) restricting airflow during exhalation via the oral cavity; and the number of the first and second groups,

b) airflow during exhalation is restricted via the nasal cavity.

4. The apparatus of claim 2 or 3, wherein the valve arrangement comprises:

a) an oral valve to control breathing via the oral cavity; and the number of the first and second groups,

b) nasal valves that control breathing through the nasal cavity.

5. The apparatus of any of claims 1 to 4, wherein a valve configuration is used to control at least one of:

a) A degree of positive airway pressure in the user's airway;

b) the degree of airflow during exhalation; and the number of the first and second groups,

c) differential resistance during inspiration and expiration.

6. The apparatus of claim 5, wherein the valve configuration comprises at least one of:

a) the size or number of valve airway openings;

b) the size or number of valve member openings;

c) a valve member characteristic; and the number of the first and second groups,

d) a biasing member characteristic.

7. The apparatus of claim 5 or 6, wherein the valve configuration is selected based on a user's breathing characteristics.

8. The apparatus of any one of claims 1 to 7, wherein the valve member comprises one or more valve member openings to allow airflow through the valve member when the valve member is in the second position.

9. The apparatus of any one of claims 1 to 8, wherein the valve body comprises one or more openings to allow airflow through the valve body at least when the valve member is in the second position.

10. The apparatus of any of claims 1-9, wherein movement of the valve member is controlled based on at least one of:

a) a valve member characteristic comprising at least one of:

i) A valve member thickness;

ii) valve member material properties;

iii) valve member stiffness; and a process for the preparation of a coating,

iv) valve member surface area; and the number of the first and second groups,

b) a biasing member characteristic.

11. The apparatus of any one of claims 1-10, wherein movement between the first position and the second position is achieved by at least one of:

a) pivotal movement of the valve member; and the number of the first and second groups,

b) deformation of the valve member.

12. The device of any one of claims 1 to 11, wherein the valve member is a silicone flap.

13. The apparatus of any one of claims 1 to 12, wherein the valve member is biased into the first position by airflow through the valve air passage.

14. The apparatus of any of claims 1-13, wherein the valve member is biased into the second position by at least one of:

a) a gas flow through the valve gas passage; and the number of the first and second groups,

b) elasticity of the valve member.

15. The device of any one of claims 1 to 14, wherein the valve member is biased into the first position by elastic deformation of the valve member during inhalation and resiliently returns to the second position when a user is not inhaling.

16. The apparatus of any one of claims 1-15, wherein the valve member engages the valve body to retain the valve member in the second position.

17. The apparatus of any one of claims 1 to 16, wherein the appliance body comprises an extraoral opening extending between the lips of the user and an appliance airway passing through the appliance body to an intraoral opening disposed in the oral cavity to allow airflow into and/or out of a posterior region of the oral cavity.

18. The apparatus of claim 17, wherein the valve body is coupled to the extraoral opening by at least one of:

a) friction fit;

b) interference fit is carried out;

c) clamping and matching; and the number of the first and second groups,

d) and (4) magnetically engaging.

19. The apparatus of claim 17 or 18, wherein the valve body comprises a ring configured to be positioned outside and adjacent to the extraoral opening, and wherein the valve airway comprises one or more valve airway openings through the ring.

20. The apparatus of claim 19, wherein the valve member is coupled to the ring such that at least a portion of the valve member is positioned between the ring and the extraoral opening.

21. The apparatus of any one of claims 17-20, wherein the valve body comprises one or more guides to position the valve body relative to the extraoral opening.

22. The apparatus of any one of claims 17-21, wherein the valve body comprises one or more tabs having a lip adapted to engage a groove within the extraoral opening to thereby couple the valve body to the extraoral opening.

23. The apparatus of any one of claims 17-22, wherein at least a portion of the valve body is at least one of:

a) shaped to fit within the extraoral opening; and the number of the first and second groups,

b) shaped to fit over the extraoral opening.

24. The apparatus of any one of claims 17 to 23, wherein the valve body comprises a hollow tube having a substantially elliptical cross-section.

25. The apparatus of any one of claims 1-24, wherein the valve body comprises a plurality of valve air passage openings, and wherein the valve member is adapted to block selected ones of the valve air passage openings.

26. The apparatus of any one of claims 1 to 25, wherein the valve arrangement comprises a plurality of valve members.

27. The apparatus of any one of claims 1-26, wherein the valve body comprises at least one valve airway opening, and wherein the valve member at least partially obstructs the at least one valve airway opening.

28. The apparatus of claim 27, wherein the valve body includes a shoulder extending at least partially around the at least one valve air passage opening, and wherein the valve member engages the shoulder in the second position to retain the valve member in the second position.

29. The apparatus of claim 27 or 28, wherein the valve body comprises one or more struts extending across the opening, and wherein the valve member engages the struts in the second position to retain the valve member in the second position.

30. The apparatus of any one of claims 1-29, wherein the valve body is coupled to a nasal pillow that at least partially defines a nasal airway to allow airflow into and out of a nasal cavity of a user.

31. The apparatus of claim 30, wherein the nasal pillows are mounted on a nasal pillow connector body attachable to the valve body.

32. The apparatus of claim 31, wherein the nasal pillow connector body is movably mounted to the valve body to allow adjustment of a relative position of the nasal pillow and the valve body.

33. The apparatus of claim 31 or 32, wherein the nasal pillows and the nasal pillow connector body are integrally formed from a rigid or semi-rigid material such as nylon, polyurethane or silicone rubber.

34. The apparatus of any one of claims 31-33, wherein the nasal pillow connector is reversibly attachable by at least one of:

a) friction fit;

b) interference fit is carried out;

c) clamping and matching; and the number of the first and second groups,

d) and (4) magnetically engaging.

35. The apparatus of any one of claims 31-34, wherein the nasal pillow connector is attachable to the valve body by a nasal pillow connector rod.

36. The apparatus of any one of claims 31-34, wherein the valve body comprises a nasal valve body and an oral valve body, the nasal pillow connector being directly attachable to the nasal valve body such that the nasal airway is at least partially defined by the nasal valve body, the nasal pillow connector, and the nasal pillow.

37. The apparatus of claim 36, wherein the nasal valve body and the oral valve body are adjustably coupled to one another.

38. The apparatus of any one of claims 30-37, wherein a nasal cavity valve member is positioned in the nasal airway, the nasal cavity valve member being movable between a first position and a second position at least partially due to airflow through the nasal airway, and wherein the nasal cavity valve member at least partially obstructs the nasal airway in the second position such that there is differential resistance during inhalation and exhalation through the nasal cavity.

39. The apparatus according to any one of claims 30-38, wherein said nasal airway is at least one of:

a) in fluid communication with the valve gas passage; and the number of the first and second groups,

b) independent of the valve air passage.

40. The apparatus of any one of claims 1-39, wherein a device connector is coupled to the valve body, the device connector defining a device airway that supplies a flow of gas from a positive airway pressure device, and wherein the device airway is in fluid communication with at least one of:

a) the valve air passage; and the number of the first and second groups,

b) the nasal airways.

41. The apparatus of claim 40, wherein the device connector comprises a plurality of device connector airway openings to control air pressure in the device connector airway.

42. The apparatus of any one of claims 1 to 41, wherein the appliance body comprises a hollow side base extending inwardly from a hollow arcuate sidewall.

43. The apparatus according to any one of claims 1 to 42, wherein extraoral opening is defined by a tubular body projecting forwardly from the arcuate sidewall.

44. The apparatus of any one of claims 1 to 43, wherein the appliance body defines at least two channels, each channel connecting an intra-oral opening to an extra-oral opening, each channel passing through at least one of: at least partially along the oral cavity; and at least partially between the teeth, thereby providing the user with an airway that at least partially bypasses the nasal passage and functions to replicate a healthy nasal passage and pharyngeal space.

45. The apparatus according to any one of claims 1 to 44 wherein the oral appliance comprises at least one bite member coupled to the body, the bite member being positioned at least partially between a user's teeth and the body in use.

46. The apparatus of any one of claims 1-45, wherein the at least one snap member mechanically engages an inner surface of the hollow sidewall, thereby coupling the at least one snap member to the body.

47. The apparatus of any one of claims 1 to 46, wherein the valve member is part of a valve that is removably mounted to the valve body to allow for valve member interchange.

48. The apparatus of any one of claims 1 to 47, wherein the valve arrangement comprises a first valve mechanism for controlling resistance during inhalation and a second valve mechanism for providing resistance during exhalation.

49. The apparatus of any one of claims 1 to 48, wherein the valve member is mounted on a valve ring, and wherein the valve ring is biased into engagement with a valve seat within the valve body, such that movement of the valve member controls resistance during inhalation and such that biasing of the valve ring against the valve seat controls resistance during exhalation.

50. The apparatus of any one of claims 1 to 49, wherein the valve arrangement comprises:

a) a base attached to the valve body in use;

b) a spring; and the number of the first and second groups,

c) a valve ring supporting a valve member movable such that the valve ring is open during inhalation and closed during exhalation, and wherein the valve ring is biased into engagement with a valve seat such that the valve is open during exhalation and closed during inhalation.

51. The apparatus of claim 50, wherein the base is movably mounted to the valve body to allow adjustment of spring compression and control of resistance during exhalation.

52. The apparatus of any one of claims 1 to 51, wherein the valve arrangement comprises:

a) a first valve controlling resistance to airflow through the mouth of the user; and the number of the first and second groups,

b) a second valve controlling resistance to airflow through the nasal cavity of the user.

53. The apparatus of any one of claims 1 to 52, wherein the apparatus comprises a port in communication with at least one of an appliance airway and a valve airway, wherein in use the port is for delivering at least one of a gas and a drug to the airway of a subject.

54. The apparatus of claim 53, wherein the port is coupled to a delivery tube extending along an airway of an oral appliance.

55. Apparatus according to claim 53 or 54, wherein the apparatus comprises a second port in communication with the intra-oral opening, wherein in use the second port is for sampling exhaled air.

56. The apparatus of any one of claims 1 to 55, wherein the apparatus comprises first and second ports in communication with respective appliance intraoral openings.

57. The apparatus of any one of claims 1 to 56, wherein the appliance body comprises a tubular body configured to extend between the lips of a user, and wherein the tubular body comprises:

a) a first extraoral opening in fluid communication with an appliance airway that passes through the body to an intraoral opening disposed in the oral cavity to allow airflow into and/or out of a posterior region of the oral cavity; and the number of the first and second groups,

b) a second extraoral opening extending into the user's mouth to allow access to the mouth.

58. The apparatus of claim 57, wherein the second extraoral opening is configured to receive a surgical instrument.

59. A valve arrangement for use with an oral appliance having an appliance body shaped to be positioned at least partially within the oral cavity of a user, the valve arrangement comprising:

a) a valve body including a valve airway in fluid communication with a user airway; and the number of the first and second groups,

b) a valve member positioned in the valve airway, the valve member being movable between a first position and a second position at least partially due to gas flow through the valve airway, and wherein the valve member at least partially obstructs the valve airway in the second position such that there is differential resistance during inhalation and exhalation.

60. A breathing assistance apparatus comprising:

a) an oral appliance having an appliance body shaped to be positioned at least partially within a user's oral cavity, the appliance body including an extraoral opening extending between the user's lips and an appliance airway passing through the body to an intraoral opening disposed in the oral cavity to allow airflow into and/or out of a rear region of the oral cavity; and the number of the first and second groups,

b) a valve arrangement comprising:

i) a valve body comprising a valve air passage, the valve body coupled to the extraoral opening such that the valve air passage is in fluid communication with the appliance air passage; and the number of the first and second groups,

ii) a valve member positioned in the valve airway, the valve member being movable between a first position and a second position at least partially due to gas flow through the valve airway, and wherein the valve member at least partially obstructs the valve airway in the second position such that there is differential resistance during inhalation and exhalation.

61. A valve arrangement for use with an oral appliance having an appliance body shaped to be positioned at least partially within the oral cavity of a user, the appliance body including an extraoral opening extending between the lips of the user and an appliance airway passing through the body to an intraoral opening provided in the oral cavity to allow airflow into and/or out of a rear region of the oral cavity, the valve arrangement comprising:

a) A valve body comprising a valve air passage, the valve body coupled to the extraoral opening such that the valve air passage is in fluid communication with the appliance air passage; and the number of the first and second groups,

b) a valve member positioned in the valve airway, the valve member being movable between a first position and a second position at least partially due to gas flow through the valve airway, and wherein the valve member at least partially obstructs the valve airway in the second position such that there is differential resistance during inhalation and exhalation.

62. A method of configuring a breathing assistance apparatus for a user, the breathing assistance apparatus comprising:

a) an oral appliance having an appliance body shaped to be positioned at least partially within an oral cavity of a user; and the number of the first and second groups,

b) a valve arrangement comprising:

i) a valve body including a valve airway in fluid communication with a user airway; and the number of the first and second groups,

ii) a valve member positioned in the valve airway, the valve member being movable between a first position and a second position at least partially due to gas flow through the valve airway, and wherein the valve member at least partially obstructs the valve airway in the second position such that there is differential resistance during inhalation and exhalation, the method comprising

(1) Determining a breathing characteristic of the user; and the number of the first and second groups,

(2) configuring the breathing assistance apparatus at least partially according to the breathing characteristics of a user.

63. A method according to claim 62, wherein the method comprises configuring the breathing assistance apparatus by configuring the valve arrangement.

64. A method according to claim 63, wherein the method comprises configuring the valve arrangement to produce positive airway pressure in a user's airway by at least one of:

a) restricting airflow during exhalation via the oral cavity; and the number of the first and second groups,

b) airflow during exhalation is restricted via the nasal cavity.

65. A method according to any one of claims 62 to 64, wherein the method comprises configuring the breathing assistance apparatus to generate positive airway pressure in a user's airway by connecting a device airway to a device connector coupled to the valve body, the device connector defining a device airway that supplies a flow of gas from a positive airway pressure device, and wherein the device airway is in fluid communication with at least one of:

a) the valve air passage; and the number of the first and second groups,

b) the nasal airways.

66. A method according to any one of claims 62 to 65, wherein said method comprises progressively introducing positive airway pressure in the user's airway by at least one of:

a) Restricting airflow during exhalation via the oral cavity;

b) restricting airflow during exhalation via the nasal cavity;

c) restricting airflow during exhalation via the oral and nasal cavities;

d) supplying positive airway pressure from a positive airway pressure device; and the number of the first and second groups,

e) positive airway pressure is supplied from a positive airway pressure device and limits airflow during exhalation via the oral cavity.

Technical Field

The invention relates to a breathing assistance apparatus comprising an oral appliance and a valve arrangement configured to provide differential resistance during inhalation and exhalation.

Background

The reference in this specification to any prior publication (or information derived from it), or to any matter which is known, is not, and should not be taken as an acknowledgment or admission or any form of suggestion that the prior publication (or information derived from it) or known matter forms part of the common general knowledge in the field of endeavour to which this specification relates.

Poor or ineffective breathing is a problem that can affect people's performance in everyday activities while awake and/or asleep. While awake, this may not be the best performance in activities such as sports or even when performing daily tasks. While sleep disordered breathing can lead to snoring and/or sleep apnea.

Snoring is caused by the vibration of soft tissue within the individual's breathing path and is typically caused by the movement of obstructive air during breathing during sleep. Snoring can be caused by a range of different physical causes, such as sinus obstruction, and typically occurs when the upper throat muscles relax during sleep.

Snoring can also be associated with Obstructive Sleep Apnea (OSA), which is caused by obstruction of the upper airway and results in repeated pauses in breathing during normal sleep. Individuals with OSA often suffer from daytime sleepiness and fatigue associated with significant levels of sleep disturbance, while the sleep patterns of bed partner are often disturbed by associated snoring.

Current therapies for treating OSA may include lifestyle changes, the use of mechanical devices such as oral or nasal devices to enlarge the airway, surgical procedures to enlarge and stabilize the airway during sleep, and continuous or variable Positive Airway Pressure (PAP) devices.

However, unless absolutely necessary, surgery can be serious and therefore not widely used. Although PAP devices have had a positive impact, extended wear can be uncomfortable, expensive, and often noisy, which in turn can lead to sleep disturbances. Thus, the use of surgery and PAP therapy in the treatment of sleep apnea is limited and is not generally considered an appropriate treatment for snoring.

It has been shown that approximately 30-50% of continuous variable positive airway pressure (CPAP) device users are non-compliant users within 2 years of starting their treatment. CPAP systems deliver a flow of air to a mask that the user typically wears over their mouth and nose. CPAP masks have several disadvantages, including leakage and discomfort, and users often experience a degree of claustrophobia when wearing the mask.

In addition, relatively high pressures are typically required because CPAP systems must supply air at sufficient pressure to maintain the airway and to act as a pneumatic splint. In addition, high flow rates are required because the mask provides all of the air to the user during inhalation. To achieve such high pressures and flows, relatively large and noisy pumps, such as blowers, are typically used.

Accordingly, it is desirable to provide a system in which CPAP pressure and/or air flow rate can be minimized to reduce noise, vibration and pump size, thereby improving comfort and portability.

As other mechanical devices, nasal devices have been used that expand the nasal airway using traction or splinting. However, these methods are often not very successful and may be uncomfortable for the user.

US 2004/194787 describes an anti-snoring device comprising a flexible hollow tube for insertion into the mouth of a user, the hollow tube having proximal and distal ends and an outer periphery. The tube includes an extraoral segment at a proximal end thereof, an intraoral segment at a distal end thereof, and an intermediate segment extending therebetween. The extraoral and intraoral sections each include at least one opening. The extraoral segment is adapted to extend beyond the user's outer lip, the intermediate segment is of sufficient length to extend along the oropharyngeal passage of the user's mouth, and the intraoral segment is of sufficient length to extend beyond the space behind the molars in the user's mouth, into the open pharynx and terminating between the posterior tongue and the soft palate. The anti-snoring device further comprises a stopper extending from the outer periphery of the tube on the intraoral segment for securing the intraoral segment within the oropharynx of the user. However, while this arrangement may help provide an additional airway and thus reduce snoring and apnea events, it may be uncomfortable to wear and may move in the mouth during use, which may reduce the effectiveness of the device and in turn lead to additional breathing problems.

US 2005/150504 describes a device removably inserted in the mouth to facilitate breathing during sleep, which provides a clear, unobstructed airway by protrusive positioning of the mandible and/or delivery of pressurised air to the rear of the mouth. The device has upper and lower tooth contacting members and an airway defined therebetween, and is particularly designed for use with CPAP machines. Thus, the device can only be used in the limited environments available with CPAP machines and only for the treatment of sleep apnea.

WO2012/155214 describes a device for providing breathing assistance comprising a body including a recess for receiving a user's teeth to position the body within a user's mouth, a first opening extending beyond the user's lips to allow air to be drawn from outside the mouth through the opening, a second opening provided in the mouth to allow air to be directed into a rear region of the mouth, and a channel connecting the first and second openings, the channel extending through at least a portion of the buccal sulci of the user.

WO2017/020079 provides a device for providing breathing assistance comprising a body for positioning within the mouth of a user, the body defining at least one first opening for allowing airflow between the lips of the user, two second openings disposed in the mouth to allow airflow into and out of the back region of the mouth, two channels, each channel connecting a respective second opening to at least one first opening, and each channel passing at least one of at least partially along the buccal cavity and at least partially between the teeth, thereby providing an airway for the user, the airway at least partially bypassing the nasal passage so as to function to replicate a healthy nasal passage and pharyngeal cavity, and the body further defining a tongue retainer comprising a cavity for receiving a portion of the tongue of the user in use, wherein the tongue retainer is configured to retain the tongue in an extended position to at least partially protrude between the teeth of the user.

Disclosure of Invention

In one broad form, one aspect of the invention provides a breathing assistance apparatus comprising: an oral appliance having an appliance body shaped to be positioned at least partially within a user's mouth; and, a valve arrangement comprising: a valve body including a valve airway in fluid communication with a user airway; and a valve member located in the valve air passage, the valve member being movable between a first position and a second position at least partially due to airflow through the valve air passage, and wherein the valve member at least partially obstructs the valve air passage in the second position such that there is differential resistance during inhalation and exhalation.

In one embodiment, an oral appliance comprises: an appliance airway that allows airflow into and/or out of a user's mouth; and, allowing airflow into and/or out of the nasal airways of the nasal cavity of the user.

In one embodiment, the valve arrangement generates positive airway pressure in the airway of the user by at least one of: restricting airflow during exhalation via the oral cavity; and, restricting airflow during exhalation via the nasal cavity.

In one embodiment, the apparatus comprises: an oral valve arrangement to control breathing via the oral cavity; and a nasal valve arrangement to control breathing via the nasal cavity.

In one embodiment, the valve is configured to control at least one of: the degree of positive airway pressure in the user's airway; the degree of airflow during exhalation; and, differential resistance during inspiration and expiration.

In one embodiment, the valve configuration comprises at least one of: the size or number of valve airway openings; the size or number of valve member openings; a valve member characteristic; and a biasing member feature.

In one embodiment, the valve configuration is selected based on the breathing characteristics of the user.

In one embodiment, the valve member includes one or more valve member openings to allow airflow through the valve member when the valve member is in the second position.

In one embodiment, the valve body includes one or more openings to allow airflow through the valve body at least when the valve member is in the second position.

In one embodiment, movement of the valve member is controlled based on at least one of: a valve member characteristic comprising at least one of: a valve member thickness; valve member material properties; a valve member stiffness; and, a valve member surface region; and a biasing member feature.

In one embodiment, movement between the first and second positions is achieved by at least one of: pivotal movement of the valve member; and, deformation of the valve member.

In one embodiment, the valve member is a silicone flap.

In one embodiment, the valve member is biased into the first position by airflow through the valve air passage.

In one embodiment, the valve member is biased into the second position by at least one of: gas flow through the valve airway; and, the elasticity of the valve member.

In one embodiment, the valve member is biased into the first position by resilient deformation of the valve member during inhalation and resiliently returns to the second position when the user is not inhaling.

In one embodiment, the valve member engages the valve body to retain the valve member in the second position.

In one embodiment, the appliance body includes an extraoral opening extending between the lips of the user and an appliance airway passing through the body to an intraoral opening disposed in the oral cavity to allow airflow into and/or out of a rear region of the oral cavity.

In one embodiment, the valve body is coupled to the extraoral opening by at least one of: friction fit; interference fit is carried out; clamping and matching; and, magnetically engaging.

In one embodiment, the valve body comprises a ring configured to be positioned outside of and adjacent to the extraoral cavity, and wherein the valve airway comprises one or more valve airway openings through the ring.

In one embodiment, the valve member is coupled to the ring such that at least a portion of the valve member is positioned between the ring and the extraoral opening.

In one embodiment, the valve body includes one or more guides to position the valve body relative to the extraoral opening.

In one embodiment, the valve body includes one or more tabs including a lip adapted to engage a groove within the extraoral cavity, thereby coupling the valve body to the extraoral cavity opening.

In one embodiment, at least a portion of the valve body is at least one of: shaped to fit within the oral cavity outside the oral cavity; and shaped to fit over the extraoral opening.

In one embodiment, the valve body comprises a hollow tube having a substantially elliptical cross-section.

In one embodiment, the valve body comprises a plurality of valve air passage openings, and wherein the valve member is adapted to block selected ones of the valve air passage openings.

In one embodiment, the valve arrangement comprises a plurality of valve members.

In one embodiment, the valve body comprises at least one valve air passage opening, and wherein the valve member at least partially obstructs the at least one valve air passage opening.

In one embodiment, the valve body includes a shoulder extending at least partially around the at least one valve air passage opening, and wherein the valve member engages the shoulder in the second position to retain the valve member in the second position.

In one embodiment, the valve body includes one or more struts extending across the opening, and wherein the valve member engages the struts in the second position to retain the valve member in the second position.

In one embodiment, the valve body is coupled to a nasal pillow that defines a nasal airway to allow airflow into and out of the nasal cavity of the user.

In one embodiment, the nasal pillows are mounted on a nasal pillow connector body that is attachable to the valve body.

In one embodiment, the nasal pillow connector body is movably mounted to the valve body to allow adjustment of the relative position of the nasal pillow and the valve body.

In one embodiment, a nasal cavity valve member is positioned in the nasal airway, the nasal cavity valve member being movable between a first position and a second position due, at least in part, to airflow through the nasal airway, and wherein the nasal cavity valve member at least partially obstructs the nasal airway in the second position such that there is differential resistance during inhalation and exhalation through the nasal cavity.

In one embodiment, the nasal airway is at least one of: in fluid communication with the valve gas passage; and independent of the valve airway.

In one embodiment, a device connector is coupled to the valve body, the device connector defining a device airway that supplies a flow of gas from the positive airway pressure device, and wherein the device airway is in fluid communication with at least one of: a valve air passage; and nasal airways.

In one embodiment, the device connector includes a plurality of device connector airway openings to control air pressure in the device connector airway.

In one embodiment, the appliance body includes a hollow side base extending inwardly from the hollow arcuate sidewall.

In one embodiment, the extraoral opening is defined by a tubular body projecting forwardly from the arcuate sidewall.

In one embodiment, the appliance body defines at least two channels, each channel connecting the intra-oral opening to the extra-oral opening, each channel passing through at least one of: at least partially along the oral cavity; and at least partially between the teeth, thereby providing the user with an airway that at least partially bypasses the nasal passage and functions to replicate a healthy nasal passage and pharyngeal space.

In one embodiment, the oral appliance comprises at least one bite member coupled to the body, the bite member being positioned at least partially between the teeth of the user and the body in use.

In one embodiment, the at least one snap member mechanically engages an inner surface of the hollow sidewall, thereby coupling the at least one snap member to the body.

In one embodiment, the valve member is part of a valve that is removably mounted to the valve body to allow the valve members to be interchanged.

In one embodiment, the valve arrangement comprises a first valve mechanism that controls the resistance during inhalation and a second valve mechanism that provides the resistance during exhalation.

In one embodiment, the valve member is mounted on a valve ring, and wherein the valve ring is biased into engagement with a valve seat within the valve body, such that movement of the valve member controls resistance during inhalation, and biasing of the valve ring against the valve seat controls resistance during exhalation.

In one embodiment, the valve arrangement comprises: a base attached to the valve body in use; a spring; and a valve ring supporting a valve member, the valve member being movable such that the valve ring is open during inhalation and closed during exhalation, and wherein the valve ring is biased into engagement with the valve seat such that the valve is open during exhalation and closed during inhalation.

In one embodiment, the base is movably mounted to the valve body to allow adjustment of the spring compression and control of the resistance during exhalation.

In one embodiment, the valve arrangement comprises: a first valve arrangement which controls the resistance to airflow through the mouth of a user; and a second valve arrangement which controls the resistance to airflow through the nasal cavity of the user.

In one embodiment, the apparatus comprises a port in communication with at least one of the appliance airway and the valve airway, wherein in use the port is for delivering at least one of a gas and a drug to the airway of the subject.

In one embodiment, the port is coupled to a delivery tube that extends along the airway of the oral appliance.

In one embodiment, the device comprises a second port in communication with an intra-oral opening, wherein in use the port is for sampling exhaled air.

In one embodiment, the apparatus includes first and second ports in communication with respective intraoral openings of the appliance.

In one embodiment, the appliance body comprises a tubular body configured to extend between the lips of a user, and wherein the tubular body comprises: a first extraoral opening in fluid communication with an appliance airway through the body to an intraoral opening disposed in the oral cavity to allow airflow into and/or out of a posterior region of the oral cavity; and a second extraoral opening extending into the user's mouth to allow access to the mouth.

In one embodiment, the second extraoral opening is configured to receive a surgical instrument.

In one broad form, the invention provides, in one aspect, a valve arrangement for use with an oral appliance having a appliance body shaped to be positioned at least partially within the mouth of a user; and, a valve arrangement comprising: a valve body including a valve airway in fluid communication with a user airway; and a valve member located in the valve air passage, the valve member being movable between a first position and a second position at least partially due to airflow through the valve air passage, and wherein the valve member at least partially obstructs the valve air passage in the second position such that there is differential resistance during inhalation and exhalation.

In one broad form, one aspect of the invention provides a breathing assistance apparatus comprising: an oral appliance having an appliance body shaped to be positioned at least partially within the oral cavity of a user, the appliance body including an extraoral opening extending between the lips of the user and an appliance airway passing through the body to an intraoral opening disposed in the oral cavity to allow airflow into and/or out of a rear region of the oral cavity; and a valve arrangement comprising: a valve body including a valve airway, the valve body coupled to the extraoral opening such that the valve airway is in fluid communication with the appliance airway; and a valve member located in the valve air passage, the valve member being movable between a first position and a second position at least partially due to the flow of air through the valve air passage, and wherein the valve member at least partially obstructs the valve air passage in the second position such that there is a differential resistance during inhalation and exhalation.

In one broad form, the invention provides in one aspect a valve arrangement for use with an oral appliance having an appliance body shaped to be positioned at least partially within the mouth of a user, the appliance body including an extraoral opening extending between the lips of the user and an appliance airway passing through the body to an intraoral opening provided in the mouth to allow airflow into and/or out of a rear region of the mouth, the valve arrangement comprising: a valve body including a valve airway, the valve body coupled to the extraoral opening such that the valve airway is in fluid communication with the appliance airway; and a valve member located in the valve airway, the valve member being movable between a first position and a second position at least partially due to gas flow through the valve airway, and wherein the valve member at least partially obstructs the valve airway in the second position such that there is differential resistance during inhalation and exhalation.

In one broad form, one aspect of the invention provides a method of configuring a breathing assistance apparatus for a user, the breathing assistance apparatus comprising: an oral appliance having a device body shaped to be positioned at least partially within an oral cavity of a user; and, a valve arrangement comprising: a valve body including a valve airway in fluid communication with a user airway; and a valve member located in the valve airway, the valve member being movable between a first position and a second position at least partially due to gas flow through the valve airway, and wherein the valve member at least partially obstructs the valve airway in the second position such that there is differential resistance during inhalation and exhalation, the method comprising determining a breathing characteristic of the user; and configuring the breathing assistance apparatus at least partially according to the breathing characteristics of the user.

In one embodiment, the method comprises configuring the breathing assistance apparatus by configuring a valve arrangement.

In one embodiment, the method comprises configuring the valve arrangement to generate positive airway pressure in the airway of the user by at least one of: restricting airflow during exhalation via the oral cavity; and, restricting airflow during exhalation via the nasal cavity.

In one embodiment, the method includes configuring the breathing assistance apparatus to generate positive airway pressure in a user's airway by connecting a device airway to a device connector coupled to the valve body, the device connector defining a device airway that supplies a flow of gas from a positive airway pressure device, and wherein the device airway is in fluid communication with at least one of: a valve air passage; and nasal airways.

In one embodiment, the method includes progressively introducing positive airway pressure in the airway of the user by: restricting airflow during exhalation via the oral cavity; restricting airflow during exhalation via the nasal cavity; restricting the flow of air during exhalation through the oral and nasal cavities; providing positive airway pressure from a positive airway pressure device; and supplying positive airway pressure from the positive airway pressure device and restricting airflow during exhalation via the oral cavity.

It should be understood that the broad forms of the invention and their respective features may be used in combination, interchangeably and/or independently and that reference to a single broad form is not intended to be limiting.

Drawings

Various examples and embodiments of the invention will now be described with reference to the accompanying drawings, in which:

FIG. 1A is a schematic front top side perspective view of an example of an oral appliance;

FIG. 1B is a schematic rear top side perspective view of the oral appliance of FIG. 1A;

FIG. 1C is a schematic front view of the oral appliance of FIG. 1A;

FIG. 1D is a schematic plan view of the oral appliance of FIG. 1A;

FIG. 1E is a schematic cross-sectional view of the oral appliance along line A-A' of FIG. 1D;

FIG. 2A is a schematic rear top perspective view of an example of a valve arrangement;

FIG. 2B is a schematic front top perspective view of the valve arrangement of FIG. 2A;

FIG. 2C is a schematic front top side perspective view of a breathing assistance apparatus including the oral appliance of FIG. 1A and the valve arrangement of FIG. 2A;

fig. 2D is a schematic front view of the breathing assistance apparatus of fig. 2B;

fig. 2E is a schematic cross-sectional side view of the breathing assistance apparatus of fig. 2C;

fig. 2F is a schematic plan sectional view of the breathing assistance apparatus of fig. 2C;

FIG. 3A is a schematic rear top perspective view of another example of a valve arrangement;

FIG. 3B is a schematic front perspective view of the valve arrangement of FIG. 3A;

FIG. 3C is a schematic front view of the valve arrangement of FIG. 3A;

FIG. 3D is a schematic side view of the valve arrangement of FIG. 3A;

FIG. 3E is a schematic cross-sectional side view of a breathing assistance apparatus including the oral appliance of FIG. 1A and the valve arrangement of FIG. 3A;

FIG. 4A is a schematic rear top perspective view of another example of a valve arrangement;

FIG. 4B is a schematic front top perspective view of the valve arrangement of FIG. 4A;

FIG. 4C is a schematic cross-sectional side view of the valve arrangement of FIG. 4A;

FIG. 4D is a schematic cross-sectional side view of a breathing assistance apparatus including the oral appliance of FIG. 1A and the valve arrangement of FIG. 4A;

FIG. 5A is a schematic front underside perspective view of another example of a valve arrangement;

FIG. 5B is a schematic front top side perspective view of a breathing assistance apparatus including the oral appliance of FIG. 1A and the valve arrangement of FIG. 5A;

fig. 5C is a schematic perspective side cut-away view of the breathing assistance apparatus of fig. 5B;

fig. 5D is a schematic plan sectional view of the breathing assistance apparatus of fig. 5A;

FIG. 6A is a schematic front underside perspective view of another example of a valve arrangement;

FIG. 6B is a schematic rear top perspective view of the valve arrangement of FIG. 6A;

FIG. 6C is a schematic cross-sectional side view of the valve arrangement of FIG. 6A;

FIG. 6D is a schematic cross-sectional side view of a breathing assistance apparatus including the oral appliance of FIG. 1A and the valve arrangement of FIG. 6A;

FIG. 7A is a schematic front top side perspective view of another example of an oral appliance;

FIG. 7B is a schematic rear top side perspective view of the oral appliance of FIG. 7A;

fig. 8A is a schematic front top perspective view of another example of a breathing assistance apparatus including a valve arrangement;

FIG. 8B is a schematic front top side cross-sectional view of the breathing assistance apparatus of FIG. 8A;

fig. 8C is a schematic underside view of the breathing assistance apparatus of fig. 8A;

fig. 8D is a schematic cross-sectional side view of the breathing assistance apparatus of fig. 8A;

fig. 9A is a schematic front top perspective view of another example of a breathing assistance apparatus including a valve arrangement;

FIG. 9B is a schematic front top side cross-sectional view of the breathing assistance apparatus of FIG. 9A;

fig. 10A is a schematic front top perspective view of another example of a breathing assistance apparatus;

fig. 10B is a schematic cross-sectional side view of the breathing assistance apparatus of fig. 10A;

fig. 10C is a schematic underside view of the breathing assistance apparatus of fig. 10A;

fig. 11A is a schematic front top perspective view of another example of a breathing assistance apparatus;

fig. 11B is a schematic cross-sectional side view of the breathing assistance apparatus of fig. 11A;

fig. 11C is a schematic underside view of the breathing assistance apparatus of fig. 11A;

FIG. 12A is a schematic front top perspective view of an example of a valve arrangement;

FIG. 12B is a schematic cross-sectional side view of the valve arrangement of FIG. 12A;

fig. 13A is a schematic front top perspective view of another example of a breathing assistance apparatus;

fig. 13B is a schematic cross-sectional side view of the breathing assistance apparatus of fig. 13A;

Fig. 14A is a schematic front top perspective view of another example of a valve arrangement for a breathing assistance apparatus;

FIG. 14B is a schematic perspective view of the nasal pillow of FIG. 14A;

fig. 15A is a schematic front top perspective view of another example of a breathing assistance apparatus;

FIG. 15B is a schematic perspective view of the nasal pillow of FIG. 15A;

fig. 16A is a schematic front top perspective view of another example of a valve arrangement for a breathing assistance apparatus;

FIG. 16B is a schematic perspective cross-sectional view of the valve arrangement of FIG. 16A;

FIG. 16C is a schematic perspective cross-sectional view of the valve arrangement of FIG. 16A;

fig. 17A is a schematic front underside perspective view of another example of a valve arrangement for a breathing assistance apparatus;

FIG. 17B is a schematic perspective cross-sectional view of the valve arrangement of FIG. 17A;

fig. 18A is a schematic front underside perspective view of another example of a valve arrangement for a breathing assistance apparatus;

FIG. 18B is a schematic perspective cross-sectional view of the valve arrangement of FIG. 18A;

FIG. 18C is a schematic front top view of the valve regulator;

FIG. 18D is a schematic front lower perspective view of the valve arrangement of FIG. 18A and the valve regulator of FIG. 18C;

fig. 19A is a schematic front top perspective view of another example of a valve arrangement for a breathing assistance apparatus;

FIG. 19B is a schematic perspective cross-sectional view of the valve arrangement of FIG. 19A;

fig. 20A is a schematic front top perspective view of an example of a connector arrangement;

FIG. 20B is a schematic rear underside view of the connector arrangement of FIG. 20A;

FIG. 20C is a schematic front top side perspective view of an example of an oral appliance incorporating the connector arrangement of FIG. 20A;

FIG. 20D is a schematic rear top side perspective view of the oral appliance of FIG. 20C;

FIG. 20E is a schematic cross-sectional plan view of the oral appliance of FIG. 20C;

fig. 21A is a schematic front underside perspective view of another example of a connector arrangement;

FIG. 21B is a schematic rear underside view of the connector arrangement of FIG. 21A;

fig. 22A is a schematic front top perspective view of another example of a connector arrangement;

FIG. 22B is a schematic rear underside view of the connector arrangement of FIG. 22A;

fig. 22C is a schematic cross-sectional front top perspective view of the connector arrangement of fig. 22A;

FIG. 22D is a schematic sagittal cross-sectional rear underside perspective view of the connector arrangement of FIG. 22A;

fig. 22E is a schematic front top perspective view of the connector arrangement of fig. 22A attached to a front port;

FIG. 23A is a schematic front top side perspective view of an example of an oral appliance;

FIG. 23B is a schematic rear top side perspective view of the oral appliance of FIG. 23A;

Fig. 23C is a schematic front top side perspective view of the oral appliance of fig. 22A attached to the connector arrangement of fig. 22E;

FIG. 23D is a schematic rear top side perspective view of the oral appliance of FIG. 22C;

FIG. 23E is a schematic sagittal cross-sectional front top side perspective view of the oral appliance of FIG. 22C;

fig. 24A is a schematic front top side perspective view of an example of an oral appliance;

FIG. 24B is a schematic rear top side perspective view of the oral appliance of FIG. 23A;

FIG. 25A is a schematic front top side perspective view of the oral appliance of FIG. 24A attached to an alternative example of a connector;

FIG. 25B is a schematic sagittal cross-sectional front top side perspective view of the oral appliance of FIG. 25A;

FIG. 26A is a schematic front top perspective view of an in-line valve arrangement and connector;

FIG. 26B is a schematic sagittal cross-sectional front topside perspective view of the inline valve of FIG. 26A;

fig. 27A is a schematic front top side perspective view of an example of an oral appliance;

FIG. 27B is a schematic rear top side perspective view of the oral appliance of FIG. 27A;

FIG. 27C is a schematic front view of the oral appliance of FIG. 27A;

FIG. 27D is a schematic rear view of the oral appliance of FIG. 27A;

FIG. 27E is a schematic cross-sectional view of the oral appliance along line B-B' of FIG. 27C;

FIG. 27F is a schematic cross-sectional view of the oral appliance along line C-C' of FIG. 27C;

Fig. 28A is a schematic front top side perspective view of an example of an oral appliance;

FIG. 28B is a schematic rear top side perspective view of the oral appliance of FIG. 28A;

FIG. 28C is a schematic cross-sectional rear top side perspective view of the oral appliance of FIG. 28A;

FIG. 28D is a schematic cross-sectional rear top side perspective view of a modified version of the oral appliance of FIG. 28A;

fig. 29A is a schematic front perspective view of another example of a valve arrangement for a breathing assistance apparatus;

FIG. 29B is a schematic front cross-sectional perspective view of the valve arrangement of FIG. 29A;

fig. 30A is a front view of an example of a nasal pillow connector for use in a valve arrangement according to the present disclosure;

FIG. 30B is a schematic cross-sectional view of the nasal pillow connector of FIG. 31A;

FIG. 30C is a schematic top side view of the nasal pillow connector of FIG. 31A;

fig. 31A is a schematic front perspective view of another example of a valve arrangement for a breathing assistance apparatus;

FIG. 31B is a schematic front cut-away perspective view of the valve arrangement of FIG. 31A;

fig. 32A is a schematic front perspective view of another example of a valve arrangement for a breathing assistance apparatus;

FIG. 32B is a schematic front cut-away perspective view of the valve arrangement of FIG. 32A;

FIG. 32C is a schematic front view of the valve arrangement of FIG. 32A;

FIG. 32D is a schematic side view of the valve arrangement of FIG. 32A;

FIG. 32E is a schematic cross-sectional side view of the valve arrangement of FIG. 32A; and the number of the first and second groups,

fig. 33 is a schematic front perspective view of another example of a valve arrangement for a breathing assistance apparatus.

Detailed Description

Examples of breathing assistance apparatus will now be described with reference to fig. 1A-1E and 2A-2F.

Specifically, fig. 1A to 1E show an oral appliance. The oral appliance includes an appliance body 110 that is shaped to be positioned at least partially within the mouth of a user. The appliance body includes an extraoral opening 131 extending between the lips of the user and an appliance air passage 133 through the body 110 to one or more intraoral openings 132 disposed in the oral cavity to allow air flow into and out of the rear region of the oral cavity.

Specifically, in this example, the oral appliance comprises a hollow side base 111 having spaced apart upper and lower surfaces 111.1, 111.2 extending inwardly from a hollow arcuate side wall 112 having upper and lower inner side walls 112.1, 112.2 spaced apart from a curved outer side wall 112.3. In this example, the extraoral opening 131 comprises a tubular body 131.1 projecting forwardly from an arcuate side wall 112.3, the tubular body being in fluid communication with an appliance air passage 133 extending through the hollow base 111 and side wall 112.

In use, the base 111 is positioned between the user's maxillary and mandibular teeth, the arcuate side walls 112 are positioned between the user's teeth and the cheeks, and the tubular bodies 131.1 extend between the user's lips such that the airway is at least partially received in the oral cavity between the teeth and the cheeks. This allows air to pass through the appliance airway such that air is directed to the rear region of the mouth through the second opening 132, thereby at least partially bypassing the nasal passage and serving to replicate a healthy nasal passage and pharyngeal space.

Providing airflow directly to the back of the user's mouth has many benefits. In particular, this avoids obstructions created by the nasal cavity, soft palate and tongue that may lead to snoring and apnea events, and helps reduce the drying effect of the airflow, which in turn may lead to discomfort for the user. Furthermore, providing an airway between the teeth and through the mouth allows for significant cross-sectional dimensions to be accommodated within the mouth without undue discomfort. This makes the device comfortable to wear, while ensuring that the airflow is unobstructed, thereby preventing snoring and apnea events. Thus, for example, a nasal obstruction may be bypassed by airflow through the device, thereby bypassing the nasal airway or increasing the nasal airway in the event of a partial obstruction. In addition, air flowing under or across the soft palate helps to prevent the soft palate from collapsing, which in turn can lead to additional obstruction.

In one example, the body 110 is made of a metal and in particular a titanium alloy and/or a cobalt chromium alloy. However, it should be understood that any suitable material may be used, including high strength polymers, plastics, VeroGlaze (MED620) dental materials, and the like. This may be achieved using additive printing, injection moulding or any other suitable technique. For example, the body 110 may be manufactured using laser sintering of nylon materials, or injection molding of polymers such as thermoset polymers, thermoplastic polymers, silicones, elastomers, polyvinylsiloxanes, polyurethanes, ethylvinylacetate, polycarbonate, acrylonitrile butadiene styrene, or combinations of these materials.

The body 110 may be coated with a medical grade polymer and in one example a medical grade elastomer, such as silicone or polyurethane, epoxy, or parylene, for improved comfort and to ensure biocompatibility. In one example, the coating may include an Active Composite guide (Active Composite guide) that is a three-dimensional Composite resin having different shapes and sizes, and may be bonded to the body to ensure precise positioning of the body relative to the user's teeth. The coating may be applied to the body using any suitable technique, such as dip coating, vapor coating or spray coating the body, thereby ensuring that all exposed surfaces, including the inner surfaces of the channels, are coated. As part of this process, this may include applying a primer to the body prior to coating to ensure that the coating adheres to the body. Alternatively, or in addition to coating, at least a portion of the body may be polished using at least one of mechanical polishing and electrochemical polishing.

In one example, the subject is customized by measuring the user's oral cavity, for example by taking an impression, a series of photographs, or a scan of the user's teeth and/or oral cavity, and then customizing the device based on the measured dimensions, as will be described in more detail below. More typically, however, a range of standard sized bodies may be produced, with the appropriate body being selected based on the closest fit to the intended user. An insert positioned between the user's teeth and the body in use may then be used to achieve a custom fit. Each insert is typically custom made for the user's teeth and is adapted to be removable and/or replaceable.

The insert may also be made by injection moulding a material similar to the body, may be made by additive manufacturing, such as 3D printing, and/or may be made by having the user bite into a material that may be moulded into the shape of the user's teeth and then cured. This may include, for example, UV curing using a thermoset material or the like. In one example, the insert is formed of a bite material, such as ethylene vinyl acetate or the like, although silicone or other materials, such as thermosetting polymers, thermoplastic polymers, silicone, elastomers, polyvinylsiloxane, polyurethane, ethylvinyl acetate, polycarbonate, acrylonitrile butadiene styrene, or combinations of these materials, may also be used. This may be used, for example, to allow a user to mould the insert at home by snapping into a member made of a suitable material, such as silicone.

In one example, the device may be used with a number of different inserts that may be used, for example, to provide different levels of fit, comfort, support, and the like. These inserts may also be temporary or semi-permanent, and may be made of different materials depending on their intended use. For example, a temporary insert may be created using molded-in-place silicone upon initial assembly of the breathing assistance device, which is replaced by a subsequent semi-permanent insert (such as a 3D printed acrylic insert) once it has had an opportunity to be manufactured. This allows initial assembly to be performed when the device is initially supplied with a temporary insert, wherein the semi-permanent acrylic insert is subsequently manufactured and provided to the user once ready.

While the insert may be assembled using any suitable technique, in one example, the insert may be attached to the first and second bodies using an adhesive, a mechanical coupling such as an interference fit, or the like. In this regard, in this example, the upper and lower inner side walls 112.1, 112.2 include openings 112.1, 112.21 for mechanically engaging the inserts (not shown). In particular, the inserts are attached to the upper and lower sidewalls 112.1, 112.2, positioned adjacent to the upper and lower base surfaces 111.1, 111.2, and optionally bonded using an adhesive.

As mentioned above, the use of the insert allows for variations in the shape of the teeth and jaw that can be accommodated by the body, allowing most individuals to fit by selecting one of a plurality of predetermined template bodies having standard sizes/dimensions.

In addition, the inserts may be made thermoformable, allowing for slight reshaping of the inserts by heating to accommodate changes in the jaw position or shape of the user over time. Even such semi-permanent inserts will typically be subject to wear and potential discoloration, and thus may be replaced periodically. Nevertheless, the first and second bodies may be reused as required, so that the insert may be reconstructed from a previously scanned mold. The ability to remove inserts allows these inserts to be replaced and/or cleaned and reused as needed. Similarly, the bodies may also be cleaned and/or disinfected prior to reuse.

In the above example, the body 110 is shown as a single unitary body. However, this is not necessary, and alternatively, the body 110 may be manufactured as separate upper and lower bodies that separately engage the upper and lower jaws. This allows the use of different sized bodies and allows the relative positions of the upper and lower bodies to be adjusted, thereby adjusting the degree of mandibular advancement.

In this regard, mandibular advancement is known to help maintain an open airway in the user, which in turn can reduce snoring. Temporomandibular joint disorder (TMD) occurs, for example, when the upper and lower jaws are not aligned. This may be naturally occurring or may be caused by injury or the like. In any event, this misalignment of the jaw tends to cause obstruction of the airway by changing the shape of the upper airway and moving the tongue towards the back of the mouth, which in turn exacerbates the problems associated with OSA and snoring. Thus, by allowing the relative positions of the first and second bodies to be adjusted, this allows the jaws of the user to be aligned, thereby reducing the effect of TMD and thus further reducing the likelihood of snoring and OSA.

The oral appliance of fig. 1A to 1E may be used in conjunction with a valve arrangement, an exemplary valve arrangement and its operation will now be described with reference to fig. 2A to 2F.

In this example, the valve arrangement 240 comprises a valve body 241, which valve body 241 comprises a valve air duct 242. The valve body 241 is coupled to the extraoral opening 131 of the oral appliance body 110, as shown in fig. 2C-2F, such that the valve airway 242 is in fluid communication with the appliance airway 133.

Valve member 243 is positioned in valve air passage 242 and is movable between a first position and a second position due, at least in part, to air flow through valve air passage 242. In the second position shown in fig. 2C-2F, the valve member 243 at least partially obstructs the valve air passage 242, while when the valve member 243 is in the first position, the obstruction is removed or at least reduced (shown in dashed lines in fig. 2E). As a result, there is differential resistance during inspiration and expiration.

Thus, the above-described device provides a valve arrangement that can be coupled to an oral appliance, such as the oral appliance of fig. 1A-1E, to accommodate the oral appliance such that the oral appliance can introduce differential resistance during inhalation and exhalation.

In one example, the valve arrangement is configured to minimize airway resistance during inhalation, thereby maximizing airflow into the user's lungs, while introducing greater resistance during exhalation, which in turn may help maintain pressure within the user's airway. This may help regulate breathing and in particular allow for rapid inspiration while ensuring slower expiration, thereby maintaining a minimum pressure within the system to prevent airway collapse and optimize gas exchange within the lungs, for example to minimize the chance of hyperventilation. The ability to maintain internal airway pressure may help maintain an open airway, which in turn may avoid the need to apply external PAP.

This therefore allows the system to be used not only for snoring, but also for treating sleep apnea in all severe patients who would otherwise require treatment with positive airway pressure and/or receiving supplemental air and/or oxygen.

It will also be appreciated that other configurations may be provided, such as to increase resistance during inhalation, which may be used as a means of providing breathing exercise for the user.

In the above examples, the valve body is separate from and designed to be coupled to the oral appliance, allowing the oral appliance to be used without a valve, or allowing different valve arrangements to be interchanged. However, this is not essential and alternatively the valve arrangement may be formed integrally with the oral appliance. In this case, the valve body will be formed by a portion of the oral appliance body. Thus, it will be understood that reference to the appliance body and valve body is not intended to exclude devices in which the valve arrangement is integral with the appliance.

A number of further features will now be described.

In the above examples, the oral appliance includes an appliance airway to allow airflow into and/or out of the user's mouth. However, this is not required, and additionally and/or alternatively, the oral appliance may include a nasal airway to allow airflow into and/or out of the nasal cavity of the user, examples of which are described in more detail below. Thus, it will be appreciated that the provision of an airway of the appliance is not essential and fluid communication between the valve and the airway of the user may be achieved via other mechanisms, such as via an airway external to and/or separate from the oral appliance. Thus, references to the appliance airway in the above examples should not be considered as necessarily limiting.

As described above, in one example, the valve arrangement creates positive airway pressure in the airway of the user by restricting gas flow during exhalation through the oral cavity and/or restricting gas flow during exhalation through the nasal cavity. Positive airway pressure in the user's airway can also be achieved by connecting the device airway to a device connector coupled to the valve body. In this case, the device connector provides a device airway that supplies a flow of gas from a positive airway pressure device that is in fluid communication with the valve airway or nasal airway, thereby allowing a positive pressure to be supplied to the user.

Thus, it will be appreciated that the device may be configured to generate positive airway pressure using a variety of techniques, where the technique used is generally dependent on the breathing characteristics of the user, and in particular the severity of dyspnea. For example, if the user does not experience significant breathing difficulties, the oral appliance may be used with the airway only to facilitate airflow during inhalation and exhalation. However, if the airway collapse is at risk to the user, the above mechanisms may be used to maintain progressively higher positive airway pressure until the collapse of the airway is alleviated and/or prevented.

Thus, a potential user will typically be evaluated and then tested using only the oral appliance. If this does not solve the problem, a mechanism will be used to maintain progressively higher positive airway pressure until satisfactory results are obtained. This typically involves initially restricting the airflow only through the mouth during exhalation. If this fails, airflow through the nasal cavity during exhalation is restricted, and these mechanisms are used in combination if they are individually unsuccessful. If the problem remains unresolved, positive airway pressure will be provided from the positive airway pressure device, which will be further performed in conjunction with restricting airflow during exhalation through the mouth in cases where providing positive pressure alone does not solve the problem. Thus, different mechanisms may be continuously tested until a desired positive airway pressure is maintained.

As will be apparent from the following description, each mechanism may be implemented using an oral appliance used in conjunction with a valve arrangement. This may avoid the need for the user to use the mask required by a conventional PAP machine, which is often uncomfortable and in some cases of limited effectiveness. In addition, the use of mask-based PAP systems may result in a need for increased airflow due to possible mask leaks, which in turn requires a more powerful pump, which tends to be noisy, and which in turn results in disturbed sleep. Conversely, delivering positive pressure via the following device allows air to be more efficiently directed into the airway of a user via the nasal airway or appliance airway, thereby reducing the airflow requirements needed to achieve a desired result while avoiding discomfort associated with the mask.

The device may comprise an oral valve arrangement for controlling breathing via the oral cavity and/or a nasal valve arrangement for controlling breathing via the nasal cavity. Thus, either or both of oral and nasal valve arrangements may be used, depending on the severity of the user's condition.

In one example, the device may also be controlled by a control valve configuration. In particular, this may be used to control the differential resistance during inspiration and expiration, which in turn affects the degree of positive airway pressure in the user's airway and/or the degree of airflow during expiration. Thus, in addition to controlling the mechanisms for delivering positive airway pressure, the range of pressures delivered may be controlled by adjusting the valve configuration of each mechanism, and this may again be performed according to the breathing characteristics selected by the user.

In this regard, the valve configuration may include a size or number of valve air passage openings, a size or number of valve member openings, a valve member characteristic, or a biasing member characteristic.

For example, the valve member may include one or more valve member openings to allow airflow through the valve member when the valve member is in the second (closed) position, thereby allowing exhalation to occur when the valve member is closed. In this example, the size and number of openings will control the level of resistance during exhalation, and thus the positive airway pressure generated in the user's airway. Similarly, the valve body may include one or more openings to allow airflow through the valve body at least when the valve member is in the second (closed) position, the number and size of the openings again controlling the positive airway pressure. The valve member may be configured to only partially close the opening in the airway, in which case the degree to which the opening remains open will affect the positive airway pressure.

Finally, the movement of the valve member may be controlled to adjust the relative ease and speed of valve opening or closing, which in turn may help control the build up of positive airway pressure, particularly the rate at which it starts and stops. Factors affecting valve opening or closing may include any one or more of valve member characteristics, such as valve member thickness, valve member material characteristics, valve member stiffness, valve member spring or elasticity, valve member surface area, and the like. Additionally and/or alternatively, this may depend on the characteristics of the biasing member, for example if the biasing member is used to urge the valve into the second position.

A number of more specific features will now be described.

Movement of the valve member 243 between the first and second positions may be accomplished in a variety of ways according to preferred embodiments. In the example of fig. 2A-2F, the valve member 243 is at least partially flexible, allowing movement of the valve member 243 through deformation of the valve member. In one preferred example, the valve member 243 is a silicone flap (flap) that may be deformed at least partially by the flow of air through the air passage 242. However, this is not essential and additionally and/or alternatively movement may be achieved by pivoting or hinged movement of the valve member, for example if the valve member 243 is a rigid body.

Valve member 243 is normally biased to a first position by airflow through valve air passage 242 and then to a second position by airflow through valve air passage 242 in the opposite direction and/or by the resiliency of valve member 243. Thus, in the present example, the valve member 243 is biased to the first position by elastic deformation of the valve member 243 during inhalation, wherein the valve member elastically returns to the second position when the user is not inhaling.

Further, the valve member 243 normally engages the valve body 241 to retain the valve member in the second position to prevent further movement of the valve member during exhalation, e.g., to prevent the valve from blowing outwardly.

The valve body 241 may be coupled to the extraoral opening in various ways. This is typically accomplished in a reversible manner to allow valve body 241 to be attached to the extraoral opening and then subsequently removed from the extraoral opening, and may involve the use of a friction fit, an interference fit, a clip fit, or by magnetic engagement. Such an arrangement allows the valve arrangement to be coupled to or decoupled from the oral appliance, thereby allowing the valve arrangement to be interchanged, for example allowing different levels of resistance to be introduced as required by the user. In this regard, it should be understood that if the valve member 243 is configured appropriately, the obstruction of the airway may be completely obstructed, thereby forcing the user to exhale completely through their nose. More typically, however, the valve member 243 is sized to provide a partial obstruction that allows exhalation to occur through the valve arrangement, while maintaining positive airway pressure within the patient's airway to maintain airway inflation.

In the example shown in fig. 2A and 2B, the valve body 241 comprises a ring 241.1 adapted to be arranged outside and adjacent to the extraoral opening, in particular at the end of the tubular body 131.1. The valve airway includes one or more openings 242 through the ring 241.1, in this example two outer openings 242.1 and two inner openings 242.2 are shown, depicted by vertical struts 241.2 extending between the upper and lower halves of the ring 241.1.

Valve body 241 typically includes a guide to position the valve body relative to the extraoral opening. Specifically, in this example, the guide 241.3 is an arcuate segment extending rearwardly from the ring 241.1 and is for engaging an inner surface of the tubular body 131.1, thereby positioning the valve body 240 relative to the extraoral opening.

The valve body 241.1 also includes a plurality of tabs 241.4, in this example, extending rearwardly from the ring 241.1, the tabs 241.4 including a lip 241.41 that engages a groove 131.2 within the extraoral opening to couple the valve body to the extraoral opening using a clip fit (clipfit) configuration. In this example, the groove extends circumferentially around the inner surface of the tubular body 131.1, but it will be appreciated that alternative configurations may be used, for example having the groove around only a portion of the tubular body 131.1, or having the groove on the outer surface of the tubular body 131.1.

In the present example, the valve member 243 is in the form of a silicone flap, coupled to the ring 241.1, and in particular coupled to an upper portion of the ring 241.1. The coupling may be achieved by bonding, welding, etc., or may involve the use of mechanical engagement, such as clamping or attachment using fasteners. This may be performed in a reversible manner, allowing the valve member 243 to be removed and replaced as needed. In any event, in this example, a portion of the valve member 243 is positioned between the ring 241.1 and the tubular body 131.1 to help further secure the valve member 243 in place while allowing the valve member 243 to deform by deflecting upwardly during inhalation. This allows airflow through each of the inner opening 242.1 and the outer opening 242.2 during inhalation. Conversely, during exhalation, the valve member 243 returns to the position shown in fig. 2A, wherein the valve member 243 abuts the vertical strut 241.2, thereby blocking the inner opening 242.2 and restricting airflow to the outer opening 242.1 during exhalation.

In the above example, the valve member comprises a single valve member formed as a naturally flat body which is arranged to abut the strut 241.2 such that the valve member 243 is forced into engagement with the strut 241.2 during exhalation to retain the valve member in the second position during exhalation. However, it should be appreciated that other configurations may be used.

Examples of alternative configurations are shown in fig. 3A to 3D. The arrangement is substantially similar to the apparatus described above with respect to fig. 2A to 2D, with like reference numerals increased by 100 referring to like features and will therefore not be described in further detail.

In contrast to the previous example, this valve arrangement includes two valve members 343.1, 343.2 arranged in a substantially V-shaped configuration, supported by the triangular rear edge of the post 341.2. The valve members 343.1, 343.2 are positioned to abut at an apex such that when a user inhales, the valve members 343.1, 343.2 articulate apart to allow airflow therethrough. When inspiration ceases, the valve members 343.1, 343.2 return to the V-shaped configuration, blocking the inner opening 342.2, such that expiration occurs only through the outer opening 342.1.

Fig. 4A to 4D show another exemplary arrangement.

In this example, the valve body 440 comprises a ring 441.1 and a hollow valve tube 441.3 extending from the ring back to serve as a guide for positioning the valve body. In this example, the hollow valve tube 441.3 has a generally oval cross-section shaped to fit within the tubular body 131.1 of the extra-oral opening body, but it will be appreciated that other shapes may be used for different shaped extra-oral openings. The hollow valve tube 441.3 includes a tab 441.4 having a lip 441.41 that again engages a groove 131.2 provided within the tubular body 131.1 to assist in coupling the valve body to the extraoral opening.

In this example, the valve arrangement comprises a valve member having two halves 443.1, 443.2 mounted to a central vertical strut 441.2 extending across the centre of the rear of the hollow tube 441.3, the valve member halves 443.1, 443.2 abutting the outer vertical strut 441.21 and the rear surface of the hollow tube 441.3 in a rest (second) position. This arrangement allows the valve member halves 443.1, 443.2 to deform back at the outer edge during inhalation to allow airflow through the tube to return to the second position during exhalation. It will be appreciated that in this example the entire airway is substantially obstructed by the valve member halves 443.1, 443.2 which together have a shape corresponding to the cross-sectional area of the hollow tube 441.3. However, this is not essential and a shortened version of the half valve member 443.1, 443.2 may be used to allow partial obstruction during exhalation.

In the above example, the valve arrangement is mounted at least partially within the tubular body 131.1 of the extraoral opening. However, this is not essential and in an alternative arrangement the valve arrangement may be provided externally of the tubular body 131.1.

Another exemplary valve arrangement will now be described with reference to fig. 5A to 5D.

In this example, the valve arrangement 540 comprises a hollow valve tube 541.1 shaped to fit over the tubular body 1131.1 of the extraoral opening 131. The hollow valve tube 541.1 includes a plurality of struts 541.2 extending vertically across the mouth of the hollow valve tube 541.1, which, as in the previous example, may be used to define inner and outer openings in the mouth. The valve member 543 includes tabs 543.1 that fit in openings 541.13 in the hollow valve tube 541.1 such that the valve member 543 abuts a diagonally rearward edge of the post 541.2.

In use, inhalation bends the valve member 543 upwardly allowing inhalation, while during exhalation the flap returns to the position shown in figure 5C blocking the airway.

Further variants are shown in fig. 6A to 6D. This arrangement is substantially similar to the apparatus described above with respect to fig. 5A to 5D, with similar reference numerals increased by 100 denoting similar features and will therefore not be described in further detail.

In contrast to the previous example, this valve arrangement includes two valve members 643.1, 643.2 arranged in a substantially V-shaped configuration, supported by the triangular rear edge of the post 641.2. The valve members 643.1, 643.2 are positioned to abut at an apex such that when a user inhales, the valve members 643.1, 643.2 articulate apart to allow airflow therethrough. When inspiration ceases, the valve members 643.1, 643.2 return to the V-shaped configuration, blocking the inner opening 642.2 so that expiration occurs only through the outer opening 642.1.

An alternative example of an oral appliance will now be described with reference to fig. 7A and 7B.

In this example, the oral appliance includes an upper body 710 and a lower body 720. The upper body 710 includes a hollow side base 711 having spaced apart upper and lower surfaces 711.1, 711.2 extending inwardly from a hollow arcuate sidewall 712 having an upper inner sidewall 712.1 spaced apart from a curved outer sidewall 712.3. These walls define an airway (not shown) that terminates in an intraoral opening 732 and connects to an extraoral opening 731 formed by a tubular body 731.1 that projects forwardly from curved outer side wall 712.3. The second body comprises a lateral top 721 extending between an inner downwardly protruding side wall 722.1 and an outer downwardly protruding side wall 722.2.

These upper and lower bodies 710, 720 are used with corresponding bite members that receive the maxillary and mandibular teeth, respectively. The snap members are typically attached to the bodies 710, 720 by mechanical or chemical bonding, for example, by using plugs that fit within sockets 712.11, 721.21 in the side walls 712.1, 721.2.

In use, the bodies 710, 720 are coupled together such that the bodies cooperate in a manner similar to the body 110 of fig. 1A-1E. However, in this example, the relative positions of the first body 710 and the second body 720 may be adjusted to control the degree of mandibular advancement. Although this may be achieved in any manner, in one example, the bodies 710, 720 include first and second mounts in the form of lugs 714, 724, respectively, that project outwardly from the sides of the first and second bodies 710, 720, the lugs being interconnected via respective arms 704. The relative positions of the first body 710 and the second body 720 can then be adjusted based on the length of the arm 704, where the arm 704 is extendable or interchangeable, allowing different lengths of arm to be provided to achieve a desired degree of mandibular advancement.

In the present example, the arms 704 are made of molded plastic or nylon, which include fittings at each end that engage the lugs, typically using an interference fit (such as a locking engagement) or using a resilient ring that stretches over the lugs.

A number of additional exemplary valve arrangements will now be described. For illustrative purposes, these are shown with reference to the oral appliance of fig. 7A and 7B, but it should be understood that the oral appliance of fig. 1 and 7 can be used interchangeably and this is not intended to be limiting.

Another example of a valve arrangement will now be described with reference to figures 8A to 8D. The valve arrangement is configured to further provide a nasal airway via the nasal pillows, although it will be appreciated that certain features are also applicable to the previous examples.

In this example, the valve arrangement comprises a hollow tubular valve body 841.1 shaped to fit over the tubular body 731.1 of the extraoral opening 731. The valve body 841.1 is also coupled to a nasal pillow 844.2 that defines a nasal airway to allow airflow into and out of the user's nasal cavity.

In this example, the nasal pillows 844.2 are attached to a nasal pillow connector body 844.1, which in turn may be attached to a valve body 841.1 via pillow mounts 841.4 that protrude upward from the valve body 841.1. The pillow mount 841.4 and nasal pillow connector body 844.1 are shaped to form a cylindrical cup and socket connection, allowing the nasal pillow connector body 844.1 to rotate about pivot pin 844.3. This allows the angle of the nasal pillow 844.2 relative to the valve body 841.1 to be adjusted so that, in use, when the valve body 841.1 is mounted to the oral appliance in use, the nasal pillow 844.2 is aligned with the user's nose.

At least one valve air passage opening 842.1, 842.2 is provided on the underside of the valve body 841.1. In this example, the openings include a nasal opening 842.1 in fluid communication with the nasal airway allowing airflow through the nasal cavity of the user and a valve airway opening 842.2 in communication with the valve airway allowing airflow through the oral cavity of the user. The nasal airway and the valve airway are physically separated, allowing independent gas flows through the nasal airway and the valve airway, although it will be appreciated that this is not required, and alternatively the airways may be in fluid communication to allow gas flow therebetween.

The respective valve members 843.1, 843.2 at least partially obstruct the nasal opening 842.1 and valve airway opening 842.2, providing differential resistance during inhalation and exhalation as previously described.

In this example, a strut 842.2 extends across the openings to effectively provide a plurality of nasal openings 842.1 and valve airway openings 842.2. In one example, the valve members 843.1, 843.2 may engage the post 841.2 in the second position to retain the valve members in the second position during exhalation. Additionally, and/or alternatively, a shoulder 843.3 may be provided that extends at least partially around the at least one valve air passage opening, wherein the valve member engages the shoulder 843.3 in the second position to retain the valve member in the second position. In this example, the shoulder 843.3 is provided by a frame 843 that supports the valve members 843.1, 843.2, although this is not required, and the shoulder 843.3 may instead form part of the valve body 841.1.

In use, inhalation bends valve members 843.1, 843.2 upward allowing unrestricted gas flow through openings 842.1, 842.2, while during exhalation valve members 843.1, 843.2 rest on shoulder 843.3, thereby blocking the airway. The degree of obstruction may be controlled by covering only some of the plurality of nasal openings 842.1 and/or valve airway openings 842.2. Alternatively, in this example, the valve members 843.1, 843.2 include one or more openings 843.11, 843.21 therein to allow airflow through the valve members 843.1, 843.2 when they are in the second position. Thus, in this configuration, this allows exhalation to occur via the openings 843.11, 843.21, thereby introducing resistance during exhalation, which in turn creates pressure in the oral and nasal cavities, which can help maintain the airway of the user open.

It will be appreciated that with this configuration, the size and number of openings 843.11, 843.21 in the valve members 843.1, 843.2 may be used to control the pressure during exhalation. Thus, by using different numbers and/or sizes of openings 843.11, 843.21, this can be used to relatively regulate the pressure in the nasal and oral cavities during exhalation. Similarly, the size, material characteristics, and/or thickness of each valve member 843.1, 843.2 may be different to adjust the desired opening force. For example, a thinner valve member, a valve member with reduced elasticity, stiffness, or resiliency, or a valve member with a larger surface area typically requires lower pressure to open. Thus, proper configuration of the valve members 843.1, 843.2 and openings 843.11, 843.21 allows for control of the relative degree of inflow and outflow resistance of the breath via the user's nasal and oral airways.

In one particular example, a frame 843 on which the valve members 843.1, 843.2 are mounted is removably mounted within the valve body 841.1, allowing the valve members 843.1, 843.2 to be easily interchanged. This allows multiple different valve members 843.1, 843.2 to be tested using the same device, allowing the best relative degree of resistance to flow in and out through the nasal and oral cavities.

An alternative example will now be described with reference to fig. 9A and 9B. For purposes of illustration, similar features to those shown in fig. 8A-8D are used to denote similar features, which, although incremented by 100, will not be described in further detail.

Thus, in this example, the valve arrangement comprises a hollow tubular valve body 941.1 shaped to fit over the tubular body 731.1 of the extraoral opening 731. The valve body 941.1 also includes a mount 941.1 connected to a nasal pillow connector body 944.1 on which the nasal pillow 944.2 is mounted. In this example, the nasal pillows 944.2 include two sets of bellows (bellow)944.21 to allow for greater compression, particularly to allow for variations in length up to 20mm to allow for greater comfort and fit to accommodate different sized noses.

It should be understood that this example also includes other similar features, including a nose opening and a valve opening, and a valve member 943.1, 943.2 including openings 943.11, 943.21, mounted on the frame 943 and movable between a first open position and a second closed position. Thus, the operation is substantially similar to that of the previous example and will not be described in further detail.

An alternative example will now be described with reference to fig. 10A to 10C. For purposes of illustration, similar features to those shown in fig. 8A-8D are used to denote similar features, although their values are increased by 200, which will not be described in further detail.

In this example, the valve arrangement comprises a hollow tubular valve body 1041.1 shaped to fit over the tubular body 731.1 of the extraoral opening 731. The valve body 1041.1 also includes a valve opening 1042 in the underside of the valve body 1041.1. The valve opening 1042 may be used in conjunction with a valve member (not shown) for providing differential resistance during inhalation or exhalation, although this is not required.

In this example, the valve body 1041.1 includes an integral nasal pillow connector body 1044.1 upon which the nasal pillows 1044.2 are mounted, which in turn includes two sets of bellows to allow for greater comfort and fit. The arrangement also includes a device connector 1045.1 coupled to a tube 1045.2 that defines a device airway that supplies a flow of gas from the positive airway pressure device. In this example, the device airway is in fluid communication with the nasal airway, allowing positive airway pressure to be provided to the nasal cavity of the user. A plurality of device connector airway openings 1045.11 are provided in the device connector 1045.1 to control the air pressure in the device connector airway. Also, an opening may be used in conjunction with a valve member to help control air pressure during inhalation and exhalation.

An alternative example will now be described with reference to fig. 11A to 11C. For purposes of illustration, similar features to those shown in fig. 8A-8D are used to represent similar features, although their values are increased by 300, which will not be described in further detail.

In this example, the valve arrangement comprises a hollow tubular valve body 1141.1, the hollow tubular valve body 1141.1 being shaped to fit over the tubular body 731.1 of the extraoral opening 731. The valve body 1141.1 also includes a valve opening 1142 in the underside of the valve body 1141.1. A valve member 1143.1 is provided mounted on the frame 1143 and is movable between a first open position and a second closed position to at least partially close the openings 1142. Valve member 1143 also includes an opening 1143.11 to allow airflow during exhalation and thereby provide differential resistance during inhalation and exhalation through the oral cavity.

In this example, the apparatus includes a nasal pillow 1144.2 attached to a nasal pillow connector body 1144.1, which in turn may be attached to a valve body 1141.1 via a pillow mount 1141.4 projecting upward from the valve body 1141.1. In this example, the pillow mount 1141.4 and the nasal pillow connector body 1144.1 are shaped to form a cylindrical cup and socket connection, allowing the nasal pillow connector body 1144.1 to rotate so that the angle of the nasal pillow 1144.2 can be adjusted. Additionally and/or alternatively, the pillow may be mounted via a ball joint to be additionally adjustable.

The arrangement also includes a device connector 1145.1 coupled to a tube 1145.2 that defines a device airway that supplies a flow of gas from the positive airway pressure device. In this example, the device airway is in fluid communication with the nasal airway, allowing positive airway pressure to be supplied to the nasal cavity. A plurality of device connector airway openings 1145.11 are provided to control the air pressure in the device connector airway. Also, an opening may be used in conjunction with a valve member to help control air pressure during inhalation and exhalation.

An example of an alternative valve arrangement will now be described with reference to fig. 12A and 12B. It will be appreciated that this may be incorporated into any of the valve bodies in the above examples and may be used in place of the flap-type valve member.

In this example, the valve 1250 includes a disk-shaped base 1251 spaced from a valve seat ring 1253 by longitudinally extending spaced parallel arms 1252. Base 1251 includes a central tube 1251.1 that slidably supports shaft 1256, which in turn is mounted in a socket 1255.1 in valve member 1255, allowing valve member 1255 to slide longitudinally toward and away from valve seat ring 1253. The base 1251 and valve member 1255 include upstanding rings 1251.2, 1255.2 on facing sides that seat a spring 1254 extending from the base 1251 to the valve member 1255, thereby urging the valve member 1255 against a valve seat 1253 to close the valve. In this case, the valve seat ring 1253 may be integrated into the sidewall of the valve body, allowing the valve to open during inspiration and close when inspiration ceases, thereby providing differential resistance during inspiration and expiration as previously described.

A further exemplary arrangement will now be described with reference to fig. 13A and 13B. For purposes of illustration, similar features to those shown in fig. 8A-8D are used to denote similar features, although their values are increased by 500, which will not be described in further detail.

In this example, the valve arrangement comprises a hollow tubular valve body 1341.1 shaped to fit within the extraoral cavity of the first body 1310. The valve body 1341.1 is similar to the valve body shown in fig. 4A-4D, and further includes a valve member 1343.1 at the rear of the valve body 1341.1. Since this arrangement has been described previously, it will not be described in further detail.

In this example, the device includes a nasal pillow 1344.2 attached to a nasal pillow connector body 1344.1 that is a tubular body that fits over the extraoral opening. The nasal pillows are fitted on the ends of device connector tubes 1345.2 that are coupled to nasal pillow connector body 1344.1 via clips 1344.4 extending laterally from nasal pillow connector body 1344.1.

A further exemplary arrangement will now be described with reference to fig. 14A and 14B. For purposes of illustration, similar features to those shown in fig. 13A and 13B are used to denote similar features, which, although incremented by 100, will not be described in further detail.

In this example, the valve arrangement 1440 includes a hollow tubular valve body 1441.1 shaped to fit over or within an extraoral opening of a first valve body (not shown). The valve body 1441.1 is similar to the valve body shown in fig. 4A-4D, and includes a valve member at the rear of the valve body. Since this arrangement has been described previously, it will not be described in further detail.

In this example, the apparatus includes nasal pillows 1444.2 that are each attached to a corresponding connector tube 1444.1 mounted on the valve body 1441.1. These nasal pillows 1444.2 and connector tube 1444.1 are coupled via a hollow ball socket arrangement to allow air to flow therethrough. The ball socket arrangement includes a socket 1444.41 at a first upper end of the connector tubes 1444.1, and a ball 1444.21 at a first lower end of the nasal pillow 1444.2. A second upper end of the nasal pillow 1444.2 terminates in an opening 1444.22 that is inserted into the nasal passage of the user, while a second lower end of the connector tube 1444.1 terminates in a plug 1444.12 that is insertable into the upper end of the device connector tube 1445.2 to allow connection to a positive airway pressure device.

Thus, the above arrangement allows each nasal pillow to be coupled to a respective connector tube via a hollow ball socket arrangement, so that the relative orientation of each nasal pillow can be independently adjusted to optimize the fit for different users. In this example, the ball of the ball socket arrangement is provided on the nasal pillow, but it will be appreciated that this is not essential and alternatively the position of the ball socket may be reversed.

A further exemplary arrangement will now be described with reference to fig. 15A and 15B. For purposes of illustration, similar features to those shown in fig. 11A through 11C are used to represent similar features, although their values are increased by 400, which will not be described in further detail.

In this example, the valve arrangement 1540 includes a hollow tubular valve body 1541.1 shaped to fit over or within the extraoral opening of the first body 1510 attached to the second body 1520 via a connector 1504. The valve body 1541.1 is similar to the valve body shown in fig. 11A-11C, and further includes a valve member therein. Since this arrangement has been described previously, it will not be described in further detail.

In this example, the apparatus includes nasal pillows 1544.2, each of which is attached to a connector body 1544.1 mounted on a valve body 1541.1. The nasal pillows 1544.2 and the connector body 1544.1 are coupled via a hollow ball socket arrangement to allow airflow therethrough. The ball socket arrangement includes two balls 1544.11 mounted on the upper end of the connector body 1544.1 and a socket 1544.21 at the lower end of the nasal pillow 1544.2. The second upper end of the nasal pillow 1544.2 terminates in an opening 1544.22 that is inserted into the nasal passage of the user, while the second lower end of the connector body 1544.1 terminates in a socket that receives a device connector 1545.1 coupled to a tube 1545.2 that defines the appliance airway that supplies airflow from the positive airway pressure device.

Again, such a device allows each nasal pillow to be coupled to a respective connector tube via a ball socket arrangement so that the relative orientation of each nasal pillow can be independently adjusted to optimize the fit for different users. Also, the position of the ball insertion opening may be reversed.

Another exemplary arrangement will now be described with reference to fig. 16A to 16C.

In this example, the valve arrangement 1640 includes a hollow tubular valve body 1641.1 shaped to fit over or within an extraoral opening of a first valve body (not shown). The valve body 1641.1 includes a valve body opening containing a valve 1650 to allow airflow into and out of the valve body to be controlled by the valve during inhalation and exhalation. In this example, the valve body 1641.1 also acts as a nasal pillow connector and supports the nasal pillow 1644.2.

This valve is shown in more detail in fig. 16B, and is generally similar to the valve of fig. 12A and 12B, in that it includes a spring arrangement. In this case, the valve 1650 includes a cylindrical base 1651 having an inwardly extending shoulder 1651.1 that serves as a seat for a first end of the spring 1654. The cylindrical base includes cross-struts 1652 that define openings to allow airflow into the valve. A second end of spring 1654 is connected to valve ring 1655.1 located within the spring and an outwardly extending beveled edge 1655.2 is provided such that the spring engages the underside of edge 1655.2. The valve ring 1655.1 supports a hub 1655.3 that is mounted on arms that extend radially inward from the valve ring 1655.1, on which hub is mounted a flexible valve member 1655.4. In use, the valve member 1655.4 selectively engages the upper end of the valve ring 1655.1, thereby selectively closing the opening defined by the valve ring 1655.1 according to the flow of gas therethrough.

In use, the valve 1650 is mounted in a valve body opening of the valve body 1641.1. This may be achieved using any suitable technique, such as frictional engagement or the like. In one example, cylindrical base portion 1651 has a threaded outer surface that engages a corresponding threaded inner surface 1641.5 of the valve body opening.

The interior surface of the valve body opening includes a narrow section 1641.6 that terminates in an angularly inwardly extending shoulder that defines a valve seat 1641.7. In use, the spring 1654 forces the angled edge 1655.2 of the valve ring 1655.1 into engagement with the valve seat 1655.1. During inhalation, the airflow pushes the valve member 1655.4 away from the valve ring 1655.1, allowing air to flow in through the opening 1652 and into the appliance air passage through the valve body. During exhalation, the valve member 1655.4 engages and seals against the valve ring 1655.2. Air pressure in valve body 1641.1 pushes valve ring 1655.1 downward, compressing spring 1654 and unseating shoulder 1655.2 from seat 1641.7 to allow outward air flow between shoulder 1655.2 and seat 1641.7 through opening 1652.

It should be appreciated that in this arrangement, the valve 1650 provides differential resistance during inspiration and expiration using a combination of different mechanisms integrated into a single common valve. In particular, this uses a flap-type valve member 1655.4 to allow inhalation, with exhalation controlled by use of a spring valve defined by the interaction between the valve ring 1655.1 and the valve seat 1641.7.

Furthermore, the valve 1650 may be easily removable from the valve body 1641.1, allowing it to be easily replaced so that different combinations of valve member characteristics and spring characteristics may be used to adjust the resistance during inhalation and exhalation, thereby matching the resistance to the particular requirements of the subject.

It will therefore be appreciated that this arrangement provides a valve which is removably mounted on a valve body to allow the valve members to be interchanged, and similar functions may be achieved with other valves, such as those described above with reference to figures 8A to 8D.

In this example, the valve arrangement comprises a first valve controlling the resistance during inhalation and a second valve mechanism providing the resistance during exhalation. In particular, in this case, the valve member is mounted on a valve ring, and wherein the valve ring is biased into engagement with a valve seat within the valve body, such that movement of the valve member controls resistance during inhalation, and biasing of the valve ring against the valve seat controls resistance during exhalation.

In a preferred arrangement, the valve comprises a base attached in use to the valve body, a spring and a valve ring, the valve ring supporting a valve member which is moveable such that the valve ring opens during inhalation and closes during exhalation, and wherein the valve ring is biased into engagement with a valve seat such that the valve opens during exhalation and closes during inhalation.

It will therefore be appreciated that the valve arrangement comprises a single removable valve which uses different valve mechanisms which operate during inhalation and exhalation respectively, thereby providing differential resistance during inhalation and exhalation. In particular, in an example, a movable valve member, such as a flap or the like, may be used to provide an airway during inhalation, while this closes during exhalation to allow the spring valve to open and provide resistance during exhalation.

A further exemplary arrangement will now be described with reference to fig. 17A and 17B. For purposes of illustration, like reference numerals increased by 100 are used to denote like features from the previous examples, and these features will not be described in detail.

In this example, the valve arrangement 1740 includes a hollow tubular valve body 1741.1 shaped to fit over or within an extraoral opening of a first body (not shown). The valve body 1741.1 includes two valve body openings containing respective valves 1750.1, 1750.2, which have a similar form to the valve 1650 described above. In this example, the valve body 1741.1 also acts as a nasal pillow connector and supports the nasal pillow 1744.2.

In this example, the body 1741.1 is divided internally to define an oral airway 1742.1 and a nasal airway 1742.2 in fluid communication with the oral appliance airway and the nasal pillows, respectively. Each airway includes a respective valve arrangement 1750.1, 1750.2 to allow airflow to independently control the inlet and outlet chamber airways 1742.1 and the nasal airway 1742.2 through the respective valves 1750.1, 1750.2 during inhalation and exhalation. For example, inhalation may have a lower resistance through the nasal airway to facilitate inhalation through the nose, while exhalation may have a lower resistance through the oral airway to maintain positive pressure in the nasal airway.

Another exemplary arrangement will now be described with reference to fig. 18A to 18D.

In this example, the valve arrangement 1840 includes a hollow tubular valve body 1841.1 shaped to fit over or within an extraoral opening of a first valve body (not shown). The valve body 1841.1 includes a valve body opening containing a valve 1850 to allow for airflow into and out of the valve body by the valve control during inhalation and exhalation. In this example, the valve body 1841.1 also acts as a nasal pillow connector and supports the nasal pillow 1844.2.

This valve is shown in more detail in fig. 18B, and is generally similar to the valve of fig. 16B. In this case, the valve 1850 comprises a cylindrical valve base 1851 having a plurality of radially extending transverse struts 1852 defining a plurality of openings to allow airflow into and out of the valve. These struts include a circumferential recess 1852.1 that acts as a seat for a first end of the spring 1854.

The second end of the spring 1854 is coupled to a valve ring 1855.1 having a shoulder 1855.2 that extends outwardly to define a 90 ° angle of rotation that engages a beveled valve seat 1841.7 within the valve body 1841.1. The valve ring 1855.1 supports a hub 1855.3 that is mounted on arms that extend radially inward from the valve ring 1855.1. The hub 1855.3 includes a cylindrical opening that slidably engages, in use, a shaft 1841.8 extending downwardly within the valve body 1841.1, thereby guiding movement of the valve ring 1855.1 within the valve body 1841.1.

The flexible valve member 1855.4 is mounted on the valve hub 1855.3. In use, the valve member 1855.4 selectively engages the upper end of the valve ring 1855.1, thereby selectively closing the opening defined by the valve ring 1855.1 according to the flow of gas therethrough.

In use, the valve 1850 is installed in the valve body opening of the valve body 1841.1. While this may be accomplished using any suitable technique, such as frictional engagement or the like, in the preferred example, the cylindrical valve base 1851 has a threaded outer surface that engages a correspondingly threaded inner surface 1841.5 of the valve body opening.

The interior surface of the valve body opening includes a narrow section 1841.6 that terminates in an angled shoulder defining a valve seat 1841.7. In use, the spring 1854 urges the shoulder 1855.2 of the valve ring 1855.1 into engagement with the valve seat 1841.7. During inhalation, the airflow pushes the valve member 1855.4 away from the valve ring 1855.1, allowing air to flow in through the opening 1852 and into the appliance air passage through the valve body. During exhalation, the valve member 1855.4 engages and seals against the valve ring 1855.2. Air pressure in the valve body 1841.1 pushes the valve ring 1855.1 downward, compressing the spring 1854 and disengaging the shoulder 1855.2 from the seat 1841.7 to allow outward airflow between the shoulder 1855.2 and the seat 1841.7 through the opening 1852.

It should be appreciated that in this arrangement, the valve 1850 provides differential resistance during inspiration and expiration using a combination of different mechanisms integrated into a single common valve. In particular, this uses a flap-type valve member 1855.4 to allow inhalation, with exhalation controlled by use of a spring valve defined by the interaction between the valve ring 1855.1 and the valve seat 1841.7.

In the above arrangement, the degree of compression in the spring 1854 may control the degree of restriction during exhalation. Further, the threaded engagement between the spool valve base 1851 and the valve body 1841.1 may be used to adjust the position of the spool valve base 1851 in the valve body 1841.1. This action adjusts the degree of compression in the spring, which in turn controls the restriction during exhalation.

To facilitate this process, a regulator 1860 may be provided, which in one example is formed from a cylindrical regulator body 1861 having a plurality of projections 1862 on an upper end that define radial and circumferential channels 1862.1, 1862.2. In use, the passages 1862.1, 1862.2 receive the cylindrical valve base 1851 and the radial strut 1852 such that rotation of the regulator body 1861 allows the cylindrical valve base 1851 to rotate and thus move in and out within the valve body 1841.1. In another example, cylindrical adjuster body 1861 includes scale markings 1863, allowing the position of cylindrical valve base 1851 to be adjusted in a controlled manner. For example, movement of the spool valve base 1851 by one marker may correspond to a set increase or decrease in exhalation resistance.

In addition to the above-described modifications to the valve arrangement, in the above-described example, a nasal pillow 1844.2 is provided that is formed from a rigid or semi-rigid pillow tube 1844.2 made from nylon or polyurethane. The pillow tubes are adjustably mounted to the valve body 1844.1 via ball socket mounts 1844.6 to allow for changes in the orientation of the tubes, while different lengths of tubes can be used to accommodate different oral-nasal heights. Gel insert 1844.5 is mounted on the tube to allow sealing.

Another exemplary arrangement will now be described with reference to fig. 19A and 19B, which show a modified version of the arrangement in fig. 18A to 18D. For ease of explanation, the explanation uses similar reference numerals as used in the example of fig. 18A to 18D, albeit increased by 100, and therefore these features will not be described in further detail.

Thus, in this example, the valve arrangement 1940 comprises a hollow tubular valve body 1941.1 incorporating a valve 1950. In this example, a nasal pillow 1944.2 similar to the nasal pillows previously described is provided.

In this example, the valve body 1941.1 further includes a port 1941.9 upstream of the valve 1950 and in fluid communication with the valve passage. In one example, the port 1941.9 is in the form of a tapered Luer fitting (Luer fitting) allowing a hose or other delivery device to be coupled directly thereto. This allows for coupling of e.g. O ₂Isogas, drugs, anesthetics, or other substances are delivered directly into the valve airway. These valve arrangements allow a flow of gas into the airway of the user such that such drugs and/or gases are entrained in the flow of gas and delivered to the airway of the user. This may also be used to deliver air under pressure, thereby providing PAP. In this example, there is no need for a continuous small vent as in the case of conventional PAP, as the pressure can be controlled using a valve arrangement, allowing the air volume and hence the pump size to be significantly reduced. For example, it may be set at, for example, 10cmH₂PAP was supplied at O pressure. The nasal PEEP (positive end expiratory pressure) provided by the valve arrangement may be set at, say, 12cmH₂O, which opens only on exhalation, since it is higher than the PAP pressure.

In one example, this form of arrangement may be used in conjunction with a dual valve arrangement similar to that described above with respect to fig. 17A and 17B, allowing a combination of PAP and PEEP to be provided. For example, in a dual configuration, the nasal PAP may be, for example, at 10cmH₂O under pressure. Nasal PEEP may be set at, for example, 12cmH₂O, which opens only on exhalation, since it is higher than the PAP pressure. The oral PEEP can be set higher.

In the example of PAP supply via a port, an additional one-way flap valve may be required on the air supply hose for safety. In particular, this may be used to prevent re-inhalation into the hose and allow the arrangement to revert to a standard PAP or TwoPAP arrangement if the air supply fails.

Such an arrangement providing air and/or other airflow may also be achieved without a valve arrangement, and examples of this arrangement will now be described with reference to fig. 20A to 20E and 21A and 21B.

In the example of fig. 20A and 20B, the connector arrangement 2070 comprises a hollow tubular connector body 2071 shaped to fit over or within the extraoral opening 131 of a breathing assistance apparatus similar to that described above with respect to fig. 1A-1E. The tubular body 2071 includes front and rear openings 2071.1, 2071.2 connected by a connector airway 2071.3 to allow airflow therethrough, such that airflow can pass into and out of the breathing assistance apparatus, and thus into and out of the airway of the user.

Additionally, the connector includes a port 2072 similar to a luer port that includes an outer opening 2072.1 and an inner opening 2072.2 in fluid communication with the connector air passage 2071.3.

As shown in fig. 20C-20E, the connector may be attached to an oral appliance similar to the oral appliance described above with respect to fig. 1A-1E. Thus, the oral appliance includes an appliance body 2010 shaped to be positioned at least partially within the mouth of a user. Specifically, in this example, the oral appliance includes a hollow side base 2011 that extends inwardly from the hollow arcuate sidewall 2012. The appliance body includes a tubular body 2131.1 extending between the lips of the user.

In this case, the port 2072 is attached to a delivery tube that extends through the connector body 2070 and the appliance airway 2033, terminating near the intraoral opening 2032. This allows gases such as air, O₂Etc. are delivered directly to the back of the mouth.

It will also be appreciated that a similar function may be achieved without the need for a port, for example, by using a clip or another similar arrangement to position and retain a delivery tube in the apparatus of figures 1A to 1E.

In the example of fig. 20A and 20B, the inner opening 2072.2 terminates at the inner wall of the tubular body 2071. In contrast, in the alternative configuration of fig. 21A and 21B, port 2172 extends through tubular body airway 2171.3 such that port inner opening 2172.2 is proximate rear opening 2171.2.

These arrangements can also be used to couple e.g. O₂Gas, medication, anesthetic or other substance such as air, is delivered directly into the valve airway. These valve arrangements allow a flow of gas out of the user's airway such that such drugs and/or gases are entrained in the flow of gas and delivered to the user's airway.

Another exemplary connector arrangement will now be described with reference to fig. 22A to 22D.

In this example, the connector arrangement 2270 includes a hollow tubular connector body 2271 shaped to fit over or within the extraoral opening of the oral appliance. The tubular body 2271 includes a front opening 2271.1 and a rear opening 2271.2 connected by a connector airway 2071.3, allowing airflow therethrough, such that airflow can enter and exit the oral appliance, and thus the airway of the user.

In addition, the connector includes a first port 2272 extending laterally from an upper portion of the connector body 2271, the first port including an outer opening 2272.1 and an inner opening 2272.2. The connector further includes a second port 2273 extending transversely from the connector body 2271 and aligned opposite the first port 2272. The second port includes an outer opening 2273.1 and an inner opening 2273.2 and is not in fluid communication with the first port to define two distinct flow paths. In use, the first and second ports may be provided to allow different gases to be supplied to or received from the user's oral cavity, typically via intra-oral openings, and optionally via separate intra-oral openings, via respective appliance airways. This may be used to allow O to be supplied, typically via the appliance airway ₂Anesthetic or other gas for delivery to the user. At the same time, the second port may be used to collect exhaled gas, including, for example, a luer lock for measuring end tidal volume.

The connector may also be coupled to a front port 2174 having an outer opening 2174.1 and an inner opening (not shown) in fluid communication with the front opening 2271.1, which may be used to connect to additional equipment, such as an inline valve, which may be used to provide PEEP, as will be described in more detail below, or to attach respiratory equipment, such as a positive airway pressure device, Ambu bag for resuscitation, and the like.

In one example, each port 2272, 2273 may be provided in fluid communication with a utility airway, but in another example, a respective airway may be provided, and this example will now be described with reference to fig. 23A to 23E.

In this example, an oral appliance is provided having a single appliance body 2310 shaped to be positioned at least partially within the mouth of a user. Specifically, in this example, the oral appliance includes a hollow side base 2311 that extends inwardly from a hollow arcuate sidewall 2312. The appliance body includes a tubular body 2331.1 extending between the lips of the user.

In this case, tubular body 2331.1 includes a first extraoral inlet 2335 disposed in fluid communication with first intraoral opening 2336 via first channel 2337 and a second extraoral opening 2331 in fluid communication with second intraoral opening 2332 via second channel 2333. In this example, first inlet 2335 is configured to connect with an opening in first port such that it is in fluid, thereby being in fluid communication with first port 2372, allowing O to pass₂Etc. are delivered directly to the back of the mouth via first intraoral opening 2336, while second port 2373 is in fluid communication with second channel 2333, allowing collection of exhaled air for determination of end tidal volume.

It should be understood that the example of fig. 23A-23E uses a one-piece oral appliance capable of receiving maxillary and mandibular teeth, but this is not required and it should be understood that a similar configuration could be implemented with a two-piece oral appliance, similar to that shown in fig. 7A and 7B. Such an example will now be described in more detail with reference to fig. 24A and 24B.

In this example, the oral appliance body 2410 is shaped to be positioned at least partially within the mouth of the user and to engage the maxillary teeth. The oral appliance includes a hollow side base 2411 extending inwardly from a hollow arcuate side wall 2412, with a tubular body 2331.1 extending forwardly to extend between the lips of the user in use.

The tubular body 2431.1 also includes a second extraoral opening 2431 in fluid communication with the second intraoral opening 2432 via a second passageway, and a first extraoral opening 2435 in fluid communication with the first intraoral opening 2436 via a first passageway, thereby allowing for the provision of first and second ports in fluid communication with the first and second intraoral openings 2432, 2436, respectively.

An alternative connector arrangement for use with the oral appliance of fig. 24A and 24B is shown in fig. 25A and 25B.

In this example, the oral appliance includes a body 2510 similar to the body 2410 described above. In this example, connector 2570 includes a first port 2572 in fluid communication with first gas passage 2537. Second port 2573 is also disposed in fluid communication with second gas passage 2533, and thus it will be appreciated that operation is substantially similar to that described above. However, in this example, first port 2572 and second port 2573 are vertically offset, which may facilitate communication with the respective gas passages.

In one example, the above arrangement may be used with an in-line valve arrangement, and examples thereof will now be described with reference to fig. 26A and 26B.

In this example, the valve arrangement 2680 includes a valve body 2681 that includes a front opening 2681.1 and a rear opening 2681.2. A valve arrangement 2650 is provided in the valve body, which is generally similar to that described in relation to figures 18A to 18D.

Specifically, in this arrangement, 2650 includes a cylindrical valve base 2651 having radially extending lateral struts 2652 that define openings that allow gas flow into and out of the valve. These struts include circumferential recesses that serve as seats for the first ends of the springs 2654. The second end of spring 2654 is coupled to a valve ring 2655.1 having a shoulder that extends outward to define a 90 ° angle of rotation that engages a valve seat in valve body 2681. The valve ring 2655.1 supports a hub 2655.3 that is mounted on arms that extend radially inward from the valve ring 2655.1. Hub 2655.3 includes a cylindrical opening that slidably engages, in use, a shaft 2681.4 extending axially within valve body 2681 to guide the movement of valve ring 2655.1 within valve body 2681.

The flexible valve member 2655.4 is mounted on the valve hub 2655.3. In use, the valve member 2655.4 selectively engages the upper end of the valve ring 2655.1, thereby selectively closing the opening defined by the valve ring 2655.1 according to the flow of gas therethrough.

In use, valve 2650 is mounted in valve body 2681 via a threaded outer surface of cylindrical valve base 2651 that engages a correspondingly threaded inner surface of valve body 2681, and which may be held in place via front opening body 2681.5.

It should be appreciated that in this arrangement, the valve 2650 provides differential resistance during inspiration and expiration using a combination of different mechanisms integrated into a single common valve. Specifically, this uses a flap-type valve member 2655.4 that opens during inhalation to provide a first level of resistance, with exhalation controlled through the use of a spring valve defined by the interaction between the valve ring 2655.1 and the valve seat 2641.7.

In the above arrangement, the degree of compression in the spring 2654 may control the degree of restriction during exhalation. Further, the threaded engagement between the cylindrical valve base 2651 and the valve body 2681 may be used to adjust the position of the cylindrical valve base 2651 in the valve body 2681. This action adjusts the degree of compression in the spring, which in turn controls the restriction during exhalation.

It should be appreciated that an in-line valve arrangement may be used in conjunction with the front connector port 2674, thereby allowing an in-line valve to be used with the port arrangement of fig. 22 to 25.

Another example of a breathing assistance apparatus will now be described with reference to fig. 27A to 27F.

The oral appliance includes an appliance body 2710 that is shaped to be positioned at least partially within the mouth of a user. Specifically, in this example, the oral appliance includes a hollow side base 2711 having spaced apart upper and lower surfaces 2721.1 and 2721.2 that extends inwardly from a hollow arcuate side wall 2712 having upper and lower inner side walls spaced apart from a curved outer side wall 2712.3. The appliance body includes a tubular body 2731.1 extending between the lips of the user.

In this example, an extraoral opening 2731 is provided on the outside of tubular body 2731.1, wherein extraoral opening 2731 is in fluid communication with an implement airway 2733 that passes through tubular body 2710 to one or more intraoral openings 2732 provided in the oral cavity to allow air flow into and out of the rear region of the oral cavity.

A port 2735 is provided that extends from tubular body airway 2731.3 and is in fluid communication with appliance airway 2733 to enable a user to access a device such as O₂Gas such as air, medication, anesthetic or other substance is delivered directly into the airway of the oral appliance.

Additionally, in this example, a second extraoral opening 2734 is provided that is located within tubular body 2731.1 and inside extraoral opening 2731 that opens directly in front of the user's mouth. This allows access to the external oral cavity of the user, for example for inserting tools or devices or the like.

This arrangement is particularly suitable for surgical applications because it allows for delivery of drugs such as anesthetics via port 2735 and allows for access to the oral cavity via opening 2734, e.g., allows for surgical instruments such as gastroscopic/endoscopic instruments to be received and inserted into the oral cavity.

Fig. 28A-28C show another variation.

In this example, the opening 2371 is replaced by two ports 2872, 2873 that communicate with the first and second intra-oral openings 2836, 2832 via respective first and second airways 2837, 2833. In this case, the second airway 2833 is partially closed by the lingual wall 2811.3, but in the variation shown in fig. 28D, the lingual wall is removed so that the second port 2873 opens directly to the oral cavity via the opening 2873.1. In another case, O is delivered via port 2872₂Or other gas and the tip tidal volume is measured through port 2873. As with the previous example, the oral cavity may be accessed via opening 2874.

Another example of a valve arrangement will now be described with reference to fig. 29A and 29B, which show a modified version of the valve arrangement shown in fig. 18A to 18D. For ease of explanation, the explanation uses similar reference numerals as used in the example of fig. 18A to 18D, albeit increased by 1100, and therefore these features will not be described in further detail.

Thus, in this example, the valve arrangement 2940 comprises a hollow tubular valve body 2941.1 shaped to fit over or within the extraoral opening of the first body (not shown). The valve body 2941.1 includes a valve body opening that contains a valve 2950 to allow airflow into and out of the valve body to be controlled by the valve during inhalation and exhalation. The valve 2950 shares the same configuration as the valve 1850 described above with reference to fig. 18A-18D, and therefore will not be described in further detail. Which is arranged in fluid communication with the nasal pillow tube 2944.2 of the valve arrangement and the extraoral opening when fitted to the first body.

In this example, the valve arrangement 2940 further includes a nasal pillow connector 2944.1 mounted to the valve body 2941.1 via a hollow nasal pillow connector rod 2980.1. The nasal pillow tube 2944.2 is formed integrally with the nasal pillow connector 2944.1 from a rigid or semi-rigid material such as nylon, polyurethane, or silicone rubber. The nasal pillow connector rod 2980.1 is adjustably mounted to the valve body 2941.1 via a hollow ball socket mount 2944.6 to allow the orientation of the nasal pillow 2944.2 to be changed. A gel ring 2944.3 is mounted on the nasal pillow tube 2944.2.

The nasal pillow connector 2944.1 can be coupled with the nasal pillow connector rod 2980.1 in a variety of ways. In this example, nasal pillow connector 2944.1 is reversibly attached to nasal pillow connector rod 2980.1 to allow nasal pillow connector 2944.1 to be attached to and subsequently removed from nasal pillow connector rod 2980.1. Such reversible coupling arrangements may include magnetic engagement, use of an interference fit, a clip fit, or, as is the case in the present example, a friction fit.

This reversible coupling arrangement allows the nasal pillow connectors 2944.1 to be interchanged. Thus, by connecting appropriately configured nasal pillow connectors 2944.1, different oronasal heights and different nostril opening sizes and directions can be easily accommodated. With such a modular design, various aspects that may be changed between different nasal pillow connectors 2944.1 may include: the angle at which the nasal pillow tubes 2944.2 protrude; the length and/or diameter of the nasal pillow tube 2944.2; the shape of the nasal pillow 2944.2 (e.g., substantially circular or substantially oval); the overall height and/or width of the connector, etc. The gel ring 2944.3 may then improve the seal between the nasal pillow and the user's nares by compensating for any minor differences in fit between the recently fitted nasal pillow connector and the user's facial attributes.

Another example of an interchangeable nasal pillow connector 3044.1 integrally formed with the nasal pillow tube 3044.2 is shown in fig. 30A-30C. The lower surface of the nasal pillow connector 3044.1 defines a substantially elliptical lower opening 3044.7 that is in fluid communication with the nasal pillow tube 3044.2 and is configured to couple to the nasal pillow connector stem with a friction fit.

Another example of a valve arrangement will now be described with reference to fig. 31A and 31B, which shows a modified version of the valve arrangement shown in fig. 29A and 29B. For ease of illustration, the illustration uses similar reference numerals as used in the example of fig. 29A and 29B, albeit increased by 200, and therefore these features will not be described in further detail.

Thus, in this example, the valve arrangement 3140 comprises a hollow tubular oral cavity valve body 3141.1 shaped to fit over or within the extraoral opening of the first body (not shown). Additionally, in this example, the valve arrangement 3140 also includes a hollow tubular nasal valve body 3191.1 mounted to the oral valve body 3141.1 via a sliding adjustment means 3170. The oral valve body 3141.1 includes a valve body opening containing an oral valve 3150 to allow for control of airflow into and out of the oral valve body 3141.1 through the oral valve 3150 during inhalation and exhalation through the user's oral airway. Nasal valve body 3191.1 also includes a valve body opening containing a nasal valve 3190 to allow for control of airflow into and out of nasal valve body 3191.1 through nasal valve 3190 during inhalation and exhalation through the user's nasal airway.

The slide adjustment means 3170 includes an adjustment flange 3171.1 formed on the oral valve body 3141.1 and two complementary gripping flanges 3174.1 formed on the nasal valve body 3191.1. A curved slot 3171.2 is formed in the adjustment flange 3171.1, and a clamping bolt 3174.2 passes through both the clamping flange 3174.1 and the curved slot 3171.2. A nut appropriately tightened on the clamping bolt 3174.2 can clamp the two clamping flanges 3174.1 to the adjustment flanges to provide sufficient friction to secure the nasal valve body 3191.1 relative to the oral valve body 3141.1. Loosening the nut of the clamp bolt 3174.2 to release the friction allows the nasal valve body 3191.1 to move relative to the oral valve body 3141.1, with the clamp bolt 3174.2 moving along the slot 3171.2.

In this example, nasal pillow connector 3144.1 is reversibly coupled directly to nasal valve body 3191.1 with an integrally formed nasal pillow tube 3144.2 by a clip or snap fit. It should be understood that other reversible coupling arrangements may be used, as described above with respect to the valve arrangement described in fig. 29A and 29B. Additionally, in this example, both the oral valve 3150 and the nasal valve 3190 have the same configuration as the valve 1850 described above with reference to fig. 18A to 18D. It should be appreciated that in other examples, one or both of the oral and nasal valves 3150, 3190 may be provided with alternative configurations.

An example of such an alternative valve arrangement will now be described with reference to fig. 32A to 32D, which show a modified version of the valve arrangement shown in fig. 31A and 31B. For ease of illustration, the illustration uses similar reference numerals as used in the example of fig. 31A and 31B, albeit increased by 100, and therefore these features will not be described in further detail.

In this example, oral valve 3250 shares the same general configuration as described above with respect to valve arrangement 540 shown in fig. 5A-5D, and nasal valve 3290 shares the same general configuration as described above with respect to the valve arrangement shown in fig. 4A-4D. In this example, similar to valve members 843.1, 843.2 of valve arrangement 840 depicted in fig. 8A-8D, the valve members of both oral valve 3250 and nasal valve 3290 include one or more openings therein to allow airflow through these valve members when they are in the closed position. Thus, in this configuration, this allows exhalation to occur via the opening, thereby introducing resistance during exhalation, which in turn creates pressure in the oral and nasal cavities, maintaining positive airway pressure within the patient's airway to maintain airway inflation, which can help maintain the user's airway open. It should be understood that the discussion above regarding the various configurations of valve members 843.1, 843.2 of valve arrangement 840 shown in fig. 8A-8D applies equally to oral valve 3250 and nasal valve 3290 in this example.

Further, in this example, nasal pillow connector 3244.1 is reversibly coupled directly to nasal valve body 3291.1 with an integrally formed nasal pillow tube 3244.2 by a clip or snap fit. Nasal valve 3290 is located at the opening of nasal valve body 3291.1, which snaps or clips into the lower opening of nasal pillow connector 3244.1. It should be understood that other reversible coupling arrangements may be used, as described above with respect to the valve arrangement described in fig. 29A and 29B. It should also be understood that nasal valve 3290 can be located elsewhere in nasal valve body 3291.1.

Another example of a valve arrangement will now be described with reference to fig. 33, fig. 33 showing a modified version of the valve arrangement shown in fig. 31A and 31B. For ease of illustration, the illustration uses similar reference numerals as used in the example of fig. 31A and 31B, albeit increased by 400, and therefore these features will not be described in further detail.

In this example valve arrangement 3340, nasal valve body 3191.1 of valve arrangement 3140 is replaced by a device connector 3345.1 coupled to tube 3345.2, which defines a tool airway that supplies airflow from a positive airway pressure device. The device connector 3345 is mounted to the valve body 3341.1 via a slide adjustment device 3370, which has the same configuration as the slide adjustment device shown in fig. 31A to 32E, and is coupled to the nasal pillow connector 3344.1 using a suitable coupling arrangement (such as a clip, snap, friction or interference fit) or by a magnetic mechanism. The valve body 3341.1 is substantially identical to the oral valve body 3141.1 described above with reference to fig. 31A and 31B. It should be understood that the valve body 3341.1 may take alternative configurations, such as the configuration of the oral valve body 3241.1 of the valve arrangement depicted in fig. 32A-32E.

In this example, the device airway is in fluid communication with the nasal airway, allowing positive airway pressure to be provided to the nasal cavity of the user. A plurality of device connector airway openings are provided in the device connector 3345.1 to control the air pressure in the device connector airway. It should be appreciated that in other examples, additional or alternative airway openings may be provided in the tube 3345.2. These airway openings may be used in conjunction with nasal valves provided to help the device connector control nasal air pressure during inhalation and exhalation.

Thus, it should be understood that in some embodiments, the oral appliance and connector may include first and second ports in communication with respective intraoral device openings that allow intraoral delivery of airflow, O₂Or other gases, and also allows for sensing of exhaled air, e.g., for determining tip tidal volume. This communication may be direct by having the port extend into the oral cavity, and/or may be via the appliance airway, such as by providing a port that communicates with the appliance airway extending to an opening in the oral cavity.

In one example, this is achieved using an ISO 5367-2014 compliant port that can be attached to oxygen (or AIR) at a suitable flow rate (such as 6 liters/minute) with or without a valve. This may provide a hospital or remote setting with adequate airway pneumatic splints. Can also provide a measure of CO ₂Luer lock for end tidal volume. These connectors may be used in surgery, for example, for sedation or total intravenous anesthesia (TIVA) for monitoring or anesthetic infusion. The device may allow deeper sedation without airway obstruction/hypoxia and reduce litigation due to lack of consciousness. In addition, this may help prevent tooth damage from biting the oropharyngeal airway or laryngeal mask during removal. The arrangement may also be used for home or remote use, for example for COPD/OSA/asthma patients.

In further examples, the port may communicate with a channel within the oral appliance, allowing O₂Delivered to the back of the mouth via a dedicated channel separate from the air inhalation/exhalation channel. In this case, additional devices may be added to the front of the kit, for example to allow the use of additional equipment including, but not limited to, Ambu bags for resuscitation, inline PEEP valves, filters or non-rebreathing oxygen masks.

In another example, the oral appliance may be configured to provide access to the oral cavity, e.g., to allow insertion of an instrument, such as inAs occurs during gastroscopy, endoscopy, and the like. In such a case, an opening may be provided in the oral appliance to keep the user's mouth open while also allowing delivery of O via the corresponding channel ₂And the like.

This can help protect expensive equipment and avoid injury to the patient. This configuration can move oxygen deep into the buccal/alveolar spaces on each side through dedicated separate airways and with wider dental anchors to remove pressure from the (vulnerable) anterior teeth. In addition, if desired, a luer lock port may be provided to measure CO₂End tidal volume.

It will thus be appreciated that at least some of the above examples provide a valve arrangement configured to be attached to an extraoral opening of an oral appliance to provide a breathing assistance apparatus that can provide differential resistance to airflow during inhalation and exhalation. In particular, these arrangements may be used to provide differential resistance during inhalation and exhalation, with the level of resistance being controlled by appropriate valve configurations, thereby allowing different levels of positive airway pressure to be generated within the user's airway during exhalation.

Adjustment of the characteristics of the valve arrangement, as well as different combinations of valve arrangements, such as oral only, nasal only, combinations of oral and nasal, etc., may be used to control the generated positive airway pressure, which is performed based on the user's breathing characteristics, thereby optimizing the airway pressure based on the requirements of each user.

While the device has been described with reference to the oral appliance of fig. 1A to 1E, it will be appreciated that this is not essential and a similar arrangement may be implemented with any suitable oral appliance. For example, although preferred, the airway arrangement of the oral appliance of fig. 1A to 1E is not intended to be limiting. In particular, the valve arrangement described in more detail below may be used with any configuration of oral appliance that includes an airway to allow airflow through the oral cavity. For example, the airway may extend directly through the tubular body 131.1 and into the front of the oral cavity, effectively providing an airway directly between the lips and the incisors. Alternatively, the airway may include a portion of the oral cavity, for example by using an open channel, for example using one or more openings provided along the length of the channel to allow airflow into the oral cavity along the entire length of the oral cavity.

Additionally and/or alternatively, in certain embodiments, the valve arrangement may be used with an oral appliance that does not have an airway, for example when the valve arrangement is used to control airflow through a nasal cavity of a user. In this case, the oral appliance may be in the form of a moulded mouthpiece which effectively serves only to support the valve arrangement outside the user's mouth. This may represent a viable alternative to using a mask, which is the preferred arrangement for most conventional PAP techniques, but is often uncomfortable for the user, particularly where positive airway pressure is delivered to the nasal passages of the user.

It will therefore be appreciated that the valve arrangement is intended for use with a variety of oral appliances and that reference to the appliance of figures 1A to 1E, although beneficial, is not intended to be limiting.

It will also be appreciated that the above arrangement may also be used in combination with other features. For example, the valve arrangement and/or the extraoral opening may comprise a heat and/or moisture exchanger, such as a Heat Moisture Exchange (HME) sponge, which controls the water and temperature content of the inhaled air by exchanging heat and moisture with the exhaled air. In one example, this may be provided in an extra-oral cavity, where the valve is outside the extra-oral cavity, or vice versa, to ensure that there is sufficient available space to accommodate the HME sponge and valve. Although this is not necessary and, optionally, a valve and a heat and/or moisture exchanger may be incorporated into the valve arrangement and/or the extraoral opening.

Throughout this specification and the claims which follow, unless the context requires otherwise, the word "comprise", and variations such as "comprises" or "comprising", will be understood to imply the inclusion of a stated integer or group of integers or steps but not the exclusion of any other integer or group of integers. The term "about" as used herein means ± 20% unless otherwise indicated.

It must be noted that, as used in the specification and the appended claims, the singular forms "a," "an," and "the" include plural referents unless the context clearly dictates otherwise. Thus, for example, reference to "a support" includes a plurality of supports. In this specification and the claims which follow, reference will be made to a number of terms which shall be defined to have the following meanings unless an intention to the contrary is apparent.

It will, of course, be appreciated that while the above has been given by way of illustrative embodiments of the invention, all such and other modifications and variations thereto as would be apparent to persons skilled in the art are deemed to fall within the broad scope and ambit of the invention as herein set forth. It will be understood that the invention disclosed and defined in this specification extends to all alternative combinations of two or more of the individual features mentioned or evident from the text or drawings. All of these different combinations constitute various alternative aspects of the present invention.