NZ764985A - Combined nasal and mouth ventilation mask - Google Patents

Combined nasal and mouth ventilation mask

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Publication number
NZ764985A
NZ764985A NZ764985A NZ76498515A NZ764985A NZ 764985 A NZ764985 A NZ 764985A NZ 764985 A NZ764985 A NZ 764985A NZ 76498515 A NZ76498515 A NZ 76498515A NZ 764985 A NZ764985 A NZ 764985A
Authority
NZ
New Zealand
Prior art keywords
mask
nasal
chamber
port
patient
Prior art date
Application number
NZ764985A
Inventor
Michael Pedro
Steven Cataldo
David Kane
Thomas Reilly
Ryan Redford
Original Assignee
Revolutionary Medical Devices Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Revolutionary Medical Devices Inc filed Critical Revolutionary Medical Devices Inc
Publication of NZ764985A publication Critical patent/NZ764985A/en

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Abstract

A gas ventilation mask comprising a nasal mask and a mouth mask, the nasal mask defining a nasal chamber having a multi-lobed Y-shaped seal adapted to interface with a patient’s face, and the mouth mask defining an oral chamber, wherein the mouth mask is connected with and moveable relative to the nasal mask, and the nasal and oral chambers are coupled to one another through a sealable passage. The nasal mask has an oxygen port and a ventilation port.

Description

GOOQO‘xM-inwt—n Combined Nasal and Mouth Ventilation Mask During surgery a patient usually is placed under anesthesia and the most common delivery system consists of canisters containing anesthesia gases and oxygen, a system of regulating gas flow and the patient’s breathing, and a device ensuring the potency of the patient’s airway for breathing, oxygenation and the delivery of an anesthetic gas mixture.
A mask is used to provide oxygen to the patient either before the patient is anesthetized, while the t is anesthetized, or if the patient is sedated during the surgery or procedure. However, one of the drawbacks of mask ventilation is that it requires constant contact between the provider’s hands and the patient’s face to hold themask in place and WWWL’JWNNMNNNNNNNb—hb—th—Ii—At—d—d—Ai—ti—Ao—A#WNb—‘OKDOONONUI$WN—‘OCOONQM-5WN—‘O keep the patient in the sniffing position in order to ensure that oxygen and anesthetic gases do not leak out into the air and that the patient’s airway remains patent. if the provider does not maintain the patient in the sniffing on, a dangerous complication known as upper airway obstruction may occur. The reason the provider needs to perform continuous mask holding and maneuvering is due to the human anatomy and physiology.
When muscles of the jaw, tongue and upper airway relax due to sedatives and/or muscle relaxants given to the patient for sedation and/or esia, wherein, the jaw of the patient drops and the tongue obstructs the airway resulting in snoring (partial obstruction) or apnea ete inability for oxygen to pass via the upper airway into the , the upper airway , pharynx, larynx) may become partially obstructed and possibly completely closed. Another problem exists when a provider fails to administer enough anesthesia or sedative or the anesthesia or sedative begins to wear off and the patient begins to move. This can cause the patient’s airway to ct as well since the patient’s head and neck position are no longer in the sniffing position. Patient movement during surgery also can be dangerous because it can cause the n to make a mistake, particularly in eye, ear, nose, neck, head, and throat surgery.
Notwithstanding the aforesaid potential problems, the use of facemasks, r nasal masks, which only cover the nose, or facemasks, which cover both the nose and mouth, to apply inhalational agents, such as oxygen or volatile anesthetic gases, is ially universal in the medical field. However, up until now, nasal masks and facemasks have been used separately as either nasal masks alone or facemasks alone. A significant clinical need has emerged, where ing a nasal mask with a mouth mask into one could have a substantial impact on patient safety during both endotracheal intubation and red anesthesia care cases involving on. For example, current standard of care recommends pre-oxygenating (delivering 100% oxygen via facemask) a patient for several minutes prior to endotracheal intubation in order to fill the patient’s ©00\IO\Ul-I>UJN lungs with oxygen. Also, pre-oxygenating a patient significantly lengthens the time (2 -8 minutes) that patient begins to rate (blood—oxygen levels begin to fall to ally low levels). Exemplary of gas inhalation masks used in administering general anesthesia (GA) to a patient is that disclosed in US. Pat. No. 5,975,079 (Hellings et a!) As indicated by this , an acceptable anesthesia mask should be disposable, made of transparent material, have a strap or straps to hold the mask in place, when desired, be of sufficient size to cover the patient’s nose and mouth, and have a pneumatic sealing cushion, not only to promote patient comfort, but to t exposing the medical staff to anesthesia or other applied gas or gases. See also US 8,336,549 B2 in which there is discussed a 11 disposable anesthesia face mask comprising a shell member having an annular flange 12 and a donut shaped pneumatic sealing cushion attached to the shell member annular l3 flange. The shell member and its flange are “pear—shaped” defining a nasal portion of 14 first transverse , a mouth portion of second transverse extent, and an under-the— chin engagement portion of third transverse extent, where the second transverse extent is 16 greater than the first transverse extent and the third transverse extent is greater than the 17 second transverse . 18 Other prior art esia masks and CPAP masks are described in US 5,738,094; 19 US 2014/0083425; US 2003/0024533; US 6,779,524; US 2014/0076311; US 8,001,968, US 6,112,746; US 558; US 7,178,524; US 7,036,508; 5,560,354; US 21 2015/0059759; and US 5,243,971 22 Furthermore, mask straps and harnesses are commonly used to hold masks on a 23 patient. However, a common m in the majority of cases today with the use of 24 currently ble mask straps and/or the head harness is that they still require the provider to hold and maneuver the mask continuously during the surgery because there is 26 no way of fixing patient’s head and neck to a surface. US. Patent No. 6,981,503 B1 27 (hands-free anesthesia mask) proposes a way of attaching a head strap to the face; 28 however, it does not provide a means of restricting head and neck nt. Many 29 times when the patient is relaxed with on and anesthesia the head falls forward, causing collapse of the airway. One way to solve this problem is to fix the patients face 31 mask or head to a base surface which will prevent it from falling forward. Also, to avoid 32 partial and/or complete obstruction the provider can perform a maneuver called the “jaw 33 thrust” maneuver. The “jaw thrust” maneuver” is done with one hand moving thejaw up 34 and forward to move the tongue so that the airway is opened. The “jaw thrust” is performed while holding a mask over the patient’s mouth and nose to deliver oxygen. In GONONUx-bww order to ventilate the patient while performing a “jaw thrust” the provider is required to hold the mask over the patient’s face almost constantly and prevents the y to perform other tasks during the surgery. This has led to a significant loss of popularity of the mask anesthetics and the increased use of other airway devices, which are more invasive and have greater potential side effects and complications. Also, a problem exists that when a mask is adjusted on a patient when in a sniff position, when the patient’s head is moved to a more natural or “vertical” position, e.g,, post operation, the mask becomes loose on the patient’s head. See also U.S. Pat. 6,439,231; U.S. 511; U.S. 5,983,896; U.S. 5,778, 872; U.S. 4,265,235; U.S. 5,404,873; U.S. 3,856,051; U.S. 11 3,556,097; U.S. 4,007,737; U.S. 4,188, 946; U.S. 4,265,235; U.S. 4,463,755; U.S. 12 4,232,667; U.S. 4,596,246; U.S. 5,121,746; U.S. 5,284,160; U.S. 5,778,872; and U.S. 13 6,129,082; U.S. 2003/0183232 A1; U.S. 3,815,596;, U.S. 5,462,050; U.S. 6,035,852; 14 U.S.6,412,488; U.S. 6,736,139; U.S. 6,792,943; U.S. 6,981,503; U.S. 7,753,051 U.S. 6,981,503 B1; U.S. 7,753,051; U.S. 2009/0178680; US 4,905,712; US 3,889,668; U.S. 16 3,897,777; US 2007/0295335. 17 In our co-pending PCT ation Serial No. PCT/USI4/44934, we provide an 18 improved mask strap system for an anesthesia mask that allows hands-free t 19 ventilation while maintaining the patient in the sniffing position and ting head and neck nt. We also e an anesthesia strap system for maintaining an 21 anesthesia face mask on the head of the user, that prevents movement of the patient’s 22 head and neck, and can be placed in front of the patient’s face. Therefore if the t is 23 already lying down, sedated, or etized, the provider will not have to lift the 24 patient’s head off the table. We also provide an anesthesia mask anchor ring system including a plurality of elastomeric cords connecting the mask anchoring to a support. 26 The present invention provides improvements over the foregoing and other prior 27 art, and helps to solve the problem of patient’s desaturating by maintaining ventilation 28 even during intubation. The present ion in one aspect provides a gas ventilation 29 mask comprising an anesthesia nasal mask and a mouth or oral mask ng tively a nasal chamber and an oral chamber, ably connected to one another 31 so that the nasal mask may be used either separately as a nasal mask, or together with the 32 mouth mask as a combination mouth mask. 33 In another aspect of the invention, the mask is characterized by one or more of 34 the following features: (a) wherein the nasal and oral chambers are connected to one another through a self—closing valve or passage, preferably a septum or duck valve or passage; (b) further including at least one ation or oxygen port communicating with the nasal chamber, wherein at least one of the ventilation or oxygen port preferably is offset to a side of the nasal chamber; (c) comprising both a ventilation port and an oxygen port communicating with the nasal chamber, wherein at least one of the ventilation port and/or the oxygen port preferably is offset to a side of the nasal chamber, and further comprising a removable stopper or cap for at least one of the ports; (d) wherein the mask is formed at least in part of a transparent material to permit visualization of condensation or aspiration; (e) r comprising a lobed, preferably Y-shaped seal that interfaces with the patient’s face and the oral and/or nasal ventilation chambers of the mask; (1‘) further sing a J—shaped seal, connected to the oral chamber that seals the oral chamber and nasal chamber interface when the two chambers are engaged, preventing gas from escaping through that interface; (g) further comprising a multi—lobed, preferably Y-shaped seal on the nasal chamber that over—laps the J-shaped seal of the oral chamber, preventing gas from escaping that interface when both chambers are pressured; (h) further comprising a mask strap anchor pair that has one closed side for odating a strap attached and an open side, or two open sides, wherein the open side or sides allows a care provider to attach the strap to a patient, n the open side or sides preferable are oriented up so that when strap tension force is applied, the force is resisted by a bottom portion of the strap anchor in order that the strap does not slide off the anchor; and (i) further comprising grip indents on the left and right surfaces of the oral r for gripping by a care provider in placing the mask onto a patient’s face.
In another aspect of the invention, the mask comprises a nasal cushion including a nasal bridge region, a cheek region, and an upper lip , and a mouth cushion including a lower lip region, a check , and an upper lip region; a first nasal membrane or seal comprising a substantially triangularly shaped frame of ently deformable material having a first molded inwardly curved rim of the first nasal membrane or seal; a second nasal membrane or seal of resiliently deformable material, the second nasal membrane or seal being thinner, as thin, or thicker than the first nasal O¥OOO\IO\Ui-S>WN—a membrane or seal, the second nasal membrane or seal having a second molded inwardly curved rim, the second nasal membrane or sea] curved rim spaced a first distance from the first nasal membrane or seal curved rim in the cheek region and the second nasal membrane or seal curved rim spaced a second distance from the first nasal ne or seal curved rim in the nasal bridge region, the second distance being greater than the first distance. The first and second distances being measured when the mask is not in use. A portion of the second membrane or seal curved rim forms a face contacting seal. A first mouth membrane or seal comprises a substantially oval shaped frame of resiliently deformable al having a first molded inwardly curved rim of the first mouth .....ai membrane or sea]; a second mouth membrane or seal of resiliently deformable al, ll being thinner, as thin, or thicker than the first mouth ne or seal, has a second 12 molded inwardly curved rim. The second mouth membrane or seal curved rim is spaced l3 a third distance from the first mouth membrane or seal curved rim in the cheek region 14 and the second mouth membrane or seal curved rim is spaced a fourth distance from the first mouth membrane or seal curved rim in the mouth region. The fourth distance is 16 greater than the third distance, the third and fourth distances being measured when the 17 mask is not in use, a portion of the second membrane or sea] curved rim forming a face 18 contacting seal. 19 In still yet another aspect of the invention, the mask as above described is terized by one or more of the ing features: 21 (a) wherein the second molded rim and the first molded rim have a co-located 22 notch to accommodate the bridge of a wearer’s nose; wherein the first nasal membrane 23 or seal molded rim and the second nasal membrane or seal molded rim preferably are 24 substantially saddle-shaped, wherein the second nasal membrane or seal preferably is shaped so that the seal portion, in use, ts at least the wearer’s nose,; and, wherein 26 the seal portion, in use, preferably contacts the wearer’s facial tissue around the sides and 27 over the bridge of the wearer’s nose, and between the base of the wearer’s nose and the 28 top wearer’s lip; 29 (b) wherein the second rim and seal portion are shaped to generally match facial rs of the wearer in the region of facial tissue around the sides and over the 31 bridge of the ’s nose, and between the base of the wearer’s nose and the wearer’s 32 upper lip; 33 (0) wherein the first and second nasal membranes or seals comprise single 34 molded pieces; \OOONQUIQUJN-d ((1) wherein the first molded inwardly curved rim of the first nasal ne or seal is as thick, less thick, or thicker than the second nasal membrane or seal; and (e) n the second molded inwardly curved rim of the second nasal membrane or seal is as thick, less thick, or thicker than the first nasal membrane or seal.
In a still further aspect of the invention the mask includes a mask body for connection with a supply of breathable gas; and a nasal cushion secured to the mask body, the mask body and the cushion forming a nose-receiving cavity. The cushion includes: a nasal bridge , a cheek region and an upper lip region; and a substantially triangularly-shaped first nasal membrane or seal of resiliently deformable WWWWWNNNNNNNNNNH—‘F—‘HH—‘D—‘I—‘D—Ib—d$UJNh-lOKDOONQm-RWNHOOOOVONUI-RWNF‘O material is ed having a first molded inwardly curved rim to surround wearer’s nose. A second nasal membrane or seal also formed of resiliently deformable material is provided. The second membrane or sea] is vely more flexible than the first nasal membrane or seal. The second nasal membrane or seal has a second molded inwardly curved rim, the second molded rim being of the same general shape as the first molded rim and being fixed to and extending away from the first nasal membrane or sea] so as to have a second nasal membrane or seal inner surface spaced a first distance from an outer surface of the first molded rim in the wearer’s cheek region. The second membrane or seal inner surface is spaced a second distance from the first nasal membrane or seal outer surface of the first molded rim in the nasal bridge region. The second distance is greater than the first distance, when the first and second distances are measured when the mask is not in use. A portion of the second molded rim forms a face contacting seal, wherein the portion preferably is substantially coterminous with respect to said second molded rim and is resiliently deformable towards said first nasal membrane or seal.
In another aspect of the invention, the mask is terized by one or more of the following features: (a) the second membrane or seal molded rim and the first nasal membrane or seal molded rim preferably each have a ated notch to accommodate the bridge of a ’s nose. The first and second molded rims ably are ntially saddle- shaped. The second nasal membrane or sea] preferably is shaped so that the seal portion, in use, contacts at least the wearer’s nose. And, wherein the seal portion, in use, contacts the wearer’s facial tissue around the sides and over the bridge of the wearer’s nose, and between the base of the wearer’s nose and the wearer’s upper lip of the wearer; (b) wherein the rim and the seal portion are shaped to generally match facial oxoooqoxmhwww contours in the region of facial tissue around the sides and over the bridge of the wearer’s nose, and between the base ofthe nose and the upper lip of the wearer.
The present invention also provides a nasal CPAP treatment apparatus and a oral/nasal full face mask comprising: a generator, ventilator or 02 source for the supply of gas at a pressure elevated above atmospheric pressure; a gas delivery conduit coupled to the generator; and a nasal mask or a full face mask that comprises a nasal cushion including a nasal bridge region, a cheek region, and an upper lip region, and a mouth n including a lower lip region, a check region, and an upper lip region; a first nasal membrane or seal comprising a substantially triangularly shaped frame of resilient .._1 material having a first molded inwardly curved rim of the first nasal membrane or seal; a ll second nasal membrane or seal of resilient material, said second nasal membrane or sea] being thinner, as thin, or r than the first nasal membrane or seal. The second nasal 13 membrane or sea] has a second molded inwardly curved rim, the second nasal membrane 14 or seal curved rim being spaced a first distance from the first nasal membrane or seal curved rim in the cheek region and the second nasal membrane or sea] curved rim being 16 spaced a second distance from the first nasal ne or seal curved rim in the nasal 17 bridge region. The second ce is greater than the first ce, the first and second 18 distances being measured when the mask is not in use. A portion of the second 19 membrane or seal curved rim forms a face contacting sea]. A first mouth ne or seal comprises a substantially oval shaped frame of resiliently deformable material 21 having a first molded inwardly curved rim of the first mouth membrane or seal; a second 22 mouth membrane or sea] of resilient material, the second mouth membrane or seal being 23 thinner, as thin, or thicker than the first mouth membrane or seal, the second mouth 24 membrane or seal having a second molded ly curved rim. The second mouth membrane or seal curved rim is spaced a third distance from the first mouth membrane 26 or seal curved rim in the cheek region and the second mouth membrane or seal curved 27 rim being spaced a fourth distance from the first mouth ne or seal curved rim in 28 the mouth region. The fourth distance is greater than the third distance, the third and 29 fourth distances being measured when the mask is not in use, a portion of the second membrane or sea] curved rim g a face contacting seal. 31 In another aspect of the invention, the CPAP as above bed is characterized 32 by one or more of the following features: 33 (a) wherein the first and second molded rims preferably each have a co— 34 located notch to accommodate the bridge of a wearer’s nose. The first and second \oooqoxmgwwr—n molded rims preferably are substantially —shaped. The second nasal membrane or seal preferably is shaped so that the seal portion, in use, contacts at least the wearer’s nose. The seal portion, in use, contacts the facial tissue around the sides and over the bridge of the nose, and facial tissue around the sides and over the bridge of the nose, between the base of the nose and the upper lip and between the base of the nose and the upper lip ofthe wearer; (b) wherein the second molded rim and the seal portion are shaped to generally match facial contours in the region of facial tissue around the sides and over the bridge of the wearer’s nose, between the base of the wearer’s nose and the wearer’s WNNNNNNNNNNH—‘F‘H—Ifl—d—flp—@WNflowmflONLI‘ch-WN—‘OCOOVQMQWNHO upper lip and between the base of the wearer’s nose and the wearer’s upper lip of the wearer. The second molded rim and the first molded rim preferably have a co-locating rim to accommodate the lips of a wearer’s mouth. The first mouth membrane or seal molded rim and the second mouth membrane or seal molded rim preferably are substantially oval shaped. The second mouth membrane or seal preferably is shaped so that the seal portion, in use, contacts at least a wearer’s upper and lower lip, and also preferably contacts the facial tissue around the sides and over the upper and lower lips of the mouth of the wearer. The second rim and seal portion ably are shaped to generally match facial contours in the region of facial tissue around the sides and over the upper and lower lip of the mouth of the . The first and second mouth membranes or seals preferably comprise one molded pieces, wherein the first molded inwardly curved rim of the first mouth membrane or seal preferably is as thick, less thick, or r than the second mouth membrane or seal, and wherein the second molded inwardly curved rim of the second mouth membrane or seal preferably is as thick, less thick, or thicker than the first mouth membrane or seal.
The present invention also provides a mask for tion to a wearer’s face comprising: a mask body for connection to a supply of breathable gas; and a mouth cushion secured to said mask body. The mask body and cushion form a mouth—receiving cavity. The cushion includes: a mouth region, a cheek region and an upper and lower lip region. A substantially oval-shaped first mouth membrane or seal of resilient material has a first molded inwardly curved rim to nd the wearer’s mouth; a second mouth ne or sea] also formed of resiliently deformable material, the second mouth membrane or seal being relatively more flexible than the first mouth membrane or seal.
The second mouth membrane or seal has a second molded ly curved rim, the second molded rim being of the same general shape as the first molded rim and fixed to COOQQUI-QUJNH and extending away from the first mouth membrane or seal so as to have a second mouth ne or seal inner surface spaced a first distance from an outer surface of the first molded rim in the cheek region. The second mouth ne or seal inner surface is spaced a second distance from the first mouth membrane or seal outer surface of the first molded rim in the mouth region. A portion of the second molded rim forms a face ting seal. The seal portion is substantially coterminous with respect to the second molded rim and is resiliently deformable towards the first mouth membrane or seal in use of the mask.
In another aspect of the invention, the aforesaid mask is characterized by one or .._i O more of the following features: 11 (a) the second membrane or seal molded rim and the first mouth membrane 12 or seal molded rim preferably each have a ated rim to accommodate the wearer’s 13 mouth. The first and second molded rims preferably are substantially oval—shaped. The 14 second mouth ne or seal preferably is shaped so that the seal portion, in use, contacts at least the wearer’s mouth. The seal portion, in use, preferably contacts the 16 facial tissue around the sides and over the wearer’s mouth, and n the ’s 17 upper and wearer’s lower lip, wherein said rim and said seal n preferably are 18 shaped to generally match facial contours in the region of facial tissue around the sides 19 and the wearer’s mouth, and between the wearer’s upper and wearer’s lower lip. (b)(l) Optionally, the mask has a ventilator circuit port, ting from a side of 21 the nasal chamber as a straight port nominally located in an X — Y plane located on a left 22 side of the patient projecting in a negative X direction or essentially parallel to the X 23 axis, wherein the angle of the port relative to the X axis preferably projects at an angle 24 that varies from plus 90 degrees to negative 90 degrees. (b)(2) Optionally, the mask has a ventilator circuit port projecting from a side of 26 the nasal chamber as a straight port nominally located in an X «— Y plane located on the 27 right side of the patient projecting in the positive X direction or essentially parallel to the 28 X axis, wherein the angle of the port relative to the X axis preferably projects at an angle 29 that varies from plus 90 degrees to ve 90 degrees. (b)(3) Optionally, the mask has a straight ventilator circuit port that is at an 3] angle nominally located in the X — Y plane, wherein the ventilator circuit port ably 32 projects to an angle out of that plan by plus 90 degrees to negative 90 degrees. 33 (b)(4) Optionally, the mask has an ate ventilator circuit port, projecting 34 from a top of the nasal chamber in the negative Y direction as an d port nominally HOOWQOMAMMa—A located in the X ~ Y plane, wherein an open end of the elbow that connects with the ventilator points to a right side of the patient projecting in a positive X direction or essentially parallel to the X axis, wherein the angle of the elbowed port relative to the X axis preferably projects at an angle that varies from plus 90 degrees to negative 90 degrees. (b)(5) Optionally, the mask has an alternate ventilator circuit port, projecting from a top of the nasal chamber in the negative Y direction as an elbowed port nominally located in the X — Y plane, wherein an open end of the elbow that connects with the ator points to a left side of the patient projecting in a negative X direction or essentially parallel to the X axis, wherein the angle of the elbowed port relative to the X wwwwwNNNNNNNNNNV‘F—O—l—l—‘v—l—‘HH#WNHOOOOQQMAWN—‘OCOOQQLh-bkfik) axis preferably projects at an angle that varies from plus 90 s to ve 90 degrees, wherein the angle of the elbow portion of the alternate ventilator t port, preferably also projects at an angle out of the plane by plus 90 degrees to negative 90 degrees. (b)(6) ally, the mask has an oxygen port projecting from a side of the nasal chamber as a straight port nominally located in an X — Y plane located on a left side of the patient projecting in the negative X direction that can be parallel to the X axis, wherein the angle of the port ve to the X axis ably projects at an angle that varies from plus 90 degrees to negative 90 degrees. (b)(7) ally, the mask has an oxygen port projecting from the side of the nasal chamber as a straight port nominally located in an X — Y plane located on a right side of the patient projecting in the ve X direction that can be parallel to the X axis, wherein the angle of the port relative to the X axis preferably projects at an angle that varies from plus 90 degrees to negative 90 degrees. (b)(8) ally, the mask has an oxygen port, projecting from a top of the nasal chamber in a negative Y direction as an elbowed port nominally located in an X ~ Y plane, wherein the open end of the elbow that connects with the ventilator points to a right side of the patient projecting in the positive X direction that can be parallel to the X axis, wherein the angle of the elbowed port ve to the X axis preferably projects at an angle that varies from plus 90 degrees to negative 90 s. (b)(9) Optionally, the mask has an oxygen port projecting from a top of the nasal chamber in a negative Y direction as an elbowed port nominally located in an X ~ Y plane, wherein the open end of the elbow that connects with the ator points to a left side of the patient projecting in the negative X direction that can be parallel to the X axis, 1 wherein the angle of the elbowed port ve to the X axis preferably projects at an \DOO\IO\UIAUJN angle that varies from plus 90 degrees to negative 90 degrees. (b)(lO) Optionally, the mask has an alternate ventilator circuit port projecting from a front ofthe nasal chamber in the positive Z ion as an elbowed port, wherein an open end of the elbow that connects with the ventilator is pointing to a left side of the t projecting in a ve X direction or essentially parallel to the X axis, nominally in the X m Y plane, wherein the angle ofthe elbowed port relative to the X axis preferably projects at an angle that varies from plus 180 degrees to negative [80 degrees, or n the angle of the elbow portion of the alternate ventilator circuit port, wwwwwNNNNNNNNNND—‘V—‘i—‘I—‘b—JI—‘b—‘I—‘r—lb—l OONONUIAUJN—‘Ooooflam-DMN—‘O that is nominally located in the X — Y plane also preferably projects at an angle out of that plane by plus 90 degrees to ve 90 degrees. (b)(l 1) Optionally, the mask has an oxygen port, projecting from a front of the nasal chamber in a positive Z direction as an elbowed port, wherein an open end of the elbow that connects with the ventilator points to 5 left side of the patient projecting in a negative X direction or essentially parallel to the X axis, nominally in the X — Y plane, n the angle of the elbowed port relative to the X axis ably projects at an angle that varies from plus 180 degrees to negative 180 degrees, or wherein the angle of the oxygen port elbow portion that is nominally located in the X — Y plane ably also projects to an angle out of that plane by plus 90 degrees to negative 90 degrees. (b)(lZ) Optionally, the mask has a ventilator circuit port projecting from a side of the Nasal Chamber as a straight port nominally located in a Y plane located in a center side of the patient projecting in the negative y ion. (b)(l3) Optionally, the mask has an oxygen port projecting from a side of the nasal chamber as a straight port nominally located in a X H Y plane located on a left side of the patient projecting in the negative X direction or essentially parallel to the X axis, wherein the angle of the port relative to the X axis projects at an angle that varies from plus 90 degrees to negative 90 degrees.
) Optionally, the mask has an alternate ventilator circuit port projecting from a front of the nasal chamber in a positive Z direction as an elbowed port, wherein the elbow has an ability to swivel 360 degrees about the Z axis of the straight port connected to the nasal chamber, wherein the swivel elbow preferably is nominally 21 90 degree elbow. (b)(l 5) Optionally, the mask has a straight ator port connected to the nasal r in any location. l (b)(16) Optionally, wherein the nasal chamber of the mask is configured with one OOOOQQUX-bww or more ventilator circuit ports and zero or one or more oxygen ports. (b)(17) Optionally, wherein nasal chamber of the mask is designed to operate under a positive gauge pressure relative to the ambient atmosphere at a pressure less than or equal to 90 cm of water. (b)(18) Optionally, wherein the nasal and oral chambers of the mask, when connected, are designed to operate under a positive gauge pressure relative to the ambient atmosphere at a pressure less than or equal to 90 cm of water.
) Optionally, the nasal chamber is designed to operate under a negative WWWWNNNNNNNNNNHt—l—a—tw—Awi—d—d—ith—‘OKOOOQQLJI-PWNt—‘OKOOOflmm-bWNH gauge pressure relative to the ambient atmosphere at a re greater than or equal to negative 10 pounds of force per square inch. (b)(20) Optionally, the nasal and oral chambers, when connected, are designed to operate under a ve gauge re relative to the ambient atmosphere at a re greater than or equal to 10 pounds of force per square inch.
In yet another embodiment of the invention there is provided a nasal mask sing a ventilation port, an 02 port and a cap or plug hangeable between the ventilation port and the 02 port.
The present invention in yet another aspect provides improvements in devices for holding a mask in position on a patient, and in another aspect for holding a patient’s head in position. More particularly, in one aspect of the ion, there is ed a mask anchor for g a face mask on a patient, comprising a head bonnet for engaging a back of a patient’s head, a posterior head strap that originates from behind the patient’s head, in t with the patient’s head and attaches either directly or indirectly to the mask when the mask is on the patient’s face, wherein the strap can be tightened to create a seal to allow for positive pressure ventilation or left loose and for providing supplement oxygen.
In another ment the mask anchor may include one or more straps for attachment to a base/surface, for securing the mask to the patient’s face and also for securing the patient’s head to the base/surface and for stabilizing the patient’s head in In another embodiment, the mask anchor comprises three straps, a first side strap, a second side strap and a third side strap approximately evenly spaced from andjoined to the first strap and the second strap, and positioned posteriorly.
WO 87995 OOOONGUI-BWNH In one embodiment the posterior head strap is ed directly to the mask, or the first and second straps are attached directly to the mask.
In yet another embodiment, the posterior head strap is ed to an anchor ring which in turn is placed on the mask, or the first and second side straps attach to a mask anchor ring which is placed over the mask.
The present invention also provides a mask strap system including an expandable strap portion, having the ability to extend up to twice its length or more when the patient is in a sniff position, so as to maintain n on the mask when the patient is placed in a natural or “vertical” position. wwwwwNNNNNNNNNNHI—‘i—‘b—dt—‘v—‘r—‘Hh—ll—lAwwflocooqombww~coooxloxmhww_ In one embodiment the anesthesia mask strap system comprises an able strap n having the ability to extend; second and third non-expandable strap sections fixed to ends of the expandable strap section; and an adhesion section or device for fixing a length of the strap system when the second and third non—expandable strap sections are pulled to tension the expandable strap section. ably, the expandable strap section has the ability to extend up to twice its length, or more, and is formed of a resiliently expandable elastic material.
In yet another aspect of the mask strap system, the second and third non- expandable strap sections are fixed by adhesion to themselves. In such aspect the adhesion comprises hook and loop fasteners, or a mechanical clasp, such as a gripper, a suspender-type p clasp, a button and buttonhole, or a tab and belt hole.
In another and preferred aspect of the mask strap system, the strap system length is fixed by folding the second and third non-expandable strap sections back on themselves.
In still yet another embodiment of the mask strap system, the second and third non—expandable strap sections are fixed to a patient head support or a table ting the patient.
The present invention also provides an anesthesia mask having a strap system as above described.
The present invention also provides an anesthesia mask comprising an anesthesia nasal mask and a mouth mask defining respectively a nasal chamber and an oral chamber, detachably connected to one another so that the nasal mask may be used either tely as a nasal mask, or the nasal mask and the mouth mask used together as a ation nasal-mouth mask. The anesthesia mask preferably has two sets of retention straps, each comprising a first expandable strap portion having the ability to WO 87995 extend and second and third non-expandable ns fixed to ends of the first expandable strap portions, respectively and an adhesive section or device for fixing a length of the strap system when the second and third non-expandable strap sections are pulled to tension the expandable strap section, attached respectively to the nasal chamber and the oral chamber. In a preferred embodiment, the adhesion n comprises hook and loop fasteners.
With the t invention, the combined nasal mask and oral mask, can be used together as a facemask to ventilate a patient either prior to acheal intubation or during general anesthesia (GA), or the mouth mask can be separated from the nasal mask and the nasal mask used to apply uous ve airway pressure (CPAP) to help maintain a patent airway and ventilate a patient while the anesthesiologist attempts intubation, which will significantly prolong the time until the patient begins to desaturate. The current invention also is useful during sedation cases, especially for deep sedation or for ts with Obstructed Sleep Apnea (OSA) or obesity, where the upper airway of many of these patients becomes obstructed and prevents or impedes breathing.
The mouth mask of the current invention also can be separated from the nasal mask and the nasal mask can be used to apply continuous positive airway pressure (CPAP) to help relieve the upper airway ction, maintain a patent airway, and assist in ventilation during the case. The combined nasal and mouth mask of the current invention also is useful in ions where a nasal mask is not sufficient to ventilate the patient. With the mask of the present invention one can reattach the mouth mask and the mask used for traditional bag—mask ventilation. The mask of the present invention also permits a health care er to apply nasal CPAP during semi—awake fiberoptic intubations, where being able to maintain a patient’s oxygen saturation levels may be critical, or to apply PEEP to mechanically ventilated patients. Yet r feature and advantage of the mask of the present invention over the prior anesthesia mask art is the ability to secure not only the combined nasal mask and mouth mask to the patient’s face allowing for hands-free ventilation, but also to secure the patient’s head and neck in place by attaching to a surface and maintaining the patient in a position that ensures a patent airway, which is critical for oxygenation and ventilation.
Further es and advantages ofthe present invention will be seen from the following detailed description, taken in conjunction with the accompanying drawings, wherein like numerals depict like parts, and wherein: Figure 1 is a front view of a combined nasal mask and oral mask in accordance OO\)O\LII~I>UJI\> with the present invention; Figure 2A is a rear View ofthe mask ofFigure 1; s 2B—2D show details of the duck valve portion of the nasal mask r of Figure 1; Figure 2E shows details of the oral mask chamber of Figure 1; Figure 3 is an exploded View ofthe mask ofFigure 1; Figure 4 is a bottom view of the nasal r portion of the mask of Figure 1; Figure 4A is a perspective view of snap caps for use with the mask; Figure 5 is a perspective view of the nasal chamber portion of Figure 1; 11 Figure 6 is a view similar to Figure 1 of an alternative embodiment ofmask in 12 accordance with the present invention; 13 Figure 7 is a view similar to Figure 1 of another alternative embodiment of mask 14 in accordance with the present invention; Figure 8A is an exploded View from the interior of a combined nasal mask and 16 oral mask in accordance with the present invention; 17 Figure SB is an exploded side elevational view of a combined nasal mask and 18 oral mask in accordance with the present invention; 19 Figure 8C is an ed front view of a combined nasal mask and oral mask in ance with the present invention; 21 Figure 9A is an interior view of a combined nasal mask and oral mask in 22 accordance with the present ion; 23 Figure 9B is a side elevational view of a combined nasal mask and oral mask in 24 accordance with the present invention; Figure 9C is a plan view of combined nasal mask and oral mask in accordance 26 with the present invention; 27 Figures 9D and 9B are enlarged views of a J-shaped seal element of the ed 28 nasal mask and oral mask in accordance with the present invention; 29 Figure 9F is an enlarged view of a “Y” seal of a combined nasal mask and oral mask in accordance with the present invention; 31 Figure 10 is a side elevational view showing a combined nasal mask and oral 32 mask on a patient in accordance with the t invention; 33 Figure 11A and 1 18 show details of the Y element of the ed nasal mask 34 and oral mask in accordance with the present invention; \OOOQOMLUJN—n Figures 12A—12D show the J—shaped seal t in accordance with the present Figures i3A-l9B are views of an alternative and preferred embodiment of combined nasal mask and oral mask in accordance with the present invention; Figures 20A-C rate use of the nasal chamber portion of the mask for continuous positive airway pressure, and Figures 20D and 20B are side and end views of a cap valve useful with the nasal chamber portion of the mask of s 20A and 20B; Figure 21 is an end view showing a mask anchor applied to the head of a t; Figure 22 is a side elevational view thereof; NNNNNNNNNNHHH—KHHH—H—fith~O©WVQLh$WN—‘OCOOVQMAWNHO Figure 23 is a perspective view thereof; Figure 24A is a top—plan View of a mask anchor ring in accordance with further embodiment of the invention; Figure 24B is a View similar to Figure 24A showing a mask anchor ring on a mask; Figures 25A and 25B depict a ation mask on a patient in the sniff position (Figure 25A) and in a natural or “vertical” position (Figure 25B); Figures 26A and 26B are top plan and side ional views, respectively of a ventilation mask strap system in accordance with the present invention; Figure 27A is a top plan view of a ventilation mask with a strap system in accordance with the present invention; Figure 27B is a side elevational View of the strap system; Figure 27C is an ed view of a portion of the strap rated in Figure 27B; Figure 28 is a side view showing an alternative embodiment in which the mask strap is attached to a patient head support in accordance with the present invention’ Figure 29 is a top plan view of a combined nasal and mouth ventilation mask in accordance with the present invention; Figure 30A and Figure 308 are side and front views showing the mask of Figure 29 attached to a patient; and Figures 3lA—31E are similar to Figures 20A~20E, and illustrate how a luer connector may be integrated into a cap valve for accommodating a gas monitoring line.
As used herein, unless otherwise stated, the mask of the t invention advantageously may be used for delivering anesthesia, for positive pressure ventilation, CPAP, administration of supplemental , or PEEP (positive and expiratory pressure) in connection with a variety of pressurized gas sources including ventilation circuits, AMBU bags, oxygen canisters, etc.
WO 87995 KDOO\IO\UIJ§UJN—‘ Also, as used herein, the term “nasal mask” and “nasal chamber”, and “oral mask” and “oral chamber”, respectively, may be used interchangeably.
Major elements of mask 10 in accordance with the present invention are illustrated Figures l—5. The primary elements of the mask are a nasal r 12 and an oral chamber 14. Nasal chamber 12 is the primary structural element of the mask supporting all other sub—elements of the mask as will be described below, When combined as illustrated in Figure 1 and Figure 2, gases from the ventilator or to the ventilator are passed through both the mouth and the nose. The mask 10 operates as a traditional full face ventilation mask in this configuration. The full mask provides gases wmwwNNNNNNNNNNh—‘H—KH—IH—‘Hfl—lWN“O\DOO\]O\m-PWNHO\OOO\IO\M~hWN—‘O to the patient and removes waste gas h a ventilation port of the nasal chamber which es to a ventilation circuit that then attaches to an anesthesia machine. Gases can be exchanged from the patient’s nasal orifice and or the oral orifice of the patient.
One or more duckbill valves 16 are integral to the nasal chamber 12 as shown in Fig. 2D.
In this state, they seal the nasal chamber 12, preventing flow out of the valve orifices.
When the distal end of the oral chamber 14 proboscis tube 18 is engaged with the duck bill valve 16 located in the nasal chamber 12, the valve is opened, allowing gas transfer n the nasal and oral chambers. A duck bill valve separated from the nasal chamber 12 but placed on the oral chamber hollow proboscis tube is shown in Fig. 2E to illustrate how the valve is opened when the proboscis tube is d. The seal of the nasal chamber surrounds the nose and with the duck bill valves closed, gas exchange can only occur between the nose and the ventilation port, being contained by the other elements of the chamber.
The nasal chamber 12 and oral chamber 14 of the mask are mated and connected to one another through a nasal/oral port 17 which includes a septum or duck valve 16 (Figure 2A—2E). Alternatively, as shown in Figure 3, nasal r 12 and oral chamber 14 may be mated and connected to one another through nasal/oral port 17 by a tapered proboscis 18 which extends from the oral chamber 14 and engages with a tapered port 20 in the nasal chamber 12. A snap cap 22 which may be held on a line retainer 24 or hinged to a retainer ring 26 is provided for sealing port 20 when the nasal chamber 12 and oral r 14 are separated from one other.
A l, e.g., 15 mm diameter OD ventilator port 28 in the nasal chamber 12 aces with an anesthesia ventilation circuit or bag-mask (not shown). A preferred orientation of the ventilator port 28 is on the left side of the mask although alternate WO 87995 COONONUI-b-WNN positions could be off center or on the right side of the mask as illustrated in Figure 6.
When a patient is being transported, the ventilation port 28 remains open to the atmosphere, and allows C02 and other gasses to escape the patient during the breathing process.
A second port 30 for introduction of oxygen is provided in nasal chamber 12, and es a cap 32 which seals the oxygen port 30 during ventilation of the patient. Cap 32 is removed during patient transport and an oxygen supply line (not shown) is connected to the oxygen port 30, and typically past operation. The connection can be either a “Christmas Tree” type, as the preferred style, or a luer lock connection. The mwwwNNNNNNNNNNHHHH~HH~HH WN~O©OO\!O\UIJ>WN~O\DOO\IO\UI-I>UJNHO preferred location of oxygen port 30 is on the left side of the patient. An ate configuration could be on the right side.
When the nasal chamber 12 and oral chamber 14 are ted, the septum valve 16, is opened by the septum valve proboscis 18. This opening allows gas flow between the nasal chamber 12 and the oral chamber 14. As noted supra, a septum or duck valve is the preferred configuration, although other valves that are open when the two chambers are connected are possible. When the two chambers are separated, the proboscis 18 is removed, the duck valve 16 closes, sealing the nasal chamber 12 and prevents flow of gas out of the nasal r due to ventilator pressure inside the chamber. One or more septum or duck valves can interface between the nasal chamber 12 and the oral chamber 14, although, two are a preferred configuration. Alternatively, simple caps or plugs may be used in place of the septum or duck valve(s) to sea] the nasal chamber. Note that in an alternate ration the separate oxygen port 30 may be eliminated, and the oxygen supply line could interface directly with nasal portion of the nasal/oral port 17. A snap cap interface 34 exists on the outside of oxygen port 30. During nasal ation, a snap cap 36 is placed over oral port 30, sealing the nasal chamber 12. When the nasal chamber 12 and oral chamber 14 are connected, the tapered nasal / oral cis 18 engages with the nasal/oral port 17, creating a seal to the exterior, while allowing gas flow between the nasal chamber 12 and oral chamber 14. Note that in an ate configuration, the duck valve or septum port could be located on the oral chamber 14 and the hollow proboscis located on the nasal r 12.
Anchor straps 38, 40 are located on the left and right sides of the nasal chamber 12. Anchor straps 38, 40 secure the mask to a patient’s head or to a patient head support device as described in our PCT application number PCT/US14/44934, or in our co— WO 87995 2015/034277 1 pending US. Application Serial No. 62/118,301, filed February 19, 2015, the contents of 2 which are incorporated herein by reference. 3 Soft interface rings 38, 39, which may be, eg. a gel filled or air filled ring, or ring 4 formed of a low durometer al such as foam, silicone, a low durometer thermoplastic mer, a low durometer thermoplastic urethane, are connected to the 6 nasal chamber 12 and oral chamber 14, and interface the nasal r 12 and the oral 7 chamber 14, respectively to the patient’s face over the nose and mouth, providing near— 8 air—tight seals, as will be described in detail. 9 When the nasal chamber 12 solely is being used for ventilation of a patient, the nasal / oral port is sealed it so that positive ventilation pressure can be ed. 11 Use of the nasal/oral mask of the t invention will now be described. When 12 the nasal chamber 12 and oral chamber 14 of the mask are connected as shown in Figure 13 1, the mask is a full face ation mask. Both the nasal and oral openings of a patient’s 14 face are in communication with the ventilator circuit.
When the nasal chamber 12 and oral chamber 14 of the mask are separated as 16 shown in Figure 3, the mask may be used solely as a nasal ventilation mask. Providing 17 nasal ventilation allows for oxygenation to occur even during intubation or while 18 performing bag-mask ventilation. Note that alternate configurations ofthe mask could 19 consist of the nasal chamber 12 only, with no septum valve or oral chamber being included in the configuration. 21 Ventilation port 28 as shown is designed to nominally fit on the inner diameter of 22 a ventilation circuit (not shown). ate configurations are possible where the 23 ventilation port 28 fits the outer diameter of the ventilation circuit. In use, ventilation 24 port 28 is connected to a anesthesia circuit, while the oxygen port 30 is ted an 02 supply. The ventilation port 28 may be located to the top or to one side ofthe mask 26 (preferably to the left side of the mask). In the Figures 1-5 embodiment, the oxygen port ,27 30 is located to one side, preferably to the left side of the mask (from the 28 anesthesiologist’s viewpoint), so as to permit laryngoscopy and intubation to be Viewed 29 by the anesthesiologist from the right side of the patient’s face, and not ct the anesthesiologist’s View of the patient’s oral cavity. Of course, the ventilation port 28 and 31 oxygen port 30 may be located on the right side of the mask as well (from the 32 anesthesiologist’s viewpoint). 33 In another embodiment, shown in Figure 6, a ventilation port 70 may project off 34 center from the nasal chamber 12 as a straight port or angled to the right side of the nasal y... chamber (shown in phantOm at 71) nominally located in the X — Y plane located on the OOOVQUl-BWN right side ofthe patient, projecting in a negative X direction that can be parallel to the X axis. The angle of the port relative to the X axis can project at an angle that varies from plus 90 degrees to negative 90 degrees. In another alternative embodiment ventilation circuit port, 70, may be provided projecting from the top of the nasal chamber 12 in the ve Y direction as an elbowed port. The open end of the elbowed port 70 that connects with the ventilator may be oriented to point to the right side of the t projecting in the ve X ion that can be parallel to the X axis. The angle of the elbowed port relative to the X axis can project at an angle that varies from plus 90 WWWWNNNNNNNNNNt—IHHF‘WHH—‘HH wNI—‘oooewoxmAri—oooowoxmthi—o degrees to ve 90 degrees.
In still yet another embodiment ation port 70 may project from the top of the nasal chamber 12 in the negative Y direction as an elbowed port nominally located in the X ~ Y plane. In such embodiment, the open end of the elbow that connects with the ventilator points to the left side of the patient ting in the negative X direction that can be parallel to the X axis. Additionally the angle of the elbowed port relative to the X axis can t at an angle that varies from plus 90 degrees to negative 90 degrees.
The angle of the elbow portion of the alternate ventilation port, 70 that is nominally located in the X — Y plane also can project to an angle out of that plane by plus 90 degrees to negative 90 degrees.
Oxygen port 30 may project from the side of the left nasal chamber as a straight port nominally located in the X ~ Y plane located on the lefi side of the patient projecting in the negative X direction that can be parallel to the X axis. The angle of oxygen port 30 relative to the X axis can t at an angle that varies from plus 90 degrees to negative 90 degrees. Oxygen port 30 may project from the side of the nasal chamber 12 as a straight port nominally located in the X — Y plane located on the right side of the patient projecting in the positive X direction that can be parallel to the X axis. Additionally the angle of the oxygen port 30 relative to the X axis can project at an angle that varies from plus 90 degrees to negative 90 degrees. Oxygen port 30 also may project from the top of the nasal chamber 12 in the negative Y direction as an elbowed port nominally located in the X ~ Y plane. The open end ofthe elbow that ts with the ventilator points to the right side of the patient projecting in the positive X direction that can be parallel to the X axis. Additionally the angle of the elbowed port relative to the X axis can project at an angle that varies from plus 90 degrees to ve 90 degrees. l Oxygen port 30 also may project from the top of the nasal r in the 2 negative Y direction as an elbowed port lly located in the X — Y plane as shown 3 in phantom in Figure 3 at 30A. The open end of the elbow that connects with the 4 ventilator is pointing to the left side of the patient projecting in the negative X direction that can be parallel to the X axis. Additionally the angle of the elbowed port relative to 6 the X axis can project at an angle that varies from plus 90 degrees to negative 90 7 degrees. 8 Yet another alternative is shown in Fig 7, where the ventilation port 80 projects 9 from the front of the nasal chamber 12 in the positive Z direction as an elbowed port 1 0 which, in a preferred embodiment is swivel mounted. The open end of the elbow that 11 connects with the ventilator points to the left side of the patient projecting in the negative 12 X direction that can be parallel to the X axis as shown in Figure 13, nominally in the X — 13 Y plane. Additionally the angle of the elbowed port relative to the X axis can project at 14 an angle that varies from plus 180 degrees to negative 180 degrees. The angle of the elbow portion ofthe alternate ventilation port 80 that is nominally located in the X ~ Y 16 plane also can project to an angle out of that plane by plus 90 degrees to ve 90 17 degrees. An oxygen port also may project from the front of the nasal chamber 12 in the 18 positive Z ion as an elbowed port 82. The open end of the elbow that ts 19 with the ventilator is pointing to the left side of the patient projects in a negative X direction that can be parallel to the X axis as shown in Figure 13, lly in the X — Y 21 plane. Additionally the angle of the elbowed port relative to the X axis can project at an 22 angle that varies from plus 180 degrees to negative 180 degrees. The angle of the 23 oxygen port elbow 82 n that is nominally located in the X M Y plane also can 24 project to an angle out of that plane by plus 90 degrees to negative 90 degrees.
Alternatively, the ventilation port 28 may project from the side of the nasal 26 chamber as a straight port nominally located in the Y plane located in the front of the 27 nasal chamber 12 projecting in the negative y direction, and the oxygen port 30 t 28 from the side left of the nasal chamber as a straight port nominally located in the X ~ Y 29 plane located on the left side of the patient ting in the ve X direction that can be parallel to the X axis. Additionally the angle of the ventilation and oxygen ports 31 relative to the X axis can project at an angle that varies from plus 90 degrees to negative 32 90 degrees. 33 Referring again to Figure 7, the ventilation port 80 may t from the front of 34 the nasal chamber 12 in the positive Z direction as an elbowed port. The elbow has the UIJ>WN'—* ability to swivel 360 degrees about the Z axis of the straight port connected to the nasal chamber as illustrated, This allows 360 degree access of the ventilator circuit to the mask. This swivel elbow is nominally a 90 degree elbow but could be any angle.
Additionally the straight ventilator port connected to the nasal chamber could also be in any location as suggested earlier on the chamber.
Views of the nasal and oral chambers and corresponding seals are shown in Figures 8A-8C and Figures 9A-9F. As can be seen in the gs, the seals 102, 104 are attached along the nasal and oral chambers 106, 108 perimeter. As described above, the nasal chamber 106 has a ventilation port 110 that attaches to the ventilation circuit, an oxygen port 112 that attaches to an oxygen source and two oral chamber ports 1 14, 11 116 with duckbill valves that are closed when the oral and nasal chambers are 12 disengaged. The nasal chamber 106 also has closed and open strap loop anchors 118, 13 120 where a strap 122 attached on either side and circles the back side of the t’s 14 neck (see Figure 10), securing the mask to the patient with a tension force on. The oral chamber 108 has two proboscis 124, 126 that engage with the oral r ports 16 114, 116 opening the duckbill valves, so that both the oral and nasal chambers 106, 108 17 are at the same pressure level as determined by the ventilation circuit attached to the 18 ation port. 19 In the illustrated embodiment, the nasal chamber is intended to seal, in part to the oral chamber. Alternatively, as will be described below, the nasal chamber and the oral 21 chamber may be sealed directly and independently to the t’s face, in which case a 22 Y-shaped seal is the preferred seal for both chambers. The seals are intended to keep 23 gases within the chambers when pressurization is provided via the ventilation port. In 24 this embodiment are two types of seals 102, 104 in the mask, a multi—lobed, ably Y-shaped seal 102 (Y describes the seal section) which is the interface between the 26 oral chamber 108 and nasal chamber 106 to the face of the patient, and a J~shaped seal 27 104 (1 describes the seal cross-section) which is the interface between the region where 28 the oral and nasal chambers 108, 106 connect. In both cases, the intent of the seal is to 29 prevent gas from g the chamber through those interfaces when the chambers are pressurized relative to the ambient environment. 31 s of the force and pressure interaction of the multi-lobed, preferably Y- 32 shaped seal with the patient’s face are illustrated in Figures 1 lA-l 18. The base of the 33 multi-lobed, preferably Y-shaped seal 104 is ed to the chamber parallel to the local 34 X axis. In this case, the nasal chamber is shown. When the tension force of the strap, 1 FTension, is applied on the right and left side of the patient’s face, the multi—lobed, N preferably Y—shaped seal is ssed as illustrated, reacting to the force applied by the strap. The mutli-lobe, preferably Y~shaped seal is made of a pliable elastomer and the cantilever ofthe Y provides an effective spring stiffness, ngal. The seal will compress by an amount 55631 when the strap tension force is applied. The resulting force balance for the mask can then be described as in Figures llA-l 1B.
KSeal X 8Seal :3 2 X 1:Tension An additional benefit of the multi—lobed, preferably Y—shaped seal design is that when a differential pressure, nm, is applied to the or of the chamber as illustrated in Figure 11A, the seal is forced against the skin, making it more difficult for 11 the gas to flow between the seal and the skin due to the resulting force applied to the 12 interior Y arm of the seal, pushing it t the skin. 13 Details of the J~shaped seal 102 (J bes the seal cross section) are illustrated 14 in Figures 12A-12D. Note the interior of the J-shaped seal 102 is attached to the oral r in the region that aces with the nasal chamber when the two chambers are 16 engaged. The Jushaped seal 102 is made of an elastomer with an effective spring 17 stiffness K1363]. When the nasal and the oral chambers are engaged, a force, F336;“ is 18 applied and the seal is compressed by an amount 53w. Note the J portion of the seal 19 points inward towards the pressure as illustrated in Figure 12C provided by the ventilation circuit PVemilmion. The relationship between the applied force and 21 displacement can then be stated as follows: 22 KJSeai X 5J5eal = FJSeal 23 As will be appreciated, the multi-lobed, preferably Y—shaped seal and the J- 24 shaped seal provide numerous advantages. For one the multi-lobed, ably Y—shaped seal prevents gas leaving the pressurized portion of the oral and/or nasal chamber of the 26 mask. Also, the multi lobe, preferably Y-shaped seal, when pressurized, the interior leg 27 of the Y is pressed against the patient’s face, further sealing the mask. And the J—Seal 28 seals the oral chamber and nasal chamber interface when the two chambers are engaged, 29 preventing gas from escaping h that interface. Further, the J—Seal, when pressurized, the interior hook of the J is pressed against the t’s face, further sealing 31 the mask. Moreover, the multi—lobed preferably Y-shaped seal on the nasal chamber 32 over-laps the ed seal of the oral chamber, preventing gas from escaping that 33 interface when both chambers are pressurized.
©OO\IO«M-J>UJN._A With the mask of the present invention duckbill valves are closed when the oral and nasal chambers are separated, and open when engaged by the proboscis of the oral chamber, allowing gas flow between the oral and nasal chambers.
Finally, grip indents are provided on the left and right surfaces ofthe oral chamber allowing easier gripping by the anesthesiologist in placing the mask onto a patient’s face.
Figs. ISA—13E provide side, rear, interim and front views of still yet ment of a combined nasal and oral mask made in accordance with the present invention. In this embodiment the nasal and the oral chambers individually seal to the patient’s nose WWWWNNNNNNNNNthu—I—IH—‘Hr—p—nmt—WNHOOOOQONMAWNHOOOOVGMAWNt—‘O and mouth, respectively, and a seal between the nasal and oral chambers occurs at the proboscis — duck bill valve interface shown in Figs. 13A—19B. This allows the nasal and oral chambers to move relative to one another and still in a seal over the mouth and nose so long as the proboscis and duck bill valves remain engaged. Another benefit is that the oral and nasal chambers can translate and rotate about the X, Y and Z axes relative to each other due to flexibility of the proboscis — duck bill valve configuration, prior to being mated together. The proboscis tubes are inserted into the duck bill valves, opening them when the two chambers are engaged.
More particularly a full face ventilation mask consisting of an oral chamber and a nasal chamber is illustrated in Figs. l3A—l3F. The full mask provides gases to the t and removes waste gas through the ation port of the nasal r that is highlighted. This port attaches to a ventilation circuit that then attaches to an anesthesia machine. Gases can be exchanged from the patient’s nasal orifice and or to the oral orifice of the t in this ration.
The oral chamber portion of the mask is shown in Figs. 14A-l4C. The oral chamber consists of the chamber, “Y” a seal that surrounds the chamber opening and one or more proboscis tubes (two tubes are shown in this configuration). The r seal nds the mouth of the t, sealing the chamber to the patient’s mouth so that gas exchange through the mouth can only occur through the proboscis tubes as shown in Figs. 148 and 14C.
The nasal chamber portion of the mask shown in Figs. D consists of the nasal chamber, a “Y” seal that surrounds the perimeter of the chamber, one or more duck bill valves, an 02 port and a sealing cap over the 02 port. The seal of the nasal chamber surrounds the nose and with the duck bill valves closed, as is the case in this l configuration, gas exchange can only occur n the nose and the ventilation port, 2 being contained by the other elements of the r. 3 One or more self—closing valves, preferably in the form of duckbill valves are 4 integral to the nasal chamber as shown in Fig. 12C. When the nasal r and oral chamber are separated, the valves seal the nasal chamber, preventing flow out of the 6 valve orifices. Views of the duck bill valve separate from the chamber and integrated 7 into the chamber is shown in Figs. 16A—16B. When the proboscis of the oral chamber 8 proboscis tube is d with the duck bill valve located in the nasal chamber, the valve 9 is opened, allowing gas transfer between the nasal and oral chambers. A duck bill valve ted from the nasal chamber but placed on the oral chamber hollow cis tube 11 is shown in Fig. 17 to illustrate how the valve is opened when the proboscis tube is 12 engaged. 13 Figs. 18A-18B provides side and rear views of the nasal and oral chambers prior 14 to being engaged as a full face ventilation mask assembly. The proboscis tubes of the oral chamber are inserted into the duck bill valves of the nasal chamber, opening them 16 when the oral and nasal chambers are engaged. 17 When the nasal and oral chambers are engaged as illustrated in Figs. l9A—19C, 18 gas exchange between the two chambers can occur via the hollow proboscis tubes and 19 the open duck bill valves.
The embodiment shown in Figs. 13A-19B provides several advantages: 21 0 the nasal r when used by itself, seals over the nose, allowing gas 22 ge between the nasal cavity and a ventilation machine via a ventilation 23 P011; 24 0 the oral chamber seals over the mouth, ng gas exchange to the atmosphere or to the nasal chamber via the hollow proboscis tubes; 26 0 the engaged nasal and oral chambers separately seal the nose and mouth 27 respectively, and allow gas exchange between the two chambers via the proboscis 28 tubes and opened duck bill valve;. 29 0 the engaged nasal and oral chambers allow gas exchange via the ation port ofthe nasal chamber and the anesthesia machine; and 31 o the engaged nasal and oral chamber have an ability to move relative to each other 32 to better fit patients and seal around the nose and nasal chamber and mouth and 33 oral chamber respectively, due to the flexibility of the cis engaged with the WO 87995 l duck bill valve in translation or rotation about the X, Y and Z axes. 2 The mask of the present invention has numerous advantages over prior art masks. 3 These include: 4 0 it can be used as both a nasal and mouth anesthesia mask for bag~mask ventilation; 6 it can be used as a nasal mask alone for bag-mask ation. In such case, the 7 02 port 30 should be capped with the cap plug 36 in order to prevent gas from 8 exiting the 02 port. This same configuration of course could be used when the 9 nasal mask alone is connected to a ventilation machine; it can be used as both a full face nasal and mouth esia mask for the delivery 11 of anesthetic gases or for delivery of supplemental 02; 12 it can be used as a nasal mask alone for the delivery of anesthetic gases or for 13 delivery of supplemental 02; 14 it can be used for nasal CPAP or for full face mask CPAP; it can be used for nasal CPAP or for full face mask CPAP to relieve upper airway 16 obstruction due to the relaxation of upper airway soft tissue from intra-venous or 17 inhalation anesthetics; 18 it can be used for nasal CPAP or for full face mask CPAP to relieve upper airway 19 obstruction in patients with obstructive sleep apnea; it can be used to deliver oxygen and for ventilation during apneic periods (i.e., 21 ion of anesthesia and paralysis during induction of anesthesia) via nasal 22 mask without interfering with endotracheal intubation;. 23 it is transparent, at least in part, which enables the esiologist to visualize 24 condensation or aspiration; it has te but able and detachable nasal and mouth masks; 26 it is both an anesthesia nasal and mouth mask with a head strap that secures the 27 patient’s head and neck in position to maintain an open airway; 28 it is an anesthesia nasal mask with a head strap that secures the patient’s head and 29 neck in position to maintain an open airway; it is both an anesthesia nasal and mouth mask with a head strap that secures the 31 patient’s head and neck in position hands free; and 32 it is an anesthesia nasal mask with a head strap that secures the patient’s head and 33 neck in position hands free.
Qm-hWN—a Referring to Figures 20A-20E, to utilize the nasal portion of the mask for Continuous Positive Airway Pressure (CPAP), or to utilize the ation nasal and oral mask for full face mask CPAP, the ation port must be plugged or capped and pressurized oxygen must be supplied to the mask via the 02 port. Figure 20A shows the mask with the 02 port 30 capped by a cap plug 400 on the right; the cap plug is removed from the 02 port and the cap plug 400 is utilized to partially or completely plug the ventilation port 28 in Figures 20B and 20C. Referring in particular to Figs. 20D and 20E, the cap plug 400 es an interior recess 402 sized and shaped to fit snuggly over the 02 port 404. Cap 400 is attached to the mask by a tether 406. When mounted on the wwwwwNNNNNNNNNNHH—AHHHflfidflwa—‘oxoooqoxmAwN—‘oxoooqmmgww—l 02 port, the cap covers and seals the 02 port, preventing any gases from leaking out of the mask. Cap plug 400 has one or more generally V-shaped s 408 on a periphery wall of the cap plug 400. Grooves 408 ably vary in width, W(y) as a on Y as in Equation 1. This is one of multiple examples where the width varies as a function of Y. Conversely the depth D could vary as a function of Y. The area open between the nasal chamber and ambient atmosphere, A(Y) for each groove in the region between the valve and the ventilation port is determined by Equation 2 where: W(Y) = Wl-(Wl-W2)/L x Y Equation 1 A(Y) = W(Y) x D (per groove) Equation 2 For this arrangement rate of flow out of the ventilation port can be controlled by the amount the cap plug is inserted into the ventilation port as shown in Figure 20B. A pressurized 02 line is also attached to the 02 port 30 in the Figure 20B. The configuration shown in Figures 20B and 20C allows for the controlled application of CPAP. With the ventilation port capped, the nasal chamber remains pressurized, and gasses exit the system by having the patient exhale through the mouth.
Referring to Figures 21 and 22, there is illustrated a head strap device 20 which comprises a head bonnet 222, which comes in contact to the back of the patient’s head and one or more arm extensions 224, which contains both a proximal arm extension 226 with two ends and a distal arm extension 228 with two ends. The first end of the proximal arm extension 226 is attached to the head bonnet 222 and the second end of the al arm extension 228 is provided for attachment to a mask clip 230. The mask clip 230 allows the distal arm extension 228 of the head support head strap to attach and prevents the arm extensions 224, 226 from coming undone. The first end of the distal arm extension 228 attaches to the mask clip 230 alone to create a seal or can attach to both the mask clip 230 and a anchor clip 233 to secure the patient’s head to a surface 234 l such as the operating table or head support base, and prevent the patient’s head from WVQMQWN moving. The mask anchor clip 232 allows the distal arm extension 228 of the head strap to attach at a second point which reinforces it and r prevents the arm extension 228 from coming undone.
The mask clips 230, 232 have several functions. First they allow for a third ment for the distal arm extensions 228 of the head strap to prevent the distal arm extensions 228 from coming undone. A second function is to prevent a t’s head from moving side to side by securing the patient’s head to the head support surface 234.
When the distal arm extensions 228 of the head strap attach to the mask clips 232, it secures the patient’s head to the surface 234. 11 A third function of the mask anchor clip 232 is to prevent the patient’s head 12 and/or neck from moving away from the head support 234 or head support pillow 236 13 when the head and/or neck angles of the patient are adjusted. The distal end of the mask 14 arm extension 240 (Figure 23) attaches to a centered mask anchor clip 238 and acts as a posterior head strap that not only prevents the patient’s head from moving, but it also 16 maintains the t’s head on relative to the head support pillow 236 when the 17 head support angle is being d. The centered mask anchor clip 238 enables the 18 distal end of the centered mask anchor arm extension to attach and prevent the patient’s 19 head from moving both side to side and relative to the head support pillow 236 when the head support angle is changed. 21 In r embodiment the mask anchor head strap attaches to the mask anchor 22 ring 242, which can be placed over an aperture 244 of a mask and surrounds the aperture 23 244 of a mask, rather than attach directly to the clips built into the mask (Figures 24A 24 and 24B). The mask anchor ring consists oftwo sides, a first rigid base 246, which comes in contact and rests on the mask and a second rigid side, which has one or more 26 attachments (mask anchor spike cleats 248) for the head straps to attach to and create a 27 seal. 28 The mask ring has an advantage in that it can be used with different size masks. 29 Also, if desired, two or more straps may be placed on each side of the mask.
Referring now to Figures 25A and 25B, in yet another aspect of the present 31 invention provides a ation or anesthesia mask strap system designed to remain in 32 tension, maintaining the mask position on the patient by pulling the mask against the 33 face, while a patient is in the Sniff Position as illustrated in Figure 25A, and post 34 operation when the patient’s head is in a l or “vertical” position illustrated in GONOM-bwm—a Figure 25B. In order to maintain strap tension, the total strap elongation when placed on the patient must be greater than (Lsm'ff— LVemcai). The issue is that when Lsmrr is greater than Lyemcal and if the elongation is less than the difference, the strap will no longer be in tension.
An outer and top View of the strap, along with its major elements, are illustrated in Figures 26A and 26B. These elements include an able strap section 310, which has the ability to extend up to twice its length, or more, when a tension force is applied to the left and right end.
A first pandable strap section 312 is positioned on the left side of the patient with a hook surface on the strap outer side, away from the patient’s neck, and is 11 attached to the expandable strap on the outer or inner side of the expandable strap. A 12 second pandable strap section 314 is positioned on the right side of the patient 13 with a hook surface on the strap outer side, away from the patient’s neck, and is attached 14 to the expandable strap on the outer or inner side of the expandable strap. A first hook and loop adhesion patch 316 is positioned on the left side of the patient with loop surface 16 on the strap outer side, away from the patient’s neck that is attached to the expandable 17 strap on the outer most surface. A second hook and loop adhesion patch 318 is 18 positioned on the right side of the t with loop surface on the strap outer side, away 19 from the patient’s neck that is attached to the expandable strap on the outermost surface.
Alternatively, the loop and hook es could be reversed on the endable strap 21 sections and adhesion patch accordingly. Alternatively, the non—expandable strap 22 sections and the expandable strap section may be fixed to one another by an adhesive or 23 mechanically such as by buttons, staples, stitching, snaps, etc. 24 Figures 27A and 27B provide top and outer views of a strap attached to a ation mask in accordance with the present ion. The left and right non- 26 expandable strap sections 312, 314 are threaded h strap interfaces 320, 322 on the 27 left and right side respectively of the mask 324. The left and right non-expandable straps 28 312, 314 are attached to the respective left and right on patches 316, 318. The 29 surface of the non-expandable strap has a hook surface and the adhesion patch has a loop surface. The surfaces could be reversed where the non—expandable strap has the loop 31 surface and the adhesion patch the hook surface. 32 In use the mask 324 is placed over t’s nose and the strap is drawn around 33 the back of the neck as shown in Figure 25A. The left and right non—expandable straps 34 are pulled away from the patient’s neck, creating tension when the expandable strap 310 WO 87995 l extends or stretches due to the force applied by the anesthesiologist. They are then \OOOQONUI—BDJN inserted through the strap interfaces 320, 322 back towards the patient’s neck and ed to the hook & loop interface at the left and right adhesion s 316, 3] 8, respectively, creating strap loops 326, 328 as illustrated in Figure 27A. The tension, resulting from the extension of the expandable strap that acts as a spring, and retains the mask on the patient both in the sniff position, and in the natural or “vertical” position. ing to Figure 28, in an alternate application, the left and right non— expandable straps could attach to the loop surface of anchor patches which are part of a patient head support 332, or any other structure mounted to the operating room table. wwwuNNNNNNNNNN~H_#H—lH~—_fi WN—‘ODOONCNMQWNHOCOOflChM‘PWN—no This embodiment restrains the patient’s head to the operating room table.
Referring to Figures 29 and 30, in yet another ment, the mask comprises a combined nasal and mouth ventilation mask detachably connected to one another so that the nasal mask and the mouth mask may be used either separately as a nasal mask, or as a combination nasal—mouth mask as above described. In such embodiment the seals or membranes on both the nasal mask and the mouth mask preferably comprise lobc “Y”-shaped seals as above described. With this embodiment, the mask 350 is held on the patient with two (2) straps, one strap pair 352 attached to the nasal chamber 354, and a second strap pair 356 attached to the oral chamber 358. Strap pairs 352 and 356 are threaded through closed strap connectors 360, 362 and open strap tors 364 and 366 provided on the sides of the nasal and oral chambers 354 and 358, respectively. As described in tion with Figs. 26A and 26B, the retention straps ably include first expandable strap portions, and second and third non-expandable strap ns. In another ment (not shown) both strap connectors could be closed or both could be open. Adding strap connectors and retention straps to the oral chamber 358 as shown in Figure 29 permits one to e a better mask—to—face seal. Also, by providing separate and independently adjustable straps for the nasal chamber and the oral chamber, a better seal may be achieved. The resulting combination of a full face mask as above described with straps as above described, can provide a seal that supports a positive pressure greater than 20 cm H20 with attachment of the strap only, or with a nasal chamber held only by a strap can provide a seal that supports a positive pressure of greater than 30 cm l-le. And, a full face mask as above described can provide a seal that supports a positive pressure greater than 40 cm H20 with that clinician placing it over the patient’s face with the single hand, or with a nasal chamber only can e a seal that supports a positive l re greater than 40 cm H20 with that clinician placing it over the patient’s face with xmhww a single hand.
Various s may be made in the above invention without departing from the spirit and scope thereof. Referring to Figures E, a luer connector 420 may be integrated into the cap valve 400. With the luer connector 420 integrated into the cap valve 400, gases such as C02 being exhaled by a patient can occur when the ation mask is attached to a ventilation circuit via the ventilation port as shown in Figure 31A where the 02 port is capped but a gas monitoring line is attached to the luer connector 420. The C02 levels can also be monitored when an 02 line is connected to the mask via Nthb—lb—II—li—lh—i—lv—dD—‘Fl the 02 port in a CPAP or PEEP configuration as shown in Figure 31B. In this ~O\OOO\IO\LAJ>LNN’— configuration the gas monitoring line is ed to the luer connector integrated into the cap valve 400 which, in turn, is connected to a gas monitor. If the gas monitoring line is not connected to the luer connector, the luer connector can be capped by a cap 422, preventing gas from leaking through the associated port. Also, in place of hook and loop fasteners, the non—expandable straps may be threaded through a mechanical clasp such as a gripper of suspender-type no—slip clasp or grip; a button and buttonhole, snaps, a tab and belt hole clasp or the like. Still other changes are possible. For example, while the present invention has been described in connection with gas ventilation masks for use in delivering anesthesia, oxygen, etc. in medical settings, the combination nasal and mouth mask advantageously may be used, for example, for safety or gas masks or the like.
What is claimed: 1. A gas ation mask comprising a nasal mask and a mouth mask, the nasal mask defining a nasal chamber having a multi-lobed Y-shaped seal adapted to interface with a patient’s face, a ventilation port projecting from the nasal chamber in a first direction, and an oxygen port projecting from the nasal chamber in a second direction that is ent than the first direction, and the mouth mask defining an oral chamber, wherein the nasal and oral chambers are fluidly coupled to one another through a sealable passage, and the mouth mask is moveable ve to the nasal mask such that the gas ventilation mask can be used a combined nasal and mouth mask or as a nasal mask. 2. The gas ventilation mask as claimed in Claim 1, r comprising a mask strap anchor pair that has one closed side and an open side, or two open sides, for accommodating a strap, wherein the open side or sides are adapted to allow a care provider to attach the strap to a patient, wherein the open side or sides is/are oriented so that when strap tension force is applied, a force of the strap is resisted by a bottom portion of the respective mask strap anchor so that the strap does not slide off the mask strap . 3. The gas ventilation mask as claimed in Claim 1, wherein the oxygen port is offset to a side of the nasal chamber. 4. The gas ventilation mask as claimed in Claim 1, wherein the ventilation port and the oxygen port are offset to a side of the nasal chamber.
. The gas ventilation mask as claimed in Claim 1, wherein the ventilation port is configured to fluidly d with an anesthesia circuit. 6. The gas ventilation mask as claimed in Claim 1, wherein the nasal mask is formed at least in part of a transparent material to permit visualization of sation or aspiration. 7. The gas ventilation mask as claimed in Claim 1, wherein the nasal mask comprises an opening fluidly coupled to the passage, wherein the at least one opening preferably is adapted to be proximate an upper lip of a patient in use. 8. The gas ation mask as claimed in Claim 1, wherein the multi-lobed Y- shaped seal surrounds a periphery of the nasal mask. 9. The gas ventilation mask as d in Claim 1, wherein the multi-lobed Y- shaped seal comprises a base portion d to the nasal mask.
. The gas ventilation mask as claimed in Claim 1, n the multi-lobed Y- shaped seal is configured such that, when a tension force (FTension) of a mask strap is applied, the multi-lobed Y-shaped seal is compressed. 11. The gas ventilation mask as claimed in Claim 10, n the multi-lobed Y- shaped seal comprises a cantilever portion configured to provide a spring stiffness (KSeal) that is approximately equal to two times the tension force (FTension). 12. The gas ventilation mask as claimed in Claim 1, wherein, when a differential pressure is applied to the nasal chamber, an interior arm of the multi-lobed Y-shaped seal resists movement of a gas out of the nasal r. 13. A treatment apparatus comprising: a generator for the supply of gas at a pressure elevated above atmospheric pressure; a gas ry conduit coupled to said generator; and a gas ventilation mask as claimed in Claim 1, coupled to said conduit. 1.8 Snap Cap Retainer Gases flow thr0« a h the Oral Port, c nnectlng the Nasal and Oral amb Oral Chamber Figure 2A Alternate Nasal/Oral Port Proboscis Tapered to seat and seal in Nasal/Oral Port When en aged with Nasal hamber Figure 3 Duck Bill Valve Figure 28 Figure 2C Duck Bill Valve ¢ In closed osition on Nasal hamber WO 87995 Proboscis Tu be Duck Bill Valve Opened b); Proboscis ube Oral Chamber Figure 2E WO 87995 1.7 Snap Cap 1.8 nap ap Retainer Example ofa Snap Cap with a hinged Retainer Figure 4A Seal Cap Closes n port with a friction t Removed when por_t connects to Oxygen line 1.2 Oxygen Port Cap Figure 5 ~ Anesthesia t/ chamber resuscrtator bag Supplemental oxygen port chamber Figure 6 Alternate. C Alternate 82 Ventilator Circuit Strai ht Ventilator Port Elbow Ircuit Port Connected to Nasal Chamber 1.1 Ventilator Circuit Port Figure 7 mem5694 to; :800.03 mtoa mm>_m> m> L—wQEmSU :Exuso um $32 EQEEU, EQEEU _GLO 53> 5suc< :20 2%: to; ambm ’H 5995 880 063 95cwnc.
EQEEU 95? Emmfiwhu $3 EEO 62:90 Emm K$32 EQEEU \I/ 2:9”.
EQEEU £300.05 WO 87995 Emmmm E $32 co 7:0 8%: v: 41%, memNNF $038.25 :25me mm $05 95m: fimfiw \‘.lr.
Y Seal 104 PVentiIation Ftension Local I X Coordinate Figure :1A Figure 118 /30 a ad E32 .3895 m59< Ll,Emm 59:95 .90 2:? EQEEU COEUGW Emmz mmOLU IIIII //W/_mmmEQEo U $5.. 89.558 Eggm .mmm© h x <§ Em: —_m:v_ _o 95m: ufi mmmmBEouc > 2:? 3 WO 87995 1 1/30 Rear View Side View Nasal Figure 13A. Chambers Duck Bill Valves Duck Bill Valves Figure 138 Proboscis Oral Seal Proboscis Tubes Duck Bill Valves Opened Gas Flow To / From Nasal Chamber & Oral Chamber Via Proboscis Tubes & Open Duck Valves Figure 13E Figure 13D 12/30 Side View ation Nasal Chamber Chamber Front View Flgure 13F. Ventilation Cap ed 02 ort Strap Connector Strap Con necto Oral Chamber Figure 136 13/30 Side View Rear View Proboscis Tubes Chamber Figure 14C Gas Flow To/From Nasal Chamber & Oral Chamber Via Proboscis Tubes & Open Duck Valves 1 4/30 Figure 15A Figure 153 Side View Rear View Ventilation Port Capped 02 Port Nasal Duck Bill rs Valves Opened Nasal Chamber Duck Bill va'ves Figure 15C Figure 15D WO 87995 /30 Duck Bill Valve @ C@ Figure 16A Figure 168 Duck BillValve _ In closed OSItIon on Nasal hamber Figure 16C Proboscis Tu be Duck Bill Valve Opened b}; Proboscis ube Oral ChamberN Figure 17 1 6/30 Nasal Side View Rear View Chambers Seal Duck Bill Valves Duck Bl” Valves Figure 18A Figure 188 Figure 19A RearView Duck Bill Nasal Chamber Rear View Valves Opened Figure 198 amber r ._ W Ora Chamber Proboscjs /\’\ Tube Opeings Gas Flow To/From Nasal Chamber & Oral Chamber Via Proboscis Tubes & Open Duck Valves Figure 19C 17/30 m>_m> Q8WEmmSEcomecm> mom 86% 00¢ Q8 NO EQEEU cowmficg tom n 8%: w>_m> NO Qmu mc2m>out0n_ Cap Valve, Ventilation Port Partially Open Figure 20C Cap Valve 400 Bottom View Figure 20D 408 Cross n) ofventilation Port 19/30 Proximal end of the Centered Mark Anchor Arm extension ' If“.
Distal end ofthe Left Mask ‘ «7—» Anchor Arm ion 228 Proximal end of the 77 Right Mask Anchor Arm ——>, extension 226 Mask Anchor head support base 222 Figure 21: Mask Anchor head strap /30 2nd clip anchor 232 Distal Mark Anchor Arm extension Proximal Mark Anchor arm extension 236\ Figure 22: Mask Anchor head strap attaching to both clips & Mask Anchor clips 21/30 The Distal End of the Centered Mask Anchor arm extension 240 Centered Mask Anchor Clip 238 Figure 23: The distal end of the ed Mask Anchor Arm extension maintaining head/neck positioning while head/neck angles are changed WO 87995 22/30 Mask Anchor ring Mask Anchor spike cleat 248 Figure 24A: Mask Anchor ring Mask Anchor ring with spike cleats Mask anchor head strap arm extenSIon Figure 248: Mask Anchor ring with spike cleats around a mask 23/30 Sniff Position al Position Figure 25A Figure 258 24/30 Hook Surface 1) Expandable Strap Hook Surface 312 Loop 310 Loop 314 Surface 3L) on Adhesian Patch Patch Figure 26A Patient’s Back—of—Neck Cross~Section Nonexpandable Strap____.______Nonexpandable Strap Hook Surface Hook Surface Loop Strap Loop Surface Surface Aduesron Patch Figure 268 /30 Stra32g, oo Strap Interface 320, 322 _...., Mask, 324 Figure 27C a A- - m W Nonexnan a 4 StraTo,312 WO 87995 26/30 Nonexpandable Strap attaches to Anchor Patch Anchor Patch Figure 28 27/30 Closed Strap tor Ogipalgolo Connector 28/30 Retention Strap attached to Nasal Chamber Retention Strap attached to Ora! Chamber Figure 30A ”“ ‘\\\ Retention Strap ed to Nasal Chamber Retention Strap attached to Oral Chamber Figure 308 29/30 Ventilation Circuit Monitoring Line. Attached to Ventilation Port 422 Gas Monitor ation 02 Port Capped when Ventilation Port Plugged Attached to Ventilation when Attached to 02 chwt Supply Line Figure 31A Figure 313 WO 87995 /30 Figure 31C Figure 31D Figure 31E
NZ764985A 2014-06-04 2015-06-04 Combined nasal and mouth ventilation mask NZ764985A (en)

Applications Claiming Priority (12)

Application Number Priority Date Filing Date Title
US201462007802P 2014-06-04 2014-06-04
US201462056293P 2014-09-26 2014-09-26
US201462060417P 2014-10-06 2014-10-06
US201462061045P 2014-10-07 2014-10-07
US201462065504P 2014-10-17 2014-10-17
US201462091370P 2014-12-12 2014-12-12
US201562118301P 2015-02-19 2015-02-19
US201514690223A 2015-04-17 2015-04-17
US201562149313P 2015-04-17 2015-04-17
US201562161086P 2015-05-13 2015-05-13
US201562161093P 2015-05-13 2015-05-13
NZ72664615 2015-06-04

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