MASK WITH GUSSET
A mask system for delivering air to a user includes a suspension mechanism to allow relative movement between a face-contacting cushion and a mask shell. The suspension mechanism also provides a predetermined force to the cushion that is a function of mask pressure, displacement of the cushion or both.
This invention relates generally to masks for use in respiratory therapy. One use is in CPAP treatment of Obstructive Sleep Apnea. However, the mask arrangements presented herein are useful in other types of respiratory therapy. In the quest for an improved mask arrangement for respiratory therapy, there are various design objectives—effectiveness of seal between the mask and the patient's face, good compliance with a prescribed therapy regime, and patient comfort. The present invention provides various embodiments of a novel mask arrangement, which offers several distinct advantages over known mask arrangements.
BACKGROUNDIn respiratory therapy where air is delivered to the mask under pressure, it is important to maintain a good seal between the mask and the patient's face. Leaks between the mask and the patient's face can reduce the desired air pressure in the mask and create increased noise. Both can reduce the effectiveness of, and compliance with, the therapy. In the first instance, the prescribed treatment parameters are not being maintained. In the latter, the increased noise can disrupt the sleep cycle of both the patient and the patient's bed partner.
Leaks are especially prone to occur as the patient moves during the night. Drag and movement of the air delivery tube or the mask system as the patient turns or moves can alter the positioning and alignment of the mask with respect to the patient's face, which movement can be translated or transferred to the cushion seal, creating leaks. Thus, while the mask may initially be leak free when attached to the patient, leaks are prone to develop later in the night as the patient moves in bed, awakening the patient. Hence, patients may tighten straps more than is necessary for pressure requirements in order to reduce or prevent leaks that result from movement.
Many different mask systems are known. One broad group of known mask systems include a rigid shell, a face-contacting cushion and headgear. The shell typically encompasses the nose or nose and mouth. Some known shells encompass the entire face. The cushion is typically constructed from a soft material such as silicone. A headgear provides a means to secure the mask in position. One known form of headgear consists of an arrangement of straps.
Certain mask designs have been developed to increase the flexibility of the mask cushion to enhance patient comfort while maintaining an effective seal between the mask and the patient. The Bubble Cushion (a registered trademark of ResMed, Ltd.) Mask, covered by U.S. Pat. No. 5,243,971, the subject matter of which is incorporated herein by reference, uses a flexible cushion membrane attached to a mask shell and the pressure inside the mask system to assist in the seal of the cushion membrane itself against the skin or face of the user.
The ResMed Mirage (a registered trademark of ResMed, Ltd.) Mask System, is covered by, inter alia, U.S. Pat. No. 6,112,746, the subject matter of which is incorporated herein by reference, has a contoured, three-dimensionally shaped cushion having an outer face-contacting membrane spaced apart from an inner frame rim to both assist in the seal and increase the comfort of the patient. Neither of these masks incorporates an expanded gusset section for mounting the cushion to the mask to assist in sealing the mask to the patient (user).
A known fitting procedure with a known mask has been to supply the maximum air pressure to the mask that will be supplied to the mask during the therapy and to adjust the strap tension to the necessary level to prevent leaks at that maximum air pressure. However, in many therapy regimens, this maximum air pressure is often encountered only during a portion of the duration of the therapy and the mask air pressure is lower at other times during the therapy. Such is the case, for example, when using auto-titrating or variable pressure systems or during ramp-up when using CPAP systems. Thus, the strap tension is higher than necessary during significant portions of the therapy duration. Further, since leaks are disruptive of both the sleeping cycle and the prescribed therapy regimen, patients will often tighten the straps even more than is necessary to prevent leaks at the maximum encountered air pressure. In known masks, this higher than necessary strap pressure directly results in a higher than necessary force of the mask cushion on the patient's face, particularly as the pressure goes below the maximum mask air pressure.
See
The force (tension) in the headgear strap Fs for the prior art mask has been found empirically to be given by the equation Fs=(Fc+FAc)/(2 cos θ), where θ is the angle of the head strap with respect to the mask 110. Thus, the force of the cushion on the patient's face Fc is given by the equation Fc=2Fs cos θ−FAc. The force of the mask cushion on the patient's face is difficult to distribute completely evenly around the cushion in known masks, especially at higher forces, and results in localized high pressure spots around the mask cushion. This higher force on the face, and especially the localized high pressure spots, are uncomfortable to the patient and can disrupt the sleep cycle. See, for instance,
This force on the face increases as the head straps of a known mask are tightened to increase the sealing force of the mask, and thereby compressing the cushion and bringing the shell of the mask closer to the patient's face. When the straps are tightened, the shell of the mask moves a distance X between a position X0 when a seal is first obtained to a position Xp when it reaches the point where the cushion is being compressed beyond its normal range. The mask shell may be able to move beyond Xp but the cushion tends to become rigid or nearly so at about Xp, thereby limiting further travel. In a known mask, Fc generally increases at a first rate (i.e., the slope of the curve) as the mask moves toward the patient's face within a given range of X. This first rate occurs within the range of flexibility of the face-contacting portion 134. This first rate is also a function of the pressure in the mask acting on a back side of the face-contacting portion 134 of the mask. Thus, as the pressure in the mask increases, the first rate also increases within the given range of X.
However, the known cushion becomes less flexible as it is further compressed beyond such range of X. In a mask having a more flexible sidewall, as discussed above, Fc will then increase at a faster rate as the mask moves toward the patient's face due to a spring-force imparted by the sidewall until such point as the sidewall is nearly completely compressed and directly passing on the force from the rigid mask shell to the face. In a mask having a more rigid sidewall, as discussed above, Fc will then increase at an even faster rate for a short distance as the mask moves toward the patient's face but will quickly reach a point where the rigid sidewall is directly passing on the force from the rigid mask shell to the face.
See
U.S. Pat. Nos. 5,492,116 and 5,655,527 to Scarberry disclose a full-face respiratory mask. The mask includes a flexible seal member 18 directly attached to a mask shell 12 and is attached to the user's head by head gear 24. The flexible seal member 18 itself contacts the user's face with a broad area of contact and maintains a seal with the user's face through pressure in the space 62 acting directly upon seal membrane inner surface 54.
Japanese Provisional unexamined patent application (Laid-open Kokai) published Jan. 6, 1999 entitled NASAL MASK FOR RESPIRATION, Provisional Publication No. 11-397 discloses a bellows-formed elastic body between a mask shell and cushion. As seen in the figures of that publication, the bellows portion of the mask projects an area over the patient's face that is substantially the same as the contact area defined by the line of contact of the mask cushion with the patient's face. This publication teaches nothing about the relationship between the area of the bellows and the force applied to the patient's face. Although the bellows provides limited mechanical flexibility, no significant pressure advantages or significant mechanical flexibility can be achieved. This mask does not overcome the sealing problems incurred by movement of the mask with respect to the patient's face without utilizing an increased head strap pressure across the mask air pressure operating range.
SUMMARY OF THE INVENTIONIn one aspect, the invention provides a mask system including a shell which in use is positioned in a predetermined position relative to a patient's face, a face-contacting cushion which in use transfers a force to the patient's face, and a means for permitting relative movement between the cushion and the shell wherein said means provides a predetermined force on the cushion. In one form, the predetermined force is a function of mask pressure. In another form, the predetermined force is a function of the displacement of the shell relative to the face. In another form, the predetermined force is a function of both mask pressure and displacement of the shell relative to the face. In another form, the predetermined force is independently controlled. In another form, the means for permitting relative movement between the cushion and the shell is provided by a gusset section positioned in-between the shell and the cushion.
In one aspect, the invention provides a mask system including a face-contacting cushion having a first projected area on the face, a mask shell and a gusset section therebetween, the gusset section having a second projected area on the face wherein the second projected area is greater than the first projected area by greater than approximately 30%.
In another aspect the invention provides a mask system for use at a mask pressure including headgear coupled to a shell which exerts forces on the shell and a face-contacting cushion which transfers forces to the face, constructed and arranged so that the force transferred from the face-contacting cushion to the face is a strong function of mask pressure. The greater projected area of the gusset arrangement with respect to the face contacting area of the cushion uses the air pressure in the mask to expand the gusset into contact with the patient's face, even when the mask shell changes alignment with the patient's face, to provide a more secure seal between the mask and the patient. The expansion, contraction and bending of the gusset allows for enhanced mechanical flexibility over known mask arrangements that helps to maintain a seal even when the patient moves significantly during sleep and the position of the mask with respect to the patient's face changes. Thus, the force of the mask on the face is most significantly proportional to the mask air pressure and the cushion is maintained in secure sealing contact with the patient's face by the mask air pressure over a broader range of positioning of the mask with respect to the patient. This allows for the tension in the straps of the headgear to be generally less than with a known mask to securely seal the mask to the patient's face, especially at mask air pressures below the maximum mask air pressure for the therapy, providing greater patient comfort and compliance with the prescribed respiration therapy regime.
While some membrane-type cushion mask arrangements accommodate limited relative movement between the cushion and the wearer's face while maintaining a tolerable seal, the present invention dramatically increases the level of accommodation without a corresponding increase in the head strap pressure used to secure the mask to the patient. The gusset section provides a flexible component between the mask shell and the cushion in contact with the user's face while reducing the tension required in the headgear to maintain the seal.
Other embodiments of the present invention provide new mask cushion configurations that assist in maintaining the seal between the mask cushion and the user's face.
Another embodiment of the present invention includes the use of a novel baffle element positioned within the interior space of the mask arrangement. The employment of a baffle member within the mask of the present invention minimizes short-circuiting of the intake gas directly to the exhaust vent with the resulting buildup of carbon dioxide. Thus, the baffle serves to reduce the functional dead space of the mask and reduce the level of carbon dioxide rebreathing by the patient.
With the foregoing in mind, other objects, features and advantages of the present invention will become more apparent upon consideration of the following description and the appended claims with reference to the accompanying drawings, all of which form part of this specification, wherein like reference numerals designate corresponding parts in various figures.
A first embodiment of the respiratory mask 10 of the present invention is shown in
Cushion 30 includes a face-contacting portion 34 that is adapted to engage the face 42 of a patient (user) 40 as shown in
The gusset portion 32 includes two key characteristics that provide the benefits of one embodiment of the present invention. The first key characteristic of the gusset portion 32 is that it utilizes the pressure in the mask acting on its increased surface area to provide the primary force for maintaining the face-contacting portion of the cushion in sealing contact with the user's face. The second key characteristic of the gusset portion is that it provides a decoupling joint between the face-contacting portion 34 of the cushion 30 and the mask shell 20, thus allowing some relative movement between the mask and the user's face. This arrangement substantially protects the seal from undue disturbance in the following scenarios: 1) displacement or tilting of mask shell or harness; 2) relaxation of the facial muscles; 3) movement of the patient; and/or 4) movement of the tube.
The area Ag is a projected area on the user's face (i.e., projected on a plane normal to an axis of the mask) of an interior of the gusset portion 32 exposed to the mask air pressure. In the embodiment shown in
The significance of this can be seen from the following. In one form of the invention, the total force of the mask on the face Fm is given by the empirical equation Fm=Fc+FAc=P(Ag−kX)=2Fs cos θ. The force of the cushion on the patient's face Fc is given by the empirical equation Fc=P(Ag−Ac−kX). The force (tension) in the headgear strap Fs is given by the empirical equation Fs=P(Ag−kX)/(2 cos θ), where k is the spring constant for the elasticity of the gusset portion and X is the amount of travel of the mask shell toward the face.
Although k is usually not affected by pressure with respect to a purely mechanical spring, it has been found that within the pressure ranges occurring in the mask of the present invention, that k is proportional to both pressure and distance traveled. Thus, while in the present invention, the maximum force on the face Fm that could be expected to be exerted within Xp would be PAg, testing has shown that this is reduced by the k factor which is both proportional to pressure in the mask and distance traveled.
For a prior art mask configuration, it is seen from
From
For the present invention configuration, both the cushion contact force and the strap tension are significantly affected by the pressure in the mask due to the significantly increased area of the gusset. Therefore, as they both are most proportional to the pressure in the mask, they both will be significantly lower at low pressures and increase as the pressure reaches higher pressures.
In fact, in practice, it has been found that this holds true even at maximum mask air pressures. As an example, assume that Ac is the same in both a known mask (as, for instance, the ResMed Mirage® mask) and the inventive mask (both using, say, the same configuration in the face-contacting portion of the cushion). FAc would be the same in both cases. Then you might expect that given proper alignment of both masks, the minimum necessary Fc for sealing the masks at a given pressure would be the same in both the known and inventive masks and thus, the required Fm to seal at a given pressure to be the same in both cases. However, testing has shown that the present invention mask will seal at a lower force on the cushion, a lower force on the face, and a lower tension in the straps, even at the maximum mask air pressure, than the known mask. It is believed that the test results reflect the real world situation. That is, no face is identical and exactly conforms to the cushion and further, that it is extremely difficult to maintain exact alignment of the mask with the face. This is even more the case with older and/or overweight patient that have loose skin, wrinkles and/or skin folds that hamper the sealing of the mask to the face. Testing has shown that the present invention mask is better able to accommodate these inconsistencies from user to user and provide better sealing performance at lower forces on the face (even at the maximum mask air pressure) than the known mask.
See also the chart in
In one embodiment of the present invention shown in
In the preferred embodiment of the mask, the total force applied to the face Fm is approximately constant at between 35 to 108 grams per gf/cm2 mask air pressure, preferably between about 40 to 88 grams per gf/cm2 mask air pressure and most preferably between about 50 to 88 grams per gf/cm2 mask air pressure. The force applied by the surface area in contact with the face Fc is maintained at an approximately constant proportion to the mask air pressure being delivered to the user and is maintained between about 8 to 61 grains per gf/cm2 mask air pressure, preferably between about 27 to 61 gms per gf/cm2 mask air pressure and most preferably between about 40 to 61 grams per gf/cm2 mask air pressure over a mask air pressure range of 4 to 25 gf/cm2. The force Fc is also maintained within a range of about 0.3-4 grams per gf/cm2 pressure of the supply of pressurized breathable gas per linear centimeter around a circumference of the cushion in contact with the user's face, preferably within a range of about 0.5-4 grams per gf/cm2 pressure of the supply of pressurized breathable gas per linear centimeter around a circumference of the cushion in contact with the user's face, more preferably in a range of about 1-3 grams per gf/cm2 pressure of the supply of pressurized breathable gas per linear centimeter around a circumference of the cushion in contact with the user's face, and most preferably in a range of about 1.5-3 grams per gf/cm2 pressure of the supply of pressurized breathable gas per linear centimeter around a circumference of the cushion in contact with the user's face over a mask air pressure range of 4 to 25 gf/cm2. Although the preferred force ranges for the various forces are set forth in this paragraph, it should be recognized that the force ranges can be set between any two points within the respective overall force ranges given. It is noted that in the industry of the present invention, most pressure measurements are given in centimeters water and that 1 centimeter water=1 gf/cm2=98.07 Pascals.
The gusset portion also allows the mask to maintain a seal with the patient's face over a range of about plus or minus 8° out of alignment with the patient's face.
It has also been found that the shape of the curve for the inventive mask shown in
In the first example, shown in
A similar effect can be obtained by adding rigid backstops to the embodiment of
Where the gusset has sidewalls having a tapered thickness, as shown in
The gusset portion need not be in the single gusset form discussed above, but can have alternative configurations, examples of which are shown in
Yet another alternative mask configuration is shown in
First, if additional sealing force is needed from the gusset portion, the pressure P2 can merely be increased, or vice-versa if less sealing force is needed. Second, since the force imparted on the cushion by the gusset portion is a product of the pressure P2 and the area of the gusset portion Agc, the area Agc is less critical than in the previous embodiments because it can be offset by changes in the pressure P2. For instance, the outer periphery of the gusset portion can be made smaller in this embodiment than in the previous embodiments because an interior portion of the gusset portion is now also adding to the pressurized area of the gusset portion. Further, the area Agc of the gusset chamber can be varied as desired, and especially made smaller, by varying the pressure P2. This allows the mask to be made smaller, as compared to the other masks discussed above, to be less intrusive and more comfortable to the patient.
The pressure P2 can be controlled to be in relatively constant proportion to P1 or can be controlled to be in varying proportion to P1 as the circumstances warrant. While it is currently believed that in most therapies. P2 will be greater than P1 for most, if not all, of the therapy, it is contemplated that in certain situations, controlling P2 to be less than P1 can be desirable. In some instances, it is contemplated that P2 be held constant. The gusset chamber in this embodiment is intended to be connected only to the second pressurized gas supply and otherwise be closed, especially to the atmosphere. Thus, there should be minimal leakage from the gusset chamber and the second pressurized gas supply need only supply a small volume of gas, significantly less than the volume of gas that must be supplied for breathing purposes by the first pressurized gas supply. Further, the two separate pressurized gas supply sources for P1 and P2 can be provided by the same single gas pump and controlled by known control devices to be at the different desired pressures, or alternatively, two separate gas pumps can be used for the gas supplies to the mask interior 192 and the gusset chamber 190, respectively, to separately control each of P1 and P2.
The gusset chamber 190 can be connected to the second gas supply through a port 194 in the gusset side all 33 connecting with a port 195 integrally molded with the mask shell 20 or can bypass the mask shell 20 and connect to the second gas supply through a port 196 in the gusset sidewall 33. See
The embodiment of
In an alternative embodiment of the mask shown in
The cushion can also have alternative configurations. See
In the embodiments shown in
In the embodiments shown in
The embodiments of
Other alternative embodiments can use various combinations of any of the embodiments disclosed herein.
It should be recognized that the gusset portion of the present invention can be manufactured as a component separate from the cushion and mask shell but is attachable therebetween to provide the benefits described herein.
The reduced contact force, total force on the face and headgear tension across the mask air pressure range and especially at mask air pressures below the maximum mask air pressure improves patient comfort, in particular for auto-titrating devices which start therapy at low pressures at the beginning of the night when the patient is trying to get to sleep. The improved seal (which can be obtained with a lower contact force) reduces sleep disturbance to patients and partners by substantially reducing the risk of leaks. The improved seal also increases the confidence of the patient in the seal, resulting in more comfortable therapy for the patient. See
Another aspect of the present invention is the inclusion of the baffle 23 in the mask shell 20. The employment of the baffle in the mask shell 20 improves the movement of air within the mask. In the embodiment shown in
While the invention has been described in accordance with what is presently believed to be the most practical and preferred embodiments, it is to be understood that the invention is not to be limited to the disclosed embodiments but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and the scope of the appended claims, which claims are to be interpreted in the broadest manner so as to encompass all such equivalent structures.
Claims
1. A breathable gas mask arrangement, comprising:
- a mask shell having a portion adapted to receive a supply of pressurized breathable gas and a user side;
- a gusset portion having a first side attached to the user side of the shell and having a second side;
- a cushion having a first portion constructed and arranged to attach to the second side of the gusset portion and a second portion constructed and arranged to contact a user's face in use and provide a seal between the mask arrangement and the user's face; and
- a headgear constructed and arranged to attach the mask shell to the user;
- wherein, the gusset portion is constructed and arranged such that it can expand and contract to alter a distance between the mask shell and the cushion, an interior of the gusset portion being exposed to the supply of pressurized breathable gas and having a projected area on the user's face Ag which is greater than an area Ac of contact of the cushion with the user's face such that the supply of pressurized breathable gas acting on the area Ag provides a component of a contact force Fc of the cushion on the user's face, and a ratio of Ag/Ac is at least 1.30.
2. A breathable gas mask arrangement as in claim 1, wherein the ratio of Ag/Ac is in a range of 1.50 to 5.00.
3. A breathable gas mask arrangement as in claim 2, wherein the ratio of Ag/Ac is in a range of 2.00 to 4.00.
4. A breathable gas mask arrangement as in claim 3, wherein the ratio of Ag/Ac is in a range of 2.25 to 3.50.
5. A breathable gas mask arrangement as in claim 1, wherein the gusset portion can expand and contract to alter the distance between the mask shell and the cushion by at least 15 mm.
6. A breathable gas mask arrangement as in claim 5, wherein the gusset portion can expand and contract to alter the distance between the mask shell and the cushion by at least 20 mm.
7. A breathable gas mask arrangement as in claim 1, wherein the gusset portion includes a single gusset having a flexible sidewall with a generally triangular cross-section when not exposed to the supply of pressurized breathable gas that balloons to a generally rounded cross-section when exposed to the supply of pressurized breathable gas.
8. A breathable gas mask arrangement as in claim 7, wherein the gusset portion includes a plurality of interconnected gussets having flexible sidewalls with generally triangular cross-sections when not exposed to the supply of pressurized breathable gas that balloon to generally rounded cross-sections when exposed to the supply of pressurized breathable gas.
9. A breathable gas mask arrangement as in claim 1, wherein the gusset portion includes a plurality of sequentially interconnected steps moving from larger to smaller in area between the first and second sides of the gusset portion, respectively.
10. A breathable gas mask arrangement as in claim 1, wherein the mask shell includes an axially extending cylinder portion and the gusset portion is in the form of a piston axially slideably engaged with the cylinder portion of the mask shell.
11. A breathable gas mask arrangement as in claim 10, and further including a spring engaged between the mask shell and the piston to apply a retracting force between the mask shell and the piston.
12. A breathable gas mask arrangement as in claim 11, wherein the mask shell includes a stop portion for engaging the piston to limit axial movement of the piston.
13. A breathable gas mask arrangement as in claim 1, wherein the gusset portion includes a plurality of interconnected gussets, at least two of the gussets having differently sized areas exposed to the supply of pressurized breathable gas.
14. A breathable gas mask arrangement as in claim 1, wherein the gusset portion includes a sidewall having a thickened cross-section at a base of the sidewall.
15. A breathable gas mask arrangement as in claim 14, wherein the thickened portion has 20 a generally uniform thickness.
16. A breathable gas mask arrangement as in claim 14, wherein the gusset portion includes a sidewall having a cross-sectional thickness tapering from a thickened base portion to a thinner portion.
17. A breathable gas mask arrangement as in claim 1, and further including a generally rigid backstop attached to the mask shell for contacting a first sidewall portion of the gusset portion to limit movement of the first sidewall portion.
18. A breathable gas mask arrangement as in claim 17, wherein the generally rigid backstop extends around substantially an entire periphery of the gusset portion.
19. A breathable gas mask arrangement as in claim 18, and further including a generally rigid second backstop attached to the mask shell for contacting a second sidewall portion of the gusset portion to limit movement of the second sidewall portion.
20. A breathable gas mask arrangement as in claim 1, wherein the mask shell further includes a baffle disposed in an interior of the mask shell between a mask gas intake and a mask exhaust vent to deflect gas from the intake from directly flowing to the exhaust vent.
21-124. (canceled)
Type: Application
Filed: Nov 9, 2016
Publication Date: Mar 2, 2017
Inventors: Robert Henry FRATER (Sydney), Joanne Elizabeth DREW (Sydney), Michael Kassipillai GUNARATNAM (Sydney)
Application Number: 15/347,194