Source: https://patents.google.com/patent/DE102009047246A1/en
Timestamp: 2019-12-08 21:07:10
Document Index: 685467727

Matched Legal Cases: ['art.\n6', 'art 6', 'art 32', 'art 32', 'art 35', 'art 35', 'art 35', 'art 35', 'art 35', 'art 32', 'art 35', 'art 35', 'art 32', 'art 35', 'art 32', 'art 32', 'art 32', 'art 32', 'art 32', 'art 35', 'art 32', 'art 35', 'art 32', 'art 32', 'art 32', 'art 35', 'art 35', 'art 32', 'art 32', 'art 35', 'art 32', 'art 35', 'art 35', 'art 32', 'art 35', 'art 32', 'art 32', 'art 32', 'art 32', 'art 32', 'art 35', 'art 32', 'art 35', 'art 32', 'art 32', 'art 32', 'art 32', 'art 32', 'art 35', 'art 32']

DE102009047246A1 - Nasal cannula - Google Patents
DE102009047246A1
DE102009047246A1 DE102009047246A DE102009047246A DE102009047246A1 DE 102009047246 A1 DE102009047246 A1 DE 102009047246A1 DE 102009047246 A DE102009047246 A DE 102009047246A DE 102009047246 A DE102009047246 A DE 102009047246A DE 102009047246 A1 DE102009047246 A1 DE 102009047246A1
DE102009047246A
Nicholas Alexander Hobson
Steven Charles Korner
2008-12-01 Priority to US11875008P priority Critical
2008-12-01 Priority to US61/118,750 priority
2009-11-27 Application filed by Fisher and Paykel Healthcare Ltd filed Critical Fisher and Paykel Healthcare Ltd
2010-06-10 Publication of DE102009047246A1 publication Critical patent/DE102009047246A1/en
A nasal cannula assembly for use as part of systems for delivering respiratory gases to a patient is disclosed. The nasal cannula assembly has a manifold portion that can receive gases from a delivery conduit. The manifold has a nose port, and preferably a pair of nose ports, which extend upwardly and bend toward the rear of the manifold. The nasal ports are inserted into the nostrils of the patient and deliver gases to a patient. The nasal connections have a cutout on the back of the nasal connections. The cutout forms a gas outlet in the nasal ports and is shaped so that the area of the cutout is larger than the cross-sectional area of the nasal ports at the entry point to the nasal ports.
The The present invention relates to nasal cannula assemblies for supplying gases to a user the nasal passages. The present invention also relates a system that sends gases to a patient or user feeding the nasal passages. The present invention also relates to a method for supplying gases to a User via the nasal passages.
Of the The prior art includes a wide variety of interfaces for supplying gases to a patient. These interfaces are often used to deliver a gas stream to a person who because of a sleep disorder, or for delivery of supplemental gases to a user without support can breathe but needs these supplemental gases used. These users usually carry the interface in an intensive care unit of a hospital, in other hospital departments or in your own bedroom at home. An important consideration is that the interface is comfortable to wear, even if the Patient moves.
The following examples are interfaces that are known in the art are known.
Of the The prior art includes a nasal cannula interface. A typical nasal cannula interface contains a plenum section and an inlet hose or manifold section (symmetrical or one-sided), which in use on the upper lip of the User, as well as a pair of nasal prongs with open ends protruding from the inlet tube and in the Into the nostrils of the user, to supply the patient with gases. In general, but not always, these nasal connections have such a size and shape on that they are the nostrils of a patient do not seal. Nasal cannulae are used because they are beneficial in certain situations. For example it is used when a patient is breathing normally but supplementary Gases, such. B. supplementary oxygen needed. The existing market for nasal cannulas is with Devices for dispensing gases in the range of 0 to 5 liters per Minute well served. These devices are usually made by a double inlet lumen with a small diameter (in the range 2-3 mm) supports both sides of the nasal cannula supplied and for even or the same Air flow to each nasal connection ensures. These devices are suitable good for dispensing dry gas flows with a Rate from 0 to 5 liters per minute when the patient is breathing himself and not sealing the nasal ports of the cannula must be present at the nostrils of a user. One User withdraws the supplemental gases from the cannula during normal inhalation together with the outside air.
One Example of a nasal cannula incision surface sealing against the nostrils, is the interface Nasal Aire from Innomed, where the interface and the nasal connections via leads or hoses that spread from the user's nose his cheeks, over his ears and around the back of his head, Gases are supplied.
WO 2008/060295 describes a nonsmoking nasal cannula. Many configurations are described. The nasal ports may deliver air into the nasal passage of a patient, and the various embodiments of the described nasal ports include different external features, and may also include passages that pass through the wall of the nasal ports for sensors or similar devices to measure the properties of the gases in the nasal ports can.
Of the The prior art also includes several other types of interfaces, which are included here in the general context, but not directly are relevant. They are briefly described below.
A nasal mask with a perimeter seal that seals against the cheeks and down along the nose and along the surface of the upper lip. The entire closed space is under pressure and the receiver can breathe the compressed gas out of the enclosed space. An example is the Flexifit 405 Nose mask by Fisher & Paykel Healthcare.
A full face mask with a perimeter seal that extends down the nasal bridge down each cheek next to the nose to the jaw and along the jaw under the lower lip. The circumference encloses nose and mouth. The entire space in the mask frame is under pressure. The receiver can breathe the pressurized gas out of the room through the nose or mouth. An example is the Flexifit 431 Interface from Fisher & Paykel Healthcare.
A oral interface with an oral device in the mouth of the user fits. An example is the Oracle interface of Fisher & Paykel Healthcare.
Nasal pillows which in use are intended to sealingly engage the circumference of the nostrils of a user and deliver a stream of pressurized gases to the nasal cavity of a user. A number of different types of nasal pillows are in WO 2008/014543 described and shown.
references in this patent specification patents, other external documents or other sources of information generally serve the purpose the provision of a meaning context for discussion the features of the invention. Unless specifically something else is not a reference to such external documents to accept as concession that these documents or these Sources of information under any jurisdiction to the state The technique belongs to or is part of the usual general Level of knowledge.
task the present invention provides a nose cutting surface, the disadvantages of the prior art to some extent Overcomes degrees or those of industry and the public at least one useful alternative.
Of the Term "comprising" as in this specification used means "at least partially composed of". In interpreting any statement in this specification which covers the Term "comprising" can other characteristics than those specified by the term, available. Related terms such as "include" and "includes" are on to interpret the same way.
In a first aspect, the invention broadly comprises a nasal cannula assembly for use as part of a system for delivering breathing gas to a patient, the system having a gas source which in use directs a flow of gas to the nostrils of a user and a delivery conduit in use, connecting the gas source to the nasal cannula assembly, the nasal cannula assembly comprising:
a gas inlet manifold portion that in use can establish fluid communication with the exhaust conduit so that the gas stream is directed into the manifold portion;
at least one nasal port, and preferably a pair of nasal ports, in fluid communication with the gas inlet manifold portion which is inserted into the nostrils of the user, the gas stream flowing through the gas inlet manifold portion and the nasal ports;
wherein the nasal port or the nasal ports have a gas outlet cut-out on its rear side, wherein the gas outlet cut-out has a cross-sectional area which is greater than the cross-sectional area of the nasal port at or near the entry point of the gases into the nasal port the nasal connections.
In a second aspect, the invention roughly consists of a system for delivering respiratory gases to a patient, the system comprising:
a gas source unit that can provide a gas flow,
a discharge conduit, which may also include a secondary gas inlet conduit, which may receive respiratory gases from the gas source and guide respiratory gases from the gas source to the patient interface, and
a nasal cannula assembly comprising:
In a third aspect, the invention broadly comprises a nasal cannula assembly for use as part of a system for delivering breathing gas to a patient, the system having a gas source capable of providing a gas flow and a delivery conduit which, in use, communicates with the gas source The nasal cannula assembly connects, wherein the nasal cannula assembly comprises:
a manifold portion connected to one end of the exhaust duct so that the gas stream is guided from the exhaust duct to the manifold portion in use,
a pair of transport hoses connected to the manifold section such that the gas flow is conducted from the manifold section to the hoses;
a pair of nasal ports, each connected to a carrier tube, wherein the nasal ports can be inserted into the nostrils of a patient, wherein the gas flow through the Transport hoses, the nasal connections and flows into the nostrils of the patient,
wherein each nasal port has a rear gas outlet cut-out, the gas outlet cut-out having a cross-sectional area greater than the cross-sectional area of the nasal port at or near the entry point of the gases into the nasal ports.
In a fourth aspect, the invention broadly consists of a nasal cannula assembly for use as part of a system for delivering breathing gas to a patient, the system having a gas source capable of delivering a gas flow to the nostrils of a user in use, and a delivery conduit. in use, connecting the gas source to the nasal cannula assembly, the nasal cannula assembly comprising:
at least one nasal port, and preferably a pair of nasal ports, in fluid communication with the gas inlet manifold portion which is inserted into the user's nostrils in use, the gas stream in use flowing through the gas inlet manifold portion and nasal ports and into the user's nostrils .
wherein each of the nasal ports or both nasal ports has a gas outlet cut-out on its rear side, the gas outlet cut-out having a cross-sectional area greater than the cross-sectional area of the nasal port at or near the entry point of the gases into the nasal port the nasal ports, and wherein the at least one nasal port or both nasal ports are shaped such that the velocity of the gases exiting the nasal port is reduced compared to the velocity of the gases at or near the entry point into the nasal port ,
In a fifth aspect, the invention broadly consists of a nasal cannula assembly for use as part of a system for delivering breathing gas to a patient, the system having a gas source capable of delivering a gas flow to the nostrils of a user in use and a delivery conduit. in use, connecting the gas source to the nasal cannula assembly, the nasal cannula assembly comprising:
wherein each of the nasal ports or both nasal ports has a gas outlet cut-out on its rear side, the gas outlet cut-out having a cross-sectional area greater than the cross-sectional area of the nasal port at or near the entry point of the gases into the nasal port the nasal ports, and wherein the at least one nasal port or both nasal ports are shaped or sized to direct the gas flow generally toward the back of the nasal passageway of the patient.
In a sixth aspect, the invention broadly consists of a method of providing a gas stream to a user for therapeutic purposes comprising the steps of:
1. attaching a nasal cannula assembly to the user,
2. connecting the nasal cannula assembly to a patient interface that, in use, holds the nasal cannula assembly in position on the user,
3. Connecting the patient interface, or alternatively, connecting the nasal cannula assembly directly to a gas delivery system having a gas source capable of providing gas flow and a delivery conduit connecting the gas source to the nasal cannula assembly in use, and using the system to deliver gas flow to the nasal cannula assembly wherein the nasal cannula assembly comprises: a gas inlet manifold member adapted to fluidly communicate with the delivery conduit so as to direct the gas stream into the manifold member, at least one nasal port, and preferably a pair of nasal ports in fluid communication with the gas inlet manifold member be introduced into the nostrils of the user, wherein the gas flow through the gas inlet manifold part and the nose ports flows, wherein the nose port or the nose ports a gas outlet cutout on his or her Rear side having or having, wherein the gas outlet cutout has a cross-sectional area which is greater than the cross-sectional area of the nasal connection at or near the entry point of the gases into the nasal port or into the nasal ports.
In a seventh aspect, the invention broadly consists of a nasal cannula assembly for use as part of a system for delivering breathing gas to a patient, the system having a gas source capable of delivering a gas flow to the nostrils of a user in use, and a delivery conduit. in use, connecting the gas source to the nasal cannula assembly, the nasal cannula assembly comprising:
at least one nasal port, and preferably a pair of nasal ports, in fluid communication with the gas inlet manifold portion which is inserted into the user's nostrils in use, the gas stream flowing through the gas inlet manifold portion and the nasal ports and into the user's nostrils,
wherein each of the nasal ports or both nasal ports has a gas outlet cut-out on its rear side, the gas outlet cut-out having a cross-sectional area greater than the cross-sectional area of the nasal port at or near the entry point of the gases into the nasal port the nasal ports, and wherein the at least one nasal port or both nasal ports are shaped such that the velocity of the gases exiting the nasal port is reduced compared to the velocity of the gases at or near the entry point into the nasal port , and so that the gas flow is generally directed to the back of the nasal passageway of the patient.
Preferably the cannula assembly has a facial attachment portion which rests on the face of the user in use, wherein the Facial attachment has a pair of side straps that are extend from the face attachment part.
Preferably The face attachment part stabilizes the cannula assembly in use on the user's face, by the face of the user User is present.
Preferably the cut-out extends over half up to two-thirds of the distance on the nasal connection, whereby the Clipping is measured from the upper tip of the nasal connection.
alternative The section extends over less than half the section on the nasal connection, the section of the upper nasal tip is measured from.
alternative The neckline extends over the entire length the nasal connections.
Preferably the cut-out has a height between 3 mm and 15 mm on.
Preferably is the gas outlet cut-out from the back of the nasal cannula assembly seen oval.
alternative is the gas outlet cut-out from the back of the nasal cannula assembly seen rectangular.
alternative is the gas outlet cut-out from the back of the nasal cannula assembly seen triangular.
Preferably the nasal connections are between 5 to 20 degrees inside relative to a vertical planar line containing the face-fixing part cuts, angled.
Preferably the nasal connections are 15 degrees inwards relative to a vertical planar line, which is the face attachment part cuts, angled.
Preferably correspond to the edges of the gas outlet cut a Surface having a substantially inverted S-shape, wherein the S-shape is oriented substantially vertically.
Preferably cuts the bottom edge of the surface over the Back of the nose noses, around this neckline with the surface being an inverted S-shape, to get the ideal cut-out shape.
Preferably the at least one nasal connection has an amplification feature on.
Preferably is the gain feature on the front of the nasal connection and can prevent the nasal connection collapsed under compression or tensile forces.
Preferably For example, the gain feature is substantially vertical Burr or shaped as a spine, at least partially over the front of the nasal connection runs.
Alternatively, the at least one nosepiece has a reinforcing feature on the inside on the front wall of the nasal port to prevent the nasal port from collapsing under tensile or compressive forces.
Preferably the at least one nasal connection has at least one and preferably a variety of ribs on the front of the nasal connection run.
Preferably the at least one rib or the ribs over the outer front of the nasal connection.
Preferably the front part of the wall of the nasal port is thicker than the rear part of the wall of the nasal connection.
Preferably is the feature or are the ribs or both in one piece shaped with the nasal connection.
alternative becomes the feature or the ribs or both separately at the nasal connection attached after its formation.
Preferably the nasal cannula assembly further has side straps, with which a head-mounted fixation assembly with the nasal cannula assembly can be connected so that the nasal cannula assembly can be fixed in the patient's head during use.
Preferably There is the face attachment part, the at least one nasal connection and at least part of the side straps made of a flexible polymer material, for example, a thermoplastic elastomer or silicone.
Preferably is the feature or are the ribs or both made up of the same Material or consist of the nasal connection.
Preferably has at least one nasal connection or have both nasal connections such a shape or size or shape and size on that the gas stream generally to the back of the Nasal passage of the patient.
Preferably is at least one nasal connection or are both nasal connections shaped so that the speed of the nasal connection escaping gas compared to the velocity of the gases at or near the entry point of the nasal connection is reduced.
Preferably is at least one nasal connection or are both nasal connections bent in use up and back to a user and the cutout has an elongated shape along the Back and top of nasal connection or nasal connections so that the gas flow is generally towards the back of the Nasal passage of the patient is passed and beam-forming effects be reduced.
Preferably The nasal connections have such a shape and size in that they do not use a substantially airtight seal in use Make with the nostrils of the user.
Preferably The nasal connections are suitable for the delivery of medical High flow rate gases to a patient; so that a significant part of the patient's inhalation of respiratory gases from the nasal connections and only a minimal part Room air exists.
Preferably the distributor section is a Y or T connector.
Preferably the nasal connections are integral with the carrier line shaped.
These Roughly speaking, the invention also consists of the parts, elements and Features referenced in the specification of the application or listed there, individually or together, and from all combinations of two or more arbitrary parts, Elements or features, and if certain sizes mentioned herein for which it is in the state of Technique known equivalents exist, to which this invention refer to these known equivalents as herein recorded as if they were individually performed.
While the invention occur in different embodiments can, in the drawings, certain embodiments shown and described in detail. The present disclosure is an example of the principles of the invention to watch; it is intended to illustrate the invention as herein and not limited.
1 FIG. 5 shows a respiratory humidification system including a blower unit, a humidifier unit in gas communication with a gas source unit, a gas supply line connected to an outlet of the humidifier unit, and a patient interface, the patient interface Gas supply line connects to a user, so that the user gases can be supplied from a respiratory humidification system via the patient interface, wherein the patient interface comprises a nasal cannula.
2 10 shows a perspective view of the preferred embodiment of the patient interface in use on a user, with the preferred form of patient interface having a secondary supply line connecting the outlet end of the gas supply line to the nasal cannula, and a collar or loop looping around the neck in use a patient extends and is connected to the delivery conduit at or near the outlet end to receive the weight of the delivery conduit in use, the patient interface also having a head strap for securing the patient interface to the patient's head in use.
3 Figure 11 shows a front view and a side view of an alternative embodiment of the patient interface in use, this alternative form having a pair of ear straps which in use loop around the ears of a user in use to hold the patient interface in use on the face of a user.
4 Figure 11 is a perspective view of the front and one side of the most preferred form of nasal cannula, with the nasal cannula of the preferred form having a face mount portion and a manifold portion, the manifold portion being removable from the face mount portion with the secondary supply line connected to the manifold portion.
5 shows the patient interface 4 , wherein the distributor part is removed from the face-fixing part.
6 Figure 11 is a perspective view of the front and one side of the preferred form of the face-mounting portion of the preferred form of nasal cannula, wherein the face-mounting portion includes a portion that can receive the manifold portion and a pair of nasal terminals that extend from the face-mount portion.
7 Figure 11 is a perspective view from the back and to one side of the preferred form of the face-mounting portion of the nasal cannula, the face-mounting portion having a pair of nasal ports extending from the face-mounting portion, each nasal port having a gas exit cut-out on the back at the top of the nasal port.
8th shows a view directly from the back of the distributor part 6 , wherein the gas outlet cutout is clearly shown.
9 FIG. 11 shows a top view of the preferred shape of the face-mounting portion of the preferred form of nasal cannula, the view being the preferred inward angle of the nose-ports relative to a vertical plane intersecting the face-mounting portion and the preferred orientation of a surface surrounding the circumference of the cut-out in the preferred form defined, shows.
10 Figure 11 shows a rear perspective view of the nasal cannula of the preferred embodiment, the view showing the preferred shape and placement of the surface.
11 shows a view from below the nasal cannula of the preferred embodiment.
12 Figure 10 shows another embodiment of the nasal cannula, the cannula having a manifold with two transport tubes extending from the manifold and running in loops around the ears of the user, and a nose port connected to the end of each carrier tube.
13 shows an alternative embodiment of the nasal cannula, in which the transport hoses extend from the manifold, the transport hoses are connected to the face-fixing part and the nasal connections extend from the face-fixing part.
A preferred form of nasal cannula assembly is described below with respect to its use as part of a patient interface for use in a medical gas system. It should be noted that the nasal cannula assembly may be used with any suitable system which, in use, provides a flow of gas from a gas source to a patient. For example, it could be used as part of a system that supplies supplemental oxygen to a user, with the oxygen being provided by a source, such as a gas bottle or wall outlet. Most, however, it is suitable for a system that supplies a heated humidified gas flow to a patient or user. The nasal cannula is suitable for use at home or in a hospital environment. The nasal cannula may have different sizes (the proportions generally remain the same) so that it can be used by users of different sizes. For example, two (or more) various sizes for adults and infants are made, which would still fall within the scope of the present invention.
In 1 For example, a breathing humidification system as might be used with a first preferred embodiment of the nasal cannula assembly is shown. A patient or user 1 receives a humidified gas flow through a patient interface 20 comprising the nasal cannula assembly and described in detail below. The patient interface 20 is with a discharge line 3 connected, with the discharge line 3 a humidifier unit 2 with the patient interface 20 combines. The humidifier unit 2 consists of a humidification chamber 5 in use, a volume of water 6 contains, and a base unit 8th , The preferred embodiment of the humidification chamber 5 is made of plastic and, in the preferred embodiment, includes a conductive bottom (e.g., aluminum) directly connected to a heating plate 7 the humidifier base unit 8th is in contact. The humidifier base unit 8th is in the preferred embodiment with a control mechanism or electronic controller 9 which includes a microprocessor-based controller that executes computer software instructions stored in the controller.
In the preferred form as in 1 shown is the humidifier 2 Gases from a gas source unit 15 where the gases are heated and moistened when passing through the chamber 5 flow. It should be noted that the gas source unit 15 as mentioned above could also be replaced or supplemented by a wall connection or a gas cylinder. The gas source unit could be a gas bottle, a gas mixer, a Venturi device or a standard blower unit, or any other suitable system or device that supplies a gas flow. Humidified gases flow from the humidifier 2 through the delivery line 3 via the patient interface 20 to the patient.
It It should be noted that with the nasal cannula system used no humidifier must be used - the means the gas stream could be dry if needed and not be warmed up. By using the nasal cannula Different types of therapy can be administered. The preferred form of therapy will be described later. in the Generally, the nasal cannula allows breathing gases and the respiratory gas delivery system. The one described here Respiratory humidification is just one example of the type of therapy and system, with or as part of which the nasal cannula are used can.
The regulator 9 receives inputs from sources such as user input via a dial 10 by which a user of the device, for example, a predetermined required humidity or temperature value for the patient 1 can adjust supplied gases. In response to the input of the user or to the input of other possible input sources such. As sensors (for example, temperature or humidity sensors, which are not shown), determines the controller 9 , when and at what level the hotplate 7 must be energized so that the water 6 in the humidification chamber 5 can be heated. When heating the volume of water 6 in the humidification chamber 5 Water vapor starts the residual volume of the humidification chamber 5 to fill. The humidifier unit 2 from the blower unit 15 supplied gases pass over the surface of the water 6 into the humidification chamber 5 and are humidified by the water vapor in the humidification chamber while passing through the chamber 5 stream. The heated humidified gases pass through an outlet 4 from the humidification chamber 5 off and off the delivery line 3 to the patient interface 20 directed.
The preferred form of blower 15 is with a variable speed pump or a fan 12 provide air or other gases through a blower inlet 17 draws. The speed of the pump or fan 12 is in the preferred embodiment of another control device 18 regulated. Alternatively, the control of the pump or fan speed can also be controlled by the controller 9 respectively. The fan controller 18 can also be inputs from sensors in the system or a user input via a control panel or a control unit 19 receive. As mentioned above, the blower unit 15 by a gas source such. B. a gas cylinder or a wall connection, which is connected to a central gas source, supplemented or replaced.
The preferred form of discharge line 3 contains a heating element 11 to prevent condensation of the humidified gases in the pipe 3 ( 'Rainout').
The preferred form of moisturizing system has been described above with the nasal cannula described being part of the patient interface 20 is. The nasal cannula will now be described in detail with particular reference to 2 to 5 described.
2 shows the first embodiment of the patient interface 20 out 1 in more detail. The patient interface 20 roughly consists of one Head fixation mechanism and a nasal cannula assembly 30 and also includes a gas inlet line or secondary feed line 62 , The head fixation mechanism allows the user to customize the nasal cannula assembly 30 in the correct operating position to place and hold. The gas inlet line or secondary feed line 62 forms a liquid or gas connection between the outlet end of the main discharge line 3 and the nasal cannula assembly 30 to allow liquids or gases to flow between the main discharge line and the nasal cannula assembly. The secondary supply line 62 and a detail of the main portion of the nasal cannula assembly 30 are described in detail below.
The preferred and alternative forms of the head fixation mechanism that are part of the patient interface 20 form with special reference to 2 and 3 described. 2 shows the preferred form of the head fixing mechanism while 3 an alternative embodiment of the head fixing mechanism shows.
In the preferred embodiment, the patient interface becomes 20 through a front strap 50 and rear and upper straps 53a and 53b , in the 2 can be seen attached to the head or face of the user. The front strap 50 is in use with the nasal cannula assembly 30 connected while the rear strap 53a and the upper strap 53b with the front strap 50 , are connected, with the rear strap 53a in use, wrapped around the top and back of the patient's head. The most preferred form of the headgear device is adjustable to allow patients of different sizes and head shapes to choose the nasal cannula assembly 30 can use. For example, could an adjustment buckle 54 be included with the patient's headgear 53 loose or can attract.
Alternatively, the patient interface is through a front strap 50 and a single rear strap 53a , the front strap 50 attached to the patient's head or face. The rear strap can be over a buckle 54 with the front strap 50 be connected or the rear strap 53a may alternatively be integral with the front strap 50 be shaped. With the buckle 54 The patient may loosen or tighten the side straps to sit comfortably. Alternatively, the one-piece front and rear straps are elastic and can be stretched over the head of a patient. The elasticity of the straps exerts a force on the head to keep the nose cutting surface in the optimum position during use. Elastic side straps 50 . 53a can with the adjustment buckle 54 be used or the elastic side straps 50 . 53a can alone without a buckle 54 be used.
The headgear assembly can also be a loop 55 contain the secondary supply line 62 at the inlet end (described in detail below) or in its vicinity and supports.
A collar or a bow 63 can also work with the patient interface 20 be provided. 2 shows an example of a collar or loop 63 , In the preferred embodiment, the collar is the loop 63 at or near the junction between the delivery line 3 and the gas delivery line 62 with the gas inlet line 62 connected and supports the weight of the delivery line 3 and the gas inlet pipe 62 in use. A rocker arm 64 is with the collar 63 provided to adjust the length of the collar. The rocker arm 64 ensures that the collar 63 for patients of any size with the patient interface 20 can be used. The collar 63 supports the weight of the delivery line 3 in use, so that the weight is not on the user's face or on the nasal cannula assembly 30 rests. The use of the collar 63 prevents the combined weight of the delivery line 3 and the gas inlet pipe 62 at the nasal cannula assembly 30 pulls and prevents so that the nose connections 33 . 34 hurt the sensitive mucosa of the nasal passages or slip in use. The preferred embodiment of the collar or loop 63 sits loosely around your neck so that the user is not strangled. The bow 63 Also provides a convenient way of supporting the delivery line 3 and the gas inlet pipe 62 , This allows the patient to turn in bed without being on the line 3 to tug or rip them out and the gas inlet pipe 62 can not overheat under the blankets. In the most preferred embodiment, the collar or loop has 63 a clip that allows the loop to be opened and closed by a user around the collar 63 around the neck of the user to lay and fix. The clip has latching male and female fasteners. The clip is made by pulling on one end of the necklace 63 away. The clip is easy to remove and "breaks away" and opens when the user pulls on one side of the collar. This can make the collar 63 be removed quickly in an emergency.
An alternative embodiment of the head fixing mechanism is shown in FIG 3 shown. The nasal cannula assembly 30 becomes with over the ears running loops 66 attached to the patient's head. The loops 66 are configured to hang over the patient's ears and the Ge weight of the nasal cannula assembly 30 take up. The loops are through the side straps 31 (described below) of the nasal cannula assembly attached to the nasal cannula assembly. The ear loops are relative to the straps 31 horizontally movable. The horizontal displaceability allows a user to adjust the tightness of the earloops to ensure that the nasal cannula assembly comfortably and correctly fits a user's face. The loops 66 carry the weight of the nasal cannula assembly 30 , so that the nasal passages of the user by the weight of the nasal cannula assembly 30 not be unduly burdened. Through the loops is the nasal cannula assembly 30 more comfortable to wear.
The secondary supply line 62 will now be described in detail. The secondary supply line 62 is a short pipe or a short hose that is between the outlet of the main exhaust pipe 3 and the nasal cannula assembly 30 runs. In use, the gases escape from the main discharge line 3 out and into the secondary feed line 62 one, passing along the secondary feed line 62 flow to the patient. One reason why secondary lines like the secondary supply line 62 is the following: The main delivery line 3 is relatively heavy and bulky because it is used to transport gases over a relatively long distance (from the humidifier unit 2 to a point near the patient). The main delivery line 3 must therefore have a wall strong enough to withstand its own weight without collapsing. Because the main delivery line 3 For this reason, it is relatively long (e.g., 8 to 10 feet), and this extra length and thicker wall construction add to the weight of the main discharge line 3 added. If the outlet of the main delivery line 3 connected directly to the patient interface, allowing the user 2 This weight may be uncomfortable for the user due to the weight of the main delivery line. It becomes a lighter, shorter secondary line (eg, the secondary feed line 62 ) between the outlet of the main discharge line 3 and the patient interface 20 used. The secondary supply line 62 is lighter and shorter than the main delivery line 3 and as described above, it is generally used with e.g. As a collar or a loop 63 used with the secondary feed line 62 or with the connection between the main delivery line 3 and the secondary feed line 62 connected to the weight of the main delivery line 3 and the secondary feed line 62 to be used in use.
The connection between the outlet of the main delivery line 3 and the inlet of the secondary feed line 63 sits near the patient to twist or pull on the nasal cannula assembly 30 To prevent and possible heat problems or overheating near the patient by the in the main delivery line 3 provided heating element 11 to avoid. To reduce condensation in the unheated secondary feed line 62 For example, a conduit with vapor transfer characteristics may be provided. The secondary supply line 62 Can be integral with the main delivery line 3 be formed or it may be attached via any connection mechanism, the detachment of the secondary supply line 62 from the main delivery line 3 allowed. The connecting mechanism may be a threaded screw type or a friction locking mechanism. The secondary feed line may preferably be made of a breathable material that allows water vapor through the feed line and into the ambient air, and substantially prevents liquid water or breathing gases from flowing out of the feed line. The feed line may comprise regions of breathable material along its length or, alternatively, the entire line may be breathable. Materials may be breathable due to their composition, physical construction or a combination thereof. The mechanisms of water vapor transmission through these breathable materials are numerous and well known in the art. The purpose of the breathable region or regions of the feed line wall is to allow passage of water vapor from the gas path through independent dedicated drain points. This reduces the accumulation of condensation water in the breathing tube by drying the humidified breathing gases (by transferring water vapor into the surrounding room air) during the flow through the breathing tube. An example of such a material is SYMPATEX ™ or GORETEX ™ or NAFION ™ and so on.
By providing a short secondary supply line 62 For example, most of the moisture in the gases is transported to the patient and only a negligible and negligible loss of moisture through the breathable wall of the short secondary feed line occurs while condensate formation is reduced.
The The nasal cannula and its various features are now becoming more detailed described.
The preferred form of the nasal cannula 30 Part of the patient interface 20 is now forming in more detail with particular reference to 4 . 5 . 6 . 7 . 8th . 9 and 10 described.
The nasal cannula 30 of the preferred form comprises two main parts: a manifold section 35 and a face attachment part 32 , The preferred embodiments of these two parts will now be made with particular reference to 4 and 5 described.
In the preferred form, the manifold section is 35 in use with the secondary supply line 62 as described above and is in fluid communication with this. He could but in alternative embodiments also directly to the main delivery line 3 be connected. When the term "gas inlet manifold part" is used in this patent, it is the manifold section 35 in combination with the secondary supply line 62 or simply the distributor section 35 meant.
It should also be noted that in the preferred form as in 4 and 5 shown the distributor section 35 from the rest of the nasal cannula 30 is removable. The distributor section 35 but could also be integral with the nasal cannula 30 may be formed, if preferred or required - ie the manifold section 35 and the face attachment part 32 (which is described below) are a part.
The preferred form of the distributor part 35 is generally tubular with a substantially circular inlet 59 on one side, forming an elongated oval outlet 37 curves, with the outlet 37 on one side of the distributor part 35 is shaped so that it is perpendicular to the inlet 59 stands. The circular inlet 59 in the preferred form takes the patient end of the secondary delivery line 62 on, allowing the gases from the secondary feed line 62 through the distributor part 35 can flow (the inlet 59 could alternatively be oval or any other arbitrary shape - it need not be circular). In the preferred embodiment, the distributor part is 35 integral with the secondary supply line 62 molded (ie, it should not be removed in use and replaced repeatedly, but it can be removed if necessary), but alternatively, the distributor part 35 also removable on the secondary supply line 62 be attached. The distributor part 35 grabs the face attachment part 32 one, allowing gases through the outlet 37 and from the secondary supply line 62 to the patient 2 over the nasal connections 33 . 34 (which are described in detail below) can flow.
In the preferred embodiment, the distributor part consists 35 made of a hard plastic that deforms only under relatively high load conditions (ie it can not be easily crushed by a user's hand). The distributor part 35 can be molded, injection molded, machined or cast.
The distributor part 35 is in use with the face attachment part 32 connected, so that from the distributor part 35 escaping gases in the facial attachment part 32 enter. The term "connected" in the context of this specification means either "detachable" or "integral with". The face-fixing part is described in mm in detail.
Face mounting part
The face attachment part 32 has the nasal connections 33 . 34 on, allowing gases to pass through the face attachment part 32 flow, into the nasal connections 33 . 34 invade and to the patient 2 can be performed. In the preferred form, the nasal connections extend 33 . 34 parallel to each other, bend up and in from the face attachment section 32 , In the preferred embodiment, each nasal port is equidistantly spaced from the center of the face mount portion. The construction of the nasal connections 33 . 34 is described in detail below.
The face attachment part 32 The preferred embodiment has side straps 31 and an open tubular recess 38 on, like in 4 and 5 shown integrally molded. The open tubular depression 38 extends under the face attachment part 32 and can the distributor part 35 (for the preferred embodiment, in which the face attachment part 32 and the distributor part 35 can be separated from each other). The face attachment part 32 has a lip 39 extending around the top of the open tubular cavity 38 extends. The distributor 35 is with the facial attachment part 32 connected by friction and the lip 39 on the face fitting part 32 helps the distributor part 35 to grab and wipe a strong sealed connection to the manifold part 35 and the face attachment part 32 to build. The open tubular depression 38 gets from a rib 40 divided, located under the facial attachment part 32 extends. The rib 40 helps the distributor part 35 in the correct position when engaged with the face-fixing part 32 pick up and hold, with the rib 38 around the outside of the distributor part 35 extends. The outlet 37 on the distributor part 35 is in use with the bottom of the face mount part 32 aligned when the distributor part 35 with the Ge view attachment member 32 connected is. This alignment minimizes and reduces those from the nasal cannula assembly 30 escaping gas amount, so that an effective treatment of the user by delivering a maximum amount of humidified gases is possible.
The side straps 31 be used to attach the head strap 50 or the ear loops of the face-fixing part 32 used. The side straps 31 include a pair of straps (in the figures as straps 31 shown) extending from one side of the face-fixing part 32 and, in the preferred embodiment, as an integral part of the face-mounting member 32 are shaped. The head strap 50 becomes in use on the side straps 31 attached, so that the patient interface can be worn in use by a user. In the preferred embodiment, the ends of the headgear run 50 in loops through a pair of slits on the side straps 31 with the ends having a hook and loop fastener to hold them in place when they are looped back on themselves. Alternatively, the head strap 50 or can the loops 66 on the side straps 31 They can be clamped together, for example by cooperating male and female clips or they can be attached to the side straps 31 be stuck.
In the preferred embodiment, the face fastener, nasal prongs, side straps and open tubular recess are all fabricated as a continuous part. The face attachment part 32 , the nasal connections 33 . 34 , the side straps 31 and the open tubular depression 38 are all made of a flexible polymer material or silicone, preferably a soft thermoplastic elastomer (TPE).
The Nasal connections will now be described in detail.
in the The nasal connections are described below. In the The following description refers to the term "back" or "back" or a similar synonym to the part of the construction that is in the Use of the nasal cannula points to the patient's face and closest to it. The term "forward" or "forward" or every similar synonym refers to the page, area or the part in use from the patient's face or User away and farthest from it. Of the Term "top" or "top" refers on the page, surface or part, or the pointing away from the ground when a user or patient is the interface wears, stands or sits upright and looks ahead. The term "lower" or "lower" refers on the page, surface or part, or the to the bottom shows when a user or patient is the interface wears, stands or sits upright and looks ahead.
In the preferred embodiment, the face attachment portion 32 two nasal connections 33 . 34 which extend upwards and from the top of the face-fixing part 32 to bend inward, as in 4 . 5 . 6 and 7 is shown. In 7 and 8th The nasal connections extend 33 . 34 from the top of the face fitting part 32 and each nasal port is inserted into a nostril of the patient when the nasal cannula assembly is applied. The nasal connections 33 . 34 are configured to deliver gases to a patient. The nasal connections 33 . 34 get humidified gases from the discharge line 3 via the secondary supply line 62 , the distributor part 35 and the face attachment part 32 , It should be noted that in the preferred embodiment, the gas inlet manifold part 35 the gases from the secondary feed line 62 receives, wherein the gases through the gas inlet manifold part to the face-fixing part 32 and then into the nasal connections 33 . 34 stream. The nasal connections 33 . 34 are therefore in fluid communication with the gas inlet manifold 35 and receive gases from the secondary feed line 62 , As mentioned above, the gas inlet manifold part could 35 and the face attachment part 32 as a part - that is, as a combined manifold and face fastener, and this part could be shaped as needed to act as a manifold, with the nose ports integrally molded with the manifold, the manifold to one or more gas hoses or tubes connected, similar to the typical nasal cannulas known in the art. When used in this specification, the term "gas inlet manifold part" is broad enough to encompass this arrangement. The term is also broad enough to encompass double hoses of the type known in the art, each connected to one side or one end of the manifold hose and running in loops over the ears of a user before being attached to a main discharge pipe or hose attached to a secondary supply line. It is also to be noted that the term "a gas inlet manifold part which can form a fluid communication with a discharge conduit" is intended to mean that the gas inlet manifold member is directly or indirectly connected to intermediate pieces, such as, e.g. B. a secondary supply line or double hoses known in the art (or both) may be connected.
In the preferred embodiment, the nasal connections are 33 . 34 generally tubular with an upward and backward curvature. The nasal prongs bend in use up and to the back of the patient's head. Preferably, the nasal prongs are bent to the back of the nasal passages of the patient so that the gas flow delivered by the nasal ports is directed toward the back of the nasal passages of the patient. The curvature of the nasal connections 33 . 34 ensures that the nasal connections follow the natural curvature of a human nasal passage. Preferably, the nose ports follow a radius of curvature of 10.5 mm, but any radius between 5 and 20 mm is suitable and larger or smaller sizes are possible without deviating from the scope of the invention. The curvature of the nasal connections 33 . 34 Ensures that gases are delivered into the nasal cavity of the patient so that leakage of gases from the nasal cavity is reduced. The curvature of the nasal connections 33 . 34 provides the benefit of additional comfort and effective delivery of respiratory gases into the nasal cavity of a patient.
In the preferred embodiment, the nasal connections fit 33 . 34 into the nasal passage of the patient. Preferably, each nosepiece has a generally circular cross-section. Alternatively, the nasal connections may also have a triangular or oval cross-section. A circular cross-section is most advantageous in use because this shape conforms closely to the shape of a human nasal passage, thus making it comfortable for the patient and ensuring the correct administration of the therapy. However, the nostrils and nasal cavities of the users are not perfectly circular or geometrically shaped by default, so that other cross sections (for example triangular or oval cross sections as mentioned above) may also be preferred.
In the most preferred form, the nasal ports are located equidistant from the center of the face-mount portion. Preferably, the nose ports are angled so that they are slightly inwardly facing each other, as best shown in FIG 9 can be seen. As seen from above, the center of each tab is preferably angled inwardly by 15 degrees from the vertical line A, as in FIG 9 you can see. That is, the angle X between line A and line B as in 9 shown is 15 degrees. This applies to both couples. The line A defines a vertical plane that is substantially parallel to the vertical plane of symmetry that the face-fixing part 32 the nasal cannula 30 that is, a line or plane that would cut the human nasal when the nasal cannula is positioned on a user's face. The nasal connections 33 . 34 are curved inwardly at an angle of 15 degrees to provide the most snug fit in use. It has been found that a curvature of the nasal ports 15 degrees inwards for the most comfortable fit and for the most comfortable position for a user and an optimal position for the delivery of therapeutic gases to a patient leads. The nasal connections can be placed at any other angle greater than or less than 15 degrees. For example, the angle range between line A and line B could be between 0 degrees and 60 degrees inward. Alternatively, the nasal connections could be angled outwardly from the vertical line A. Outward curvature of the nasal ports is not preferred because it would mean that the nasal ports will not follow the natural shape of the nasal passage, making them uncomfortable for most users. However, in some situations or for some users, this outward curvature may be appropriate in certain circumstances.
Each nose port has a gas outlet cutout section 41 on the back side 43 the nasal connections on, as in 7 . 8th and 10 you can see. The gas outlet cutout or cutout portion in the preferred embodiment provides each nosepiece with the appearance of a spoon. The front 42 of the nasal port (the side farthest from the patient) extends from the facial attachment portion 32 further upwards and inwards and forms a guide wall that carries humidified gases into the nasal passage of the patient when the nasal connections 33 . 34 in use. The gas exit cutout in the nose port has a cross-sectional area greater than the cross-sectional area of the nose port at or near the entry point of the gases into the nose port of the manifold section - ie, the cross-sectional area of the nose port is at the point where gases exit the nose port ( and entering the nostrils of the user) greater than at a point at or near the point where the gases enter the nasal port from the manifold section.
The clipping section 41 can have different shapes. In the preferred embodiment, the cutout portion is 41 Seen from the back oval shaped, as best in 8th can be seen. Seen from the back thus describes the scope of the cutout section 41 an oval shape with the top of the oval angled slightly inward toward the other nasal port. The cutout portion could also be triangular (with one point of the triangle oriented towards the bottom of the nosepiece and the other two corners at the topmost inside edges of the cutout portion 41 are). The cutout could also be rectangular shaped.
The cutout may extend from various positions along the nosepiece. Preferably, the cutout section extends 41 over half to two-thirds of the distance on the nasal port, measured from the upper tip of the nasal port. Alternatively, the cutout section extends 41 over less than half the distance on the nasal port, measured from the upper tip of the nasal port. Alternatively, the cutout can also extend over the entire length of the nosepiece. In the most preferred embodiment, the cutout portion extends 41 Over half to two-thirds of the distance on the nasal connection to provide the best benefits. It has been shown that the optimum opening size is achieved when the cutout extends over half to two thirds of the way. The placement of the cutout in this position ensures that the optimum size of the cutout is achieved and that the advantages described later in this patent are achieved. For nasal connections according to the preferred embodiment, this corresponds to a section with a height of 3 mm to 15 mm. However, the size of the clipping could also fall outside of this range if required for alternative forms.
In the preferred embodiment, the cutout becomes 41 produced in a molding process. The nasal connections are preferably formed by injection molding, casting or vacuum forming. The mold used to make the desired nasal connection form already contains the cut-out feature.
In alternative embodiments, the cutout section becomes 41 by cutting across the back 43 every nasal connection 33 . 34 produced after their formation in a first molding process -. B. after molding of the face-fixing part 32 In a first molding operation, the cutout is formed by machine or manual removal of material.
The reverse S-shaped surface 80 that defines the clipping is best in 10 to see. The lower edge of the surface 80 is in 9 as a line 800 shown. It turns out that the line 800 for each nasal port is perpendicular to a line through the middle of the nasal port and aligned with the rear edge of the nasal port. This is best in 9 to see. Preferably, the surface is 80 shaped as inverted S, as in 10 you can see. The area 80 extends inward for a certain distance, thus forming the preferred "spoon" shape of the gas exit cutout. The inverted S-shape is oriented substantially vertically. The inverted S-shaped surface gives the most preferred size and shape of the cutout. After molding, the margins or the circumference of the cutout section will fit 41 to the surface of the inverted S-shaped surface, as in 10 you can see. Such a surface gives the optimum cut-out shape, which leads to the advantages listed below.
In the preferred embodiment, the rear wall includes 43 the nasal connections 33 . 34 also a reinforcing feature (not shown in the figures) that extends up the length of the rear wall of the nosepiece. The reinforcement feature helps the rear wall 43 to maintain the nasal connection upright. Preferably, the reinforcing feature is formed as a ridge that extends over at least a portion of the rear side path 43 the nasal connections 33 . 34 runs. This burr can be on the inside or on the outside of the back wall 43 because, in use, the back wall is generally not in contact with a user's upper lip or nostrils so that the enhancement feature on the user's face is not distracting and uncomfortable. Preferred and alternative forms of the enhancement feature are discussed in more detail below.
Due to the curvature and shape of the nasal connections 33 . 34 The airflow tends to over the front wall of the nasal connections 33 . 34 and not over the back wall 43 to flow - the airflow flows more on the outside of the curve than on the inside. advantages
The cutout sections in each nosepiece provide a number of advantages. The main advantages are:
1) Each nasal port may deform more easily because it has less structural stiffness (it lacks part of its support structure so it is easier to deform) so that it sits more comfortably in the nasal passage of a patient.
2) The gases do not come out of the nasal port as a jet, but through a small opening. The cutout provides a larger cutout area at the exit of the nose ports so that the velocity or air velocity of the gases is reduced at the point where they exit the nose port (s). That is, the size of the exit opening (defined by the edge or circumference of the cutout) is greater than the size or cross-sectional area of the inlet opening defined by the bottom of the nose-piece where it joins the face-mounting portion 32 connected is. The air velocity of the gases decreases with increasing area. Each nasal port is shaped so that the velocity of the gasses exiting the nasal port is reduced at or near the entry point of the nasal port compared to the velocity of the gases. This allows for a relatively larger volume of gas that can be delivered to a patient without being uncomfortable (compared to a cannula nasal connection without a cutout). With the cannula cut out, air jet effects are reduced. The free jet of the airflow is reduced due to the continuity equation for obtaining energy or mass, according to which increasing the cross sectional area equals a reduction of the airflow velocity. A jet of gas delivered into a user's nasal passage may irritate or potentially injure the tissue in the nasal passage. Reducing the flow rate of gases discharged from the nasal ports reduces irritation in the nostrils of the user and thus free-jet effects. It also follows from the equation of continuity that the larger the opening through which a gas flows, the greater the amount of diffusion.
3) The gas flow is generally directed in a backward direction (relative to a user's head) relative to a user's nasal passage.
The nasal cannula assembly 30 as in 6 and 7 shown is suitable for delivering a high air flow or a high humidification gas flow into the nasal cavity of the patient. In the preferred embodiment, the cutout between the top of the nosepiece extends to half or two-thirds of the way to provide the largest cutout. Further, the shape of the cutout (inverted S-shaped surface as described above) helps to ensure maximum diffusion and reduction of air blast effects.
In the prior art cannulae, the nasal ports of the cannula generally have an exit opening that is substantially the same size as their inlet opening (eg, when the bottom of the nasal port is connected to a manifold). In the cannula according to the invention described above, the size and shape of the cutout contribute to reducing the air velocity at the exit point from the nasal port and to direct the gases in a generally backward direction. This has been shown, to an amazing degree, to improve user comfort and compliance with a treatment program. In addition, the reduced flow rate of the breathing gases from the neckline 41 the nasal connections 33 . 34 helping to make sure that the user is breathing as normally as possible.
The reduction of air velocity through the cutouts in the nasal connections 33 . 34 allows the use of a higher flow rate than is generally the case in the prior art. In therapy, high flow rates are preferred to meet patient requirements. The use of a high flow rate ensures that wherever possible the entire volume of an inhaled breath contains respiratory gases. However, due to increased patient discomfort and potential dangerous side effects from higher flow rates, a compromise between patient comfort / safety and flow rate must normally be found. Lower flow rates than optimal are used to ensure that patient comfort is high enough to comply with the treatment program. The use of this lower flow rate means that at least a portion, and generally most of the user's respiration, consists of room air, which may be detrimental to medical gas therapy. The use of relatively higher flow rates and nasal ports to deliver humidified medical gases at high flow rates is advantageous. This ensures that the patient receives the most efficient and effective therapy. Surprisingly, it has been found that by using the nasal connections described above - ie nasal ports with a cutout section - flow rates can be delivered between (but not limited to) just over 0 l / min and 80 l / min to a user, and the first feedback the user points out that comfort is increased and the tendency to comply with the therapy instructions is increased. The nasal connections may have a different size - z. For use in neonates - without departing from the scope of the invention, the flow rates or flow range being significantly lower in neonatal use. It is believed that flow rates up to 120 l / min may be used in certain circumstances. However, it is believed that the preferred range is on the order of 20-50 l / min for adults, 5-30 l / min for infants and just over 0 l / min to 8 l / min for neonates. The neckline design is effective at low neonatal flow rates (up to 400 g light) where flow rates of 1-8 l / min would otherwise produce very high speeds due to the small size of the cannula and the patient.
The clipping sections 41 in the noses connections 33 . 34 cause the nasal connections 33 . 34 are more deformable than the nasal connections of the prior art without cutouts. Surprisingly, it has been found that addition of cut-outs does not have a significantly negative impact on the efficiency of gas delivery and, in addition to the above-mentioned advantages, also allows the nasal connections 33 . 34 can be bent more than the nasal connections of the prior art cannula to fit comfortably in the nasal passage of a patient. Normally, a range of different cannula sizes is used to ensure a fit range for all users. However, within each area, the greater bend or flexibility contributes to improving user comfort. The cutout 41 ensures that the nasal connections 33 . 34 more flexible than completely "tubular" or round nasal connections. In general, the nasal connections in use abut the nasal mucosa. In other nasal cannula arrangements, the nasal connections exert a force on the nasal mucosa and this pressure can cause irritation, making the nasal connections less comfortable to wear. This can even lead to the injury of the sensitive nasal tissue. The gas outlet cutouts 41 in nasal connections allow nasal connections 33 . 34 a higher degree of flexibility in the nasal passage when the nasal port presses against the nasal mucosa. Bending of the nasal ports reduces the pressure exerted on the nasal mucosa, making them more comfortable and potentially safer for the user to wear.
The clipping sections 41 in the cannula are also in the manufacture of the cannula advantageous. Through the clipping sections 41 For example, the cannula may be more easily lifted off the mold by a robot or a human operator. The clipping sections 41 can reduce the cycle time to form the cannula part by up to half.
Preferably, the nasal connections each have a gain feature 100 on that in 8th is shown and extends over the inner surface of the front wall of the nasal connection. It helps the nasal connector to return to its original shape after bending. Preferably, the feature provides for consolidation of the nasal port against compression or traction or both on the nasal port. The feature effectively forms a reinforcing burr 100 on the inside of the front wall 42 of the nasal connection, the feature extending upwardly from the bottom of the nasal connection and following the contour of the nasal connection. The reinforcing feature 100 allows lateral or rotational movement of the nasal port and allows the nasal port to elastically deform under compression or tensile forces, and exerts a restorative force to ensure that the nasal port returns to its original shape. In one embodiment, the reinforcing feature is an upwardly extending bead from the bottom of the nosepiece to its top. In the most preferred form, the rib is along the inside of the front wall 42 arranged. The bead runs from the bottom of the nose end up to its top. Preferably, the bead extends over the entire length of the nasal connection and follows the contour of the terminal. Alternatively, the bead may extend only over part of the height of the nasal connection. Alternatively, the bead may be disposed on the outside of the front wall. In a further alternative form, the bead may be arranged along the rear wall either on the inside or on the outside. The bead is preferably formed of a different material or material over the nasal connection. The reinforcing feature 100 (in this form the bead) is preferably made of a more rigid material than the nasal connections. The bead is applied to the nasal connection by a co-injection molding process. In the co-injection molding process, the nasal connection is formed of one material and the nasal connection and / or the distributor and the face attachment part are transferred to another tool where the bead material is molded over the nasal connection. The bead acts like a spine and supports the nasal connection.
In another form, the reinforcing feature 100 a rib that extends from the bottom of the nasal connection along its height and follows the contour of the nasal connection. The rib is preferably located on the inside of the front wall 42 but it can also be on the outside of the front wall 42 be arranged. Alternatively, the rib on the back wall 43 be arranged. The rib can be either on the inside or on the outside of the back wall 43 be arranged. The nosepiece preferably includes a plurality of ribs formed on the inside of the front wall. The ribs preferably extend over the entire length of the nasal connection, but alternatively they can also extend only over a partial section. The ribs are preferably identical in terms of their dimensions. The ribs are preferably arranged at the same distance on the nosepiece. The ribs form a skeletal structure that supports the nasal connection and reduces deformation of the nasal connections. The ribs are preferably made in a co-injection molding, as it be for the bead be was written. The ribs are preferably made of a material that is more rigid than the material used to make the nasal connections.
The nasal connector may also include a series of ribs (not shown) extending generally horizontally across the nasal port. The ribs may be used in combination with the reinforcing feature (eg, the bead) to strengthen the nose ports in compressive and tensile directions while allowing lateral and rotational movement. Preferably, the reinforcing feature 100 (with or without ribs) on the front wall 42 arranged the nosepiece. This is advantageous because it provides the greatest reinforcement and because the material used for the nasal connections is most responsive to compression. Preferably, the reinforcing feature is molded integrally with the nose pads during the molding process. Alternatively, a reinforcing feature may be attached to the nose pads after molding, e.g. B. by gluing or ultrasonic welding. Preferably, the feature is the same material as the nasal connection. Alternatively, the feature or ribs could be made of a rigid material, such as plastic. B. another polymer material.
The reinforcing feature could alternatively also be formed by the front wall 42 seen from above is thicker than the back wall 43 , The greater thickness of the front wall 42 effectively provides lateral and rotational movement of the nosepiece while providing improved strength under compression and tension loads. The thicker front wall 42 Make sure the nasal connections 33 . 34 do not collapse or break when subjected to compressive or tensile forces.
One potential problem with prior art "tubular" or "round" nasal ports is the possibility of creating a seal in the nasal passageway of the patient. Although a seal is desirable in certain circumstances, e.g. B. when using nasal pillows of the WO 2008/014543 in other circumstances, may cause a seal in the patient's respiratory system to create overpressure in the nostrils of the patient. This overpressure can lead to a Barrotrauma with serious injury and possibly death of the patient. It may also affect the patient's natural respiration or spontaneous breathing. The extra flexibility and larger opening size that fits the nose ports 33 . 34 through the cutouts 41 helps to minimize the risk that the cannula will create a seal in the nostrils of the patient. It is to be noted, however, that a seal is sometimes desirable, and although in the preferred embodiment a nasal cannula assembly has been described without intentional sealing, the nasal connections could 33 . 34 or the face attachment part 32 or both sealingly against the nostrils of a user. This is not the preferred form.
The flexibility of the side straps 31 allows easy fixation of the nasal cannula assembly 30 on the user's face as the straps can be easily bent to fit around a user's face. The flexibility of the open tubular cavity 38 in the preferred embodiment, it allows the open tubular depression 38 to the distributor part 35 to fit and create a secure friction fit or snap fit. The face attachment part 32 is molded in one piece from a flexible plastic, silicone or rubber for reliable and safe use.
The nasal cannula assembly and in particular the nasal connections are as in 2 to 10 shown primarily for delivery of high humidity, high flow rate gases that are beneficial to the patient.
A second embodiment of the patient interface may also be used as part of the humidification system as described above with reference to FIG 1 can be used described.
Roughly speaking, the second embodiment of the patient interface consists of a head fixation mechanism substantially similar to that described for the first embodiment, and a nasal cannula assembly. The head fixing mechanism serves to secure the patient interface to the face of a patient and to maintain the correct position of the patient interface in use. The head fixing mechanism as with reference to FIG 2 and 3 can also be used with the second embodiment of the nasal cannula described. Alternatively, no separate head fixation mechanism with the nasal interface needs to be used. This alternative form of head fixation will be described later. The humidification system with which the alternative nasal cannula assembly is used may have a secondary supply line 62 similar to those described above, which provide a gas or fluid connection between the outlet end of the main exhaust duct 3 and the main part of the nasal cannula assembly. In this alternative form, the secondary feed line 62 and the main delivery line 3 but seen in this context as a single "delivery line".
Nasal cannula - Second embodiment
The nasal cannula of the second embodiment will now be described in more detail with reference to FIG 12 and 13 described. The nasal cannula of the second embodiment comprises 3 main parts: a pair of transport tubes 1201 , a distributor section 1202 and a pair of nasal connections 33 . 34 wherein a pair of nasal ports are respectively secured to each of the transport hoses, the transport hoses are connected to the manifold section connected to the discharge line as described above so that a gas flow is supplied to the manifold section. The transport hoses are used instead of the secondary pipe. The distributor section 1202 is shaped as a Y-connector or a T-connector. The transport hoses are preferably frictionally fitted to the branches of the Y or T manifold section. Alternatively, the transport hoses may be threaded or glued to the Y or T piece. In a further alternative, the transport hoses are formed integrally with the Y or T piece. The Y-connector directs the gas flow from the secondary supply line to each of the transport hoses. Preferably, the Y or T piece is made of a rigid polymeric material, the material being so rigid that it does not easily deform under the usual operating loads.
The transport hoses 1201 may be attached to a head fixation or they may themselves be used as a head fixation mechanism. The transport hoses are wrapped behind the ears. The transport hoses allow a flexible fixation on the head. The transport hoses 1201 are so light that they can be wrapped around the ears of a patient and are comfortable for the patient to wear. By using the transport tubes, the entire nasal cannula is light. This can increase patient comfort while using the nasal cannula. The transport tubes also allow the use of the nasal cannula assembly by persons of different sizes, as long as the transport tubes are long enough to be placed over the ears. The transport hoses are connected to the manifold and form a fluid connection with the manifold. The transport hoses supply breathing gases to the distributor. The distributor 1202 has at least one nasal port protruding from it, the nasal port breathing gases from the manifold 1202 to the nasal passage of the patient.
In an alternative form, a nasal connection is connected to each transport tube at the patient's end. The nasal connections can be from the transport hoses 1201 be detachable. Preferably, the nose ports are attached by friction fit to the transport hoses. Alternatively, the nasal connections are screwed into the transport hoses. In another alternative, the nasal connections are glued or fastened to the transport tubes with an industrial adhesive. As a further alternative, the nasal connections may be formed integrally with the transport tubes.
In this alternative form, the nasal connections are essentially the same as the nasal connections 33 . 34 , which have been described above for the preferred or first embodiment. Each nose tab includes a cutout on the back side (the portion closest to a user's face in use) cut in the preferred form from the back of each nose piece such that the edges of the cutout of the surface are an inverted S-shaped Area correspond.
While the invention occur in different embodiments can, in the drawings, certain embodiments shown and described in detail above. The present disclosure is an example of the principles of the invention to watch; it is intended to illustrate the invention as herein and not limited.
- WO 2008/060295 [0006]
- WO 2008/014543 [0011, 0125]
Nasal cannula assembly for use as part of a system for delivering breathing gas to a patient, the system being a gas source which in use is a gas stream leads to the nostrils of a user, and a discharge line, which in use the gas source with the Nasal cannula assembly connects, wherein the nasal cannula assembly Includes: a gas inlet manifold part in use establish a fluid connection with the delivery line can, so that the gas flow led into the distributor part becomes, at least one nasal connection and preferably a pair of nasal connections in fluid communication with the gas inlet manifold part into the nostrils the user is introduced, the gas stream through the gas inlet manifold part and the nose ports flows, the nasal connection or nasal connections a gas outlet cutout on his or her back have or have, wherein the gas outlet cut a Cross-sectional area which is greater than the cross-sectional area of the nasal connection at or near the point of entry of the gases into the nasal connection or into the nasal connections.
The nasal cannula assembly of claim 1, wherein the nasal port, and preferably a pair of nasal ports ( 33 . 34 ) with the distributor part ( 1202 ) via a pair of transport hoses ( 1201 ), the transport hoses ( 1201 ) are in fluid communication with the nasal connection or nasal connections and the distributor, the transport tubes ( 1201 ) Transport gases from the distributor to the nose connections.
A nasal cannula assembly according to claim 2, wherein the distributor ( 1202 ) is a Y or T piece.
A nasal cannula assembly according to claim 2, wherein the nasal connections ( 33 . 34 ) in one piece with the transport hoses ( 1201 ), whereby the nasal connections into the nostril of the patient ( 1 ).
A nasal cannula assembly according to claim 2, wherein each nasal port ( 33 . 34 ) with the end of each transport tube ( 1201 ) connected is.
A nasal cannula assembly according to claim 1, wherein the cannula assembly comprises a facial attachment member (10). 32 ) connected to the distributor ( 35 ), wherein the facial attachment part ( 32 ) rests against the upper lip of the patient to stabilize the cannula on the patient's face.
A nasal cannula assembly according to claim 1, wherein the cutout ( 41 ) over half to two-thirds of the distance on the nasal connection ( 33 . 34 ), wherein the cutout is measured from the upper tip of the nasal connection.
A nasal cannula assembly according to claim 1, wherein the cutout ( 41 ) extends over less than half of the distance on the nasal connection, the section of the upper tip of the nasal connection ( 33 . 34 ) is measured from.
A nasal cannula assembly according to claim 1, wherein the cutout ( 41 ) extends over the entire length of the nasal connections.
A nasal cannula assembly according to claim 1 or 2, wherein the cutout ( 41 ) has a height between 3 mm and 15 mm.
A nasal cannula assembly according to any one of claims 1 to 5, wherein the cutout ( 41 ) is oval as seen from the back of the nasal cannula assembly.
A nasal cannula assembly according to any one of claims 1 to 5, wherein the cutout ( 41 ) is rectangular as seen from the back of the nasal cannula assembly.
A nasal cannula assembly according to any one of claims 1 to 12, wherein the cutout ( 41 ) is triangular as seen from the back of the nasal cannula assembly.
A nasal cannula assembly according to any one of the preceding claims, wherein the nasal connections ( 33 . 34 ) between 5 and 20 degrees inwards relative to a vertical planar line forming the face-fixing part ( 32 ) cuts, are angled.
A nasal cannula assembly according to claim 14, wherein the nasal connections ( 33 . 34 15 degrees inward relative to a vertical planar line connecting the face fixture (FIG. 32 ) cuts, are angled.
A nasal cannula assembly according to any one of claims 1 to 15, wherein the edges of the gas outlet cutout ( 41 ) of an area ( 80 ) substantially having an inverted S-shape, the S-shape being substantially vertically aligned.
A nasal cannula assembly according to claim 16, wherein the lower edge of the surface ( 80 ) over the back of the nasal connections ( 33 . 34 ) cuts to the neckline ( 41 ), where the area ( 80 ) represents an inverted S-shape to obtain the ideal cutout shape.
A nasal cannula assembly according to any one of claims 1 to 17, wherein at least one nasal port ( 33 . 34 ) a gain feature ( 100 ) having.
A nasal cannula assembly according to claim 18, wherein said enhancement feature ( 100 ) on the front ( 42 ) of the nasal connection and can prevent the nasal connection ( 33 . 34 ) collapsed under compression or tensile forces.
A nasal cannula assembly according to claim 18 or claim 19 wherein the enhancement feature ( 100 ) is formed as a substantially vertical ridge or as a spine, at least partially over the front side ( 42 ) of the nasal connection ( 33 . 34 ) runs.
The nasal cannula assembly of any of claims 1 to 17, wherein the at least one nasal port further comprises a gain feature ( 100 ) on the inside of the front wall ( 42 ) of the nasal connection in order to prevent the nasal connection ( 33 . 34 ) collapsed under tensile or compressive forces.
A nasal cannula assembly according to any one of claims 1 to 21, wherein said at least one nasal port further comprises at least one and preferably a plurality of ribs extending across said front face (10). 42 ) of the nasal connection ( 33 . 34 ).
The nasal cannula assembly of claim 22, wherein the at least one rib (s) extend beyond the outer face (10). 42 ) of the nasal connection ( 33 . 34 ) runs or runs.
A nasal cannula assembly according to any one of claims 1 to 23, wherein the anterior portion of the wall of the nasal port ( 33 . 34 ) is thicker than the rear part ( 43 ) of the wall of the nasal connection.
A nasal cannula assembly according to any one of the claims 18 to 24, wherein the feature or the ribs or both are integral is formed with the nasal connection or are.
A nasal cannula assembly according to any one of claims 18 to 24, wherein the feature or ribs or both separately at the nasal port ( 33 . 34 ) are fixed after its formation.
The nasal cannula assembly of any one of claims 1 to 26, wherein the nasal cannula assembly further comprises side straps ( 31 ) with which a head-mounted fixation assembly can be connected to the nasal cannula assembly so that the nasal cannula assembly can be secured in use to the patient's head.
A nasal cannula assembly according to claim 27, wherein the facial attachment member having at least one nasal port ( 33 . 34 ) and at least a portion of the side straps ( 31 ) consist of a flexible polymer material, for example a thermoplastic elastomer or silicone.
A nasal cannula assembly according to any one of claims 18 to 28, wherein the feature ( 100 ) or the ribs or both are made of the same material as the nasal connection.
A nasal cannula assembly according to any one of claims 1 to 28, wherein the at least one nasal port or both nasal ports ( 33 . 34 ) has a shape or size or shape and size such that the gas flow is generally directed to the back of the nasal passageway of the patient.
A nasal cannula assembly according to any one of claims 1 to 30, wherein the at least one nasal port or both nasal ports ( 33 . 34 ) is shaped such that the velocity of the gases exiting the nasal port is reduced compared to the velocity of the gases at or near the entry point of the nasal port.
A nasal cannula assembly according to any one of claims 1 to 31, wherein the at least one nasal port or both nasal ports ( 33 . 34 ) in use is bent upwards and backwards towards a user and the cutout ( 41 ) an elongated shape along the back and top of the nasal port or nasal ports ( 33 . 34 ), so that the gas flow is generally directed to the back of the nasal passageway of the patient, and jet effects are reduced.
A nasal cannula assembly according to any one of claims 1 to 32, wherein the nasal connections ( 33 . 34 ) are shaped and sized so that in use they do not form a substantially airtight seal with the nostrils of the user.
The nasal cannula assembly of any one of claims 1 to 33, wherein the nasal ports are adapted to deliver high velocity medical gases to a patient; so that a significant portion of the patient's inspiration from breathing gases from the nasal connections ( 33 . 34 ) and only a minimal part consists of room air.
System for delivering respiratory gases to a patient, the system comprising: a gas source unit, which can provide a gas flow, a patient interface, a Dispensing line, which also has a secondary gas inlet line can receive and receive the respiratory gases from the gas source and Move breathing gases from the gas source to the patient interface can wherein the patient interface is a nasal cannula assembly according to one of claims 1 to 29.
A respiratory gas delivery system according to claim 35, wherein the system has high flow rate gases in the range from just over 0 l / min to 120 l / min.
A respiratory gas delivery system according to claim 36, wherein the range is 20-50 l / min and the System is particularly suitable for use by adults.
A respiratory gas delivery system according to claim 36, wherein the range is 5-30 l / min and the system especially suitable for use by children.
A respiratory gas delivery system according to claim 36, wherein the range is just over 0 l / min to 8 l / min and the system is particularly suitable for use by newborns is.
A respiratory gas delivery system according to any one of the claims 35 to 39, wherein the system is designed to be in use such a high flow rate gives off that the largest Part of the inhalation of a user consists of medical gases and only a minimal amount of indoor air is entrained when a User inhales.
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US11875008P true 2008-12-01 2008-12-01
US61/118,750 2008-12-01
DE102009047246A1 true DE102009047246A1 (en) 2010-06-10
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DE102009047246A Pending DE102009047246A1 (en) 2008-12-01 2009-11-27 Nasal cannula
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JP (2) JP5281562B2 (en)
AU (1) AU2009243444B2 (en)
CA (3) CA2686747C (en)
DE (1) DE102009047246A1 (en)
FR (1) FR2939047B1 (en)
GB (1) GB2465689B (en)
HK (1) HK1144265A1 (en)
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2009-11-27 DE DE102009047246A patent/DE102009047246A1/en active Pending
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2009-12-01 GB GB0921068A patent/GB2465689B/en active Active
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2019-01-03 US US16/239,433 patent/US20190134336A1/en active Pending
US8997747B2 (en) 2015-04-07
AU2009243444A1 (en) 2010-06-17
CA2938743A1 (en) 2010-06-01
CA3011836A1 (en) 2010-06-01
AU2009243444B2 (en) 2015-07-16
FR2939047A1 (en) 2010-06-04
JP2010131400A (en) 2010-06-17
JP2013138874A (en) 2013-07-18
CA2686747A1 (en) 2010-06-01
JP5281562B2 (en) 2013-09-04
US20190134336A1 (en) 2019-05-09
HK1144265A1 (en) 2011-06-30
GB0921068D0 (en) 2010-01-13
FR2939047B1 (en) 2012-12-28
GB2465689A (en) 2010-06-02
US20100192957A1 (en) 2010-08-05
CA2686747C (en) 2016-10-11
GB2465689B (en) 2011-03-09
US10207071B2 (en) 2019-02-19
US20150209542A1 (en) 2015-07-30
DE60129459T2 (en) 2008-04-10 Diffuser for the administration of oxygen to a patient