WO2007141787A1 - A device and method for assisting placement of a tube device through a body passage - Google Patents

Abstract

A device, and a method of use thereof, for aiding the proper insertion of a tube device (20) into the body of a patient via a body passage, said device comprises a pneumatic signal generator (13) and it is adapted to connect to the proximal end of a conventional tube device and provide gas (e.g., air) passage and connectivity to a gas source (27) for streaming gas streams therethrough, such that acoustic signals are produced by said pneumatic signal generator in response to the passage of said gas streams.

Description

A DEVICE AND METHOD FOR ASSISTING PLACEMENT OF A TUBE DEVICE

THROUGH A BODY PASSAGE

Field of the Invention

The present invention relates to the placement of a tube device in the body of a treated subject. More particularly, the invention relates to a method and device for confirming placement of a tube device (e.g., Endotracheal tube) in the trachea of a treated subject.

Background of the Invention

Various treatment procedures requires placement of a tube device in the body of a treated subject. Typically, the tube device is advanced towards a desired location in the body of the treated subject via a body passage. For example, endotracheal tubes (ETT) are tube devices used for ensuring that there is an open pathway to the lungs of a patient, for ventilating the lungs. The process of inserting an ETT into the trachea, also known as intubation, may be carried out via the mouth, the nose (nasotracheal intubation) , or directly through an incision performed in a surgical procedure (cricothyroidotomy) on the neck of the patient.

While ETT intubation may be performed "blind", it is usually performed by visualizing the larynx by means of a laryngoscope, or by other means (e.g., CO₂ detector, esophageal detector) . In ETT intubation using direct laryngoscopy the laryngoscope is inserted into the mouth of the patient and used to push away the tongue and lift the epiglottis. This process is cumbersome to the practitioner.

An elongated flexible element is typically used as an introducer (stylet) in ETT intubation, wherein said introducer is inserted into the ETT to enhance its stiffness and pushability during placement thereof in the patient's trachea, and it is removed thereafter. After placing the ETT in the trachea a ventilator, such as a bag valve mask, may be attached to the ETT for ventilating and oxygenating the lungs.

When properly positioned the distal end of the ETT is located slightly (about 2cm) above the carina (lungs bifurcation) . However, in some instances the ETT is inserted past the carina, and in this case it mainly communicates with the right primary^ bronchus. In many other instances the ETT is inadvertently inserted into the esophagus, and in some cases the ETT distal tip moves proximally past either the carina or above the vocal cords, which diminishes lung respiratory efficiency and may result in severe medical complications.

There are various ETT sizes that suit different tracheal diameters and lengths. The proximal extremity of the ETT ends in a quick connector suitable for connecting it to ventilation devices. ETTs are also used for suctioning secretions and mucus that may block the passage of air to the patient's lung (deep suction), by means of a catheter device that is inserted through the ETT.

The ETT "blind" or laryngoscope based intubation methods commonly performed nowadays do not provide means for verifying proper insertion of ETTs into the trachea of patients, and they are not suitable for battlefield situations or events with a great number of casualties.

An audio aid for determining position of an ETT within a patient is described in US patent No. 6,3497,20. In this patent a mechanical noise maker is formed upon the distal end of a cuffed ETT, such that whenever the distal end of the ETT has been sufficiently advanced into the trachea or esophagus during endotracheal intubation and an airway is established, the mechanical noise-making device formed upon the distal end of the ETT produces audible sounds as the patient inhales and exhales, or responsive to lungs ventilation carried out by means of a ventilation device.

Namely, the audio aid described in US 6,3497,20 can not be used with conventional ETTs, rather, a modified ETT having a noise-making device formed upon its end is required. Said modified ETT is therefore more susceptible to blockage by mucus and secretions due to the noise-making device formed upon its distal end, and for the same reason, it is not suitable for introducing medication into the patient's lungs, as sometimes needed, and it is not suitable for suctioning secretions and mucus blocking patient's air passage, since the suctioning catheter device can not pass the noise making device formed upon the distal end of the ETT.

Additionally, locating the noise-making device in the air passage of the ETT complicates conventional ETT placement procedures wherein an introducer is employed. Moreover, since the noise making device is located distally, remote from the ventilation device, the magnitudes of the stream of air reaching it are substantially reduced, and correspondingly the magnitudes of the audible sounds produced by it are diminished.

The term "advanced airway device" used herein generally refers to intubation devices (e.g., tubes) and airway devices used for opening a pathway to the lungs of a treated subject, - A - such as, but not limited to, ETT (tubus) , laryngeal mask airway (LMA), combitube, king, and the like.

The methods described above have not yet provided satisfactory solutions for properly placing tube devices, such as, but not limited to, advanced airway devices, in the body of a treated subject. Therefore there is a need for a method and device that overcomes the above mentioned problems .

It is therefore an object of the present invention to provide a method and device for properly placing a tube device in a patient .

It is another object of the present invention to provide a method and device for identifying the location of the distal end tip of a tube device placed in a patient.

It is a further object of the present invention to provide a method and device for properly placing an advanced airway device in a patient by utilizing the standard advanced airway and intubation equipment commonly used nowadays.

It is yet a further object of the present invention to provide a method and device for properly placing a tube device in a patient which is simple to use and which may be implemented with low costs.

Other objects and advantages of the invention will become apparent as the description proceeds. Summary of the Invention

The present invention is directed to a device and method for confirming placement of a tube device in the body of a treated subject. The device of the present invention is adapted to connect to the proximal end of conventional tube devices which are introduced into the body of a treated subject via a body passage, and it is designed to provide gas passage and connectivity to a gas source capable of streaming gas volumes therethrough. The gas passage of the device of the invention comprises a pneumatic signal generator capable of producing acoustic signals in response to the passage of gas therethrough. Said acoustic signals propagate through the tube device into the body of the patient and are used to indicate the location of the distal tip of the tube device.

The term "tube device" used herein refers to tubes suitable for insertion into the body of a treated subject via body passages. For example, said tubes may part of systems used for internal provision of medications or ventilation gases (e.g., air, oxygen).

In one preferred embodiment the device of the invention is used for the proper insertion of an advanced airway device into the trachea of a patient. In this preferred embodiment the device of the invention is adapted to connect to the proximal end of a conventional advanced airway device and it is designed to provide gas passage and connectivity to ventilation devices for ventilating the patient's lungs therethrough. The pneumatic signal generator provided in the device is adapted for producing acoustic signals in response to the passage of air through the device. Said acoustic signals propagate through the advanced airway device into the 5

- 6 - body of the patient and are used to indicate the location of the distal tip of the advanced airway device.

The inventor hereof developed a new device, and a method of using the same, for assisting placement of tube devices in the body of a treated subject. The device of the invention is adapted to produce audible signals responsive to the passage of gas streams provided by a gas source to which the device is connected, said audible signals are produced by a pneumatic sound generator (e.g., whistle or reed) disposed in a gas passage provided thereinside.

In one aspect, the present invention is directed to a device for confirming placement of a tube device in a body passage of a treated subject comprising a gas transferring element having first and second ends and a gas transfer passage passing therebetween, said first end is adapted to connect and communicate with a gas source capable of streaming a stream of gas through said gas transfer passage, and said second end is adapted to connect and communicate with said tube device, said gas transferring element further comprises a pneumatic sound generator disposed in said gas transfer passage, such that audible signals are produced by said pneumatic sound generator whenever gas streams provided by said gas source are transferred to said tube device via said gas transfer passage. The pneumatic sound generator may be attached (e.g., by glue or welding) to the inner wall of said gas transfer passage, or fitted thereinside. Additionally or alternatively, the pneumatic sound generator may be attached to the inner wall of the gas transferring element by means of supporting elements connected thereto. The gas source may be a type of ventilation device as used for providing (manually or automatically) gas streams suitable for lung ventilation, such as, but not limited to, bag-valve or mechanical/automatic respiratory devices.

The device may further comprise filtering means disposed in the gas transfer passage, preferably near the first end, such that gas transferred therethrough is forced to pass through said filtering means. Alternatively, external filtering means may be employed by connecting the same to the first or second end of the device, wherein said filtering means is adapted to connect and communicated between the device and the gas source or the tube device.

Preferably, the first end of the gas transferring element is adapted to be received in connecting means provided in the gas source and the second end thereof is adapted to receive connecting means provided in the tube device.

In a specific embodiment of the invention the gas transferring element is constructed from coaxially connected tubes. Advantageously, one end of the gas transferring element is adapted to be received in connecting means provided in the gas source and its other end is adapted to be received in an opening of the tube device.

The pneumatic sound generator may be mounted concentrically in the gas passage by means of a plurality of radial arms.

In one preferred embodiment of the invention the tube device is (or part of) an advanced airway device. Advantageously, the gas transferring element may further comprise an inhalation gas entry. Preferably, said inhalation gas entry is implemented by a lateral connecting means having a gas passage, said lateral connecting means is adapted to connect to, and communicate with, an inhalation gas supply conduit, such that inhalation gas streamed therethrough is introduced therethrough into the gas transfer passage of said gas transferring element.

In another aspect, the present invention is directed to a method^' for placing a tube device in a treated subject, comprising: advancing said tube device towards a desired location in the body of the treated subject through a body passage; connecting to said tube device a gas transferring element comprising a pneumatic sound generator disposed in gas transfer passage passing between first and second ends of said gas passage element; connecting to said gas transferring element a gas source; streaming volumes of gas from said gas source into the gas transferring passage of said gas transfer element; determining proper placement of said tube device whenever audible signals produced by said pneumatic sound propagate to the desired location in the body of the treated subject. The method may further comprise retracting portions of the tube device and reinserting the same towards the desire location whenever audible signals produced by the pneumatic sound generator do not propagate to said desired location.

The determination of proper placement of the tube device may be carried out by listening to the external areas on the body of the treated subject near the desired location with unaided ears or by means of a stethoscope, or palpably by sensing the vibrations transmitted due to the propagation of said audible signals. The tube device may be (or part of) a type of advanced airway device. The method may further comprise connecting an inhalation gas source to the gas transferring element.

Brief Description of the Drawings

The present invention is illustrated by way of example in the accompanying drawings, in which similar references consistently indicate similar elements and in which:

Fig. 1 shows a longitudinal-section view of the intubation assisting device of the invention when connected to an ETT and a ventilating device;

Fig. 2 is a cross-sectional view of the intubation assisting device of the invention;

Fig. 3 shows a longitudinal section view of the intubation assisting device of the invention having a filtering element;

Fig. 4 exemplifies using the intubation assisting device of the invention with LMA; and

Figs. 5A to 5C schematically illustrate another preferred embodiment of the intubation assisting device of the invention, wherein Fig. 5A is perspective view, Fig. 5B is a side view, and Fig. 5C is a back view.

It should be noted that the embodiments exemplified in the Figs, are not intended to be in scale and are in diagram form to facilitate ease of understanding and description. Detailed Description of Preferred Embodiments

In one preferred embodiment the present invention relates to an intubation assisting device for assisting in properly inserting an advanced airway device into the trachea of a patient, for providing an airway to the patient's lungs, and for allowing lung ventilation (oxygenation) . The device of the present invention is adapted to connect to the proximal end of the advanced airway device and it is designed to provide gas passage and connection to ventilation devices for maintaining positive airway pressure. The gas passage of the intubation assisting device of the invention comprises an audible signal generator capable of producing audible signals in response to the passage of air therethrough. Said audible signals propagate through the advanced airway device into the body of the patient and used to indicate the location of the distal end tip of the advanced airway device.

The audible signals propagating into the body of the patient can be heard by the practitioner by listening to the patient's lungs with unaided ears or by means of a stethoscope. Alternatively, said audible signals may be palpably sensed by the practitioner by placing both hands against the sides of the chest and sensing the vibrations transmitted due to the propagation of said audible signals, as performed in Tactile Fremitus lungs test. Hearing or sensing said audible signals in the lungs of the patient is used as an indication that the advanced airway device is properly places in the trachea.^'

Fig. 1 schematically illustrates a longitudinal section view of an intubation system of the invention comprising an advanced airway device 20 (e.g., ETT) connected by means of quick connector 25 to the intubation assisting device of the invention 10, which may be connected by means of quick connector 12 to ventilation device 27 (e.g., bag-valve). Advanced airway device 20 is preferably a type of conventional intubation tube made from a flexible tube having an inner passage 22 and cuff 30 located at its distal end, said cuff 30 may be inflated by an air source 32 via inflating conduit 31. Typically, such conventional advanced airway devices are inserted into the trachea by means of an introducer (not shown) .

Intubation assisting device 10 comprises a central bore 17 in which a pneumatic sound generator 13 is mounted by means of one or more supports 15, as seen in the cross sectional view in Fig. 2. Alternatively, pneumatic sound generator 13 may be adhered or welded within the central bore 17, fitted thereinside, or manufactured as an integral part of intubation assisting device 10. Central bore 17 communicates with inner passage 22 of advanced airway device 20 via recess 18 formed at the distal end of intubation assisting device 10 and adapted to sealably and tightly fit over quick connector 25. Quick connector 12 provided at the proximal end of intubation assisting device 10 is adapted to sealably connect to ventilation means 27.

Intubation assisting device 10 may be manufactured by any suitable process known in the art, from any suitable type of plastic, rubber, or metal, preferably from plastic. The length of intubation assisting' device 10 may generally be in the range of 3 to 8 cm, preferably about 7cm. The outer diameter of intubation assisting device 10 may generally be in the range of 1.5 to 2 cm, preferably about 1.7 cm, and the inner diameter of its central bore 22 may generally be in the range of 1.1 to 1.7 cm, preferably about 1.5 cm.

Pneumatic sound generator 13 may be a type of small whistle or reed made from any suitable type of plastic, rubber, or metal. The length of pneumatic sound generator 13 may generally be in the range of 2 to 4 cm, preferably about 2.5 cm, and its diameter is generally in the range of 0.7 to 1.2 cm, preferably about 0.9 cm.

Quick connectors 25 and 12, are preferably implemented by cylindrical parts adapted to sealably and tightly fit into recesses provided in the respective connecting means, 18 and connecting means of ventilation device 27.

The practitioner may use an introducer (stylet) to assist in the intubation process. After placing advanced airway device 20 in the trachea of the patient the introducer is removed therefrom and the intubation assisting device 10 is connected thereto by means of quick connector 25. The patient may be then ventilated by connecting ventilating device 27 to intubation assisting device 10 via quick connector 12. During ventilation the air passing via central bore 22 of intubation assisting device 10 activates pneumatic sound generator 13 which in turn generates audible signals. The generated audible signals propagate distally via central bore 22 of advanced airway device 20 into the patient's body.

The audible signals propagating into the body of the patient can be heard by the practitioner by listening to the patient's lungs with unaided ears or by means of a stethoscope. When a stethoscope is used the practitioner may listen to left and right sides of the (anterior or posterior) chest, for example, by placing the diaphragm of the stethoscope on the left and right sides of the patient's chest near the nipples. The practitioner may also place the diaphragm of the stethoscope on the patient's abdomen area (e.g., around the belly), and if the audible signals are heard in the stomach it is probably due to misplacement of the advanced airway device such that it entered the esophagus .

Alternatively, said audible signals may be palpably sensed by the practitioner by placing both hands against the sides of the chest and sensing the vibrations transmitted due to the propagation of said audible signals, as performed in Tactile Fremitus lungs test. Hearing or sensing said audible signals in the lungs of the patient is used as an indication that the advanced airway device is properly places in the trachea.

The intubation assisting device 10 of the present invention advantageously integrates with the standard intubation equipment commonly used nowadays in intensive care units and ambulances without requiring any modifications thereof. Moreover, since the pneumatic sound generator 13 of intubation assisting device 10 of the invention is not located in advanced airway device 20 it permits using a regular introducer during the intubation and there is no threat of it being occluded with secretions. In addition, whenever it is required to perform mucus or secretion suction, or to introduce medication into the lungs of the treated subject, the practitioner may simply remove the intubation assisting device ¹IO and perform the needed operations via the advanced airway device 20, as conventionally performed in such cases. It should be appreciated that the intubation assisting device 10 of the invention may be conveniently used with different intubation tubes having different sizes and lengths (e.g., for adults and children) , and in combination with bacterial/viral filters. Bacterial/viral filters are commonly used nowadays with lungs ventilation eguipment in order to prevent the spreading of contagions diseases between the different patients that are treated with the same ventilation equipment, and in order to avoid repeated sterilization procedures of said equipment after each use. In addition, the intubation assisting device 10 of the invention can also be used in patients having breathing difficulties, and as well in patients with apnea.

Fig. 3 demonstrates a preferred embodiment of the intubation assisting device 40 of the invention comprising a bacterial/viral filter 48. Filter 48 is preferably placed in the proximal portion of central bore 17 and it may be manufactured from any suitable materials as conventionally used in the manufacturing of bacterial/viral filters. Alternatively, conventional filtering means (not shown) may be externally connected to the first or second end of the intubation assisting device, wherein said filtering means is adapted to connect and communicated between with the device and the ventilation device or the advanced airway device.

It should be noted that the intubation assisting device 10 (or 40) of the invention may be used with other types of airway and ventilation devices, such as for example LMA (laryngeal mask airway) and combi-tube. Fig. 4 exemplifies using intubation assisting device 10 of the invention with LMA 47 comprising quick connector 45, inner passage 42, and cuff 44 which may be inflated by an air source 32 via inflating conduit 41.

Figs. 5A to 5C illustrates another preferred embodiment of an intubation assisting device 50 of the invention comprising connecting means 54 for connecting an inhalation gas supply conduit (not shown) to intubation assisting device 50 for supplying an inhalation (e.g., oxygen) and/or anesthetic gases to the lungs of the treated subject. Conventionally, an inhalation gas supply conduit (not shown) is used for supplying an inhalation gas supplied from an inhalation gas source (e.g., compressed inhalation gas tank) to an air enrichment bug (not illustrated) connected to the ventilation device 27. Connecting means 54 may be advantageously employed as a backup connection for the inhalation gas supply conduit which may be needed whenever the air enrichment bug is accidentally torn or damaged.

With reference to the side view shown in Fig. 5B, intubation assisting device 50 may be constructed from two coaxially connected tubes, a first tube 52 having a first opening 52o at one end thereof which is adapted to be received in connection means provided in ventilation device 27, and adapted to communicate with ventilation device 27, and a second tube 51 sealably attached at one end thereof to the other end of first tube 52 and having an opening 51o at its other end which is adapted to be received in the gas passage of advanced airway device 20, and adapted to communicate with advanced airway device 20.

Pneumatic sound generator 53c is preferably mounted in first tube 52 by means of radial arms structure 53 provided near the connection point of the tubes. Radial arms structure 53 is designed to hold pneumatic sound generator 53c concentrically in first tube 52 while allowing fluid (gas) passage therethrough.

Pneumatic sound generator 53c may be attached to radial arms structure 53 by adhesive, welding, or it may be an integral part of said structure. As illustrated in the side and back views, respectively shown in Figs. 5B and 5C, connecting means 54 comprises a passage 54p, used for communicating with the passage obtained through tubes 51 and 52. In this way, intubation assisting device 50 can be used in assisting in the intubation process, as described hereinabove, while also providing inhalation gas enrichment to the gas (air) ventilating the lungs of the treated subject by connecting an inhalation gas source thereto by means of a conduit.

Intubation assisting device 50 may be manufactured from any suitable type of plastic, rubber, or metal, preferably from plastic. The length of fist tube 52 may generally be in the range of 15 to 50 mm, preferably about 26.3 mm, its diameter may generally be in the range of 7 to 20 mm, preferably about 17.5 mm, and its wall thickness is preferably about 1.15 mm. The length of second tube 51 may generally be in the range of 15 to 50 mm, preferably about 20.6 mm, its diameter may generally be in the range of 5 to 18 mm, preferably about 13 mm, and its wall thickness is preferably about 1.15 mm.

The diameter of connecting means 54 may generally be about 3 to 8 mm and the diameter of passage 54p provided thereinside may generally be about 4 to 6 mm. As shown in Fig. 5C, radial arms structure 53 is preferably constructed from a plurality of arm 53r arranged such that one side of each of said arms 53r is attached to the inner wall, and along the length of, a section of the first tube 52, and their other end is connected to pneumatic sound generator 53c concentrically disposed in the passage within said first tube 52. Preferably, more or less equal angles are obtained between arms 53r. The length of arms 53B may generally be about 8mm.

All of the abovementioned parameters are given by way of example only, and may be changed in accordance with the differing requirements of the various embodiments of the present invention. Thus, the abovementioned parameters should not be construed as limiting the scope of the present invention in any way. In addition, it is to be appreciated that the different tubes, connectors, and other members, described hereinabove may be constructed in different shapes (e.g. having oval, square etc. form in plan view) and sizes differing from those exemplified in the preceding description.

The above examples and description have of course been provided only for the purpose of illustration, and are not intended to limit the invention in any way. As will be appreciated by the skilled person, the invention can be carried out in a great variety of ways, employing more than one technique from those described above, all without exceeding the scope of the invention.

Claims

1. A device for confirming placement of a tube device in a body passage of a treated subject, comprising a gas transferring element having first and second ends and a gas transfer passage passing therebetween, said first end is adapted to connect and communicate with a gas source, and said second end is adapted to connect and communicate with said tube device, said gas transfer passage further comprises a pneumatic sound generator disposed in said gas transfer passage, such that audible signals are produced by said pneumatic sound generator whenever gas streams are transferred via said gas transfer passage.

2. The device according to claim 1, further comprising filtering means disposed in the gas transfer passage of the gas transferring element.

3. The device according to claim 1, wherein the tube device is an advanced airway device.

4. The device according to claim 3, wherein the advanced airway device is a conventional endotracheal tube, or a type of laryngeal mask airway or combi-tube.

5. The device according to claim 1, wherein the first end of the gas transferring element is adapted to be received in connecting means provided in the gas source.

6. The device according to claim 1, wherein the second end of the gas transferring element is adapted to receive connecting means provided in the tube device.

7. The intubation assisting device according to claim 1, wherein the gas transferring element is constructed from coaxially connected tubes.

8. The intubation assisting device according to claim 1, wherein one end of the gas transferring element is adapted to be received in connecting means provided in the gas source and its other end is adapted to be received in an opening of the tube device.

9. The device according to claim 1, wherein the pneumatic sound generator is mounted concentrically in the gas passage by means of a plurality of radial arms.

10. The device according to claim 3, further comprising an inhalation gas entry.

11. The device according to claim 10, wherein the inhalation gas entry comprises a lateral connecting means having a gas passage, wherein said lateral connecting means is adapted to connect to, and communicate with, an inhalation gas supply conduit .

12. The device according to claim 1, wherein the first or second end of said device is adapted to connect to an external filtering means, wherein said external filtering means is adapted to connect and communicated between said device and the gas source or the tube device.

13. A method for placing a tube device in the body of a treated subject, comprising: advancing through a body passage said tube device towards a requisite location in the body of the treated subject; connecting to said tube device a gas passage element comprising a pneumatic sound generator disposed in gas transfer passage passing between first and second ends of said gas passage element; connecting to said gas transfer element a gas source; streaming volumes of gas from said gas source into the gas transferring passage of said gas transfer element; determining proper placement of said tube device whenever audible signals produced by said pneumatic sound generator propagate to the desired location in the body of the treated subject.

14. The method according to claim 13, further comprising retracting portions of the tube device and reinserting the same towards the desired location whenever audible signals produced by the pneumatic sound generator do not propagate to said desired location in the treated subject.

15. The method according to claim 13, wherein the determination of proper placement of the tube device is carried out by listening to external areas on the body of the treated subject adjacent to the desired location with unaided ears or by means of a stethoscope, or palpably by sensing the vibrations transmitted due to the propagation of said audible signals .

16. The method according to claim 13, wherein the tube device is a type of advance airway device.

17. The method according to claim 16, further comprising connecting an inhalation gas source to the gas transfer element.

18. The method according to claim 16, further comprising connecting an external filtering means to the first or second end of the gas passage element, wherein the tube device or the gas source is connected to said filtering means.