WO2002047748A1 - Device for selective bronchial intubation and separate lund ventilation - Google Patents

Abstract

A bronchial ventilation device (2) which enables selective ventilation of a patient's lungs comprises first and second bronchial tubes (6, 8) for insertion into the left and right bronchi respectively. A tracheal tube (4) includes first and second tracheal tube sections (10, 12) which communicate with the first and second bronchial tubes (6, 8) respectively. The device (2) includes at least one sealing cuff (22, 24, 26) which enables a seal to be formed between (a) the tracheal tube (4) and the trachea, (b) the first bronchial tube (6) and the left bronchus, or (c) the second bronchial tube (8) and the right bronchus, to enable isolation and separate ventilation of the two bronchi.

Description

DEVICE FOR SELECTIVE BRONCHIAL INTUBATION AND SEPARATE LUNG VENTILATION

This invention relates to a bronchial ventilation device.

Bronchial ventilation devices are used by anaesthetists to control selective lung ventilation through a patient's left or right main bronchi. This can be desirable for example when surgery is performed on the patient's chest cavity, or when one lung has been damaged. It can also be desirable when a lung has an abscess which is to be drained, and can reduce the risk of transmission of infection from one lung to the other. Known devices include tubes with cuff seals which enable one bronchus to be isolated from the other; a seal can be formed with such devices by supplying an inflation fluid to the cuff. Existing devices can include two lumens, in which one lumen extends into one of the bronchi and the other lumen terminates above the carina for ventilation of the other lung.

Selective bronchial ventilation can also be achieved by selectively blocking one bronchus by means of a tube with a cuff seal, in which the seal can be inflated when positioned in the bronchus, occluding the bronchus against flow of breathing gas.

Such devices are advanced through the trachea after insertion orally or through a tracheotomy stoma. Accurate location of the end of the device in the bronchus is important, in particular so that the user can be sure that a reliable seal can be formed allowing isolation of one bronchus from the other. It is preferred that the engagement of the device in the bronchus should be positive and secure to reduce the likelihood of the device being dislodged.

It is known to incorporate a hook to engage the carina at the junction between the bronchi. Known devices are configured so that the seals and lumen openings are properly located relative to the trachea and the bronchi when the hook has engaged the carina. A disadvantage of such devices is that the hook can damage the patient's airways as the device is advanced through the trachea. It can also be difficult to engage the hook with the patient's carina in some cases, leading to failure of seals between the device and the patient's tissue. Difficulties with locating the hook on the carina can also lead to the lumen being advanced into the wrong bronchus. Reducing the frequency of inaccurate location of known devices can require the use of complicated and expensive equipment such as fibre optic bronchoscopes or x-ray imaging equipment (which can require incorporation of x-ray marker material in the device).

The present invention provides a bronchial ventilation device which comprises first and second bronchial tubes for location in the left and right bronchi, and seals on at least one of the tracheal tube portion of the device and the first and second bronchial tubes.

Accordingly, in one aspect, the device provides a bronchial ventilation device which comprises first and second bronchial tubes for insertion into the left and right bronchi respectively, and a tracheal tube which includes first and second tracheal tube sections which communicate with the first and second bronchial tubes respectively, the device including at least one sealing cuff which enables a seal to be formed between (a) the tracheal tube and the trachea, (b) the first bronchial tube and the left bronchus, or (c) the second bronchial tube and the right bronchus, to enable isolation and separate ventilation of the two bronchi.

The device of the invention has the advantage that it facilitates accurate location of an ventilation device within a patient's bronchi by virtue of the positive engagement between the carina and the device at the junction between the bronchial tubes. Accordingly, the device can be located without need to use complicated and expensive location equipment such as a bronchoscope or x-ray imaging equipment. The easier location of the device can reduce patient trauma.

The device of the invention can be configured for supply of breathing gas to a selected lung through the appropriate bronchial tube, for example with a seal between that tube and the respective bronchus, or between the other bronchial tube and the other bronchus, being provided by an inflated cuff.

The device of the invention can be configured for supply of breathing gas naturally through the patient's trachea and selected bronchus, with flow of breathing gas to the other bronchus being closed by means of a blocking seal provided by an inflated cuff. In this arrangement, the bronchial tube will have a relatively small cross-sectional area so that breathing gas can flow around the outside of the tube, consistent with being able to supply gas to the blocking seals in order to inflate them satisfactorily. The tube can be closed at its distal end, with its purpose then being to enable inflation of the cuff on the tube so as to block the bronchus. The tube can be open at its end and include a separate conduit (or lumen) for inflation of the cuff, the open-ended lumen being for insertion of another instrument (for example a bronchoscope) or to allow passage of small quantities of breathing gas (generally subject to control by means of a valve at around the proximal end of the tube). When the device of the invention is intended to be used in this way, the device will preferably include two sealing cuffs to enable respective seals to be formed between (a) the first bronchial tube and the left bronchus, and (b) the second bronchial tube and the right bronchus. The bronchial tubes, and also the tracheal tube sections, will then generally be kept relative small in cross-sectional area in order to minimise obstruction of the patient's natural airway to flow of breathing gas.

When the device is configured to block a bronchus against flow of breathing gas so that the patient's breathing air is supplied to the other lung through the natural airway, it can be preferred for the device to include appropriate control valves which prevent supply of inflation gas to both of the cuffs on the respective bronchial tubes. This can ensure that one of the bronchi remains open to flow of breathing gas.

The provision of separate tubes for the two bronchi can make it easier for the user (for example, surgeon, anaesthetist, nurse, or paramedic) to locate a bronchial tube reliably in a selected bronchus. With known devices which have a single bronchial tube (optionally with a carina hook), the user is required to manipulate the device as it is advanced through the patient's trachea so that the bronchial tube ends in the desired bronchus. Such known devices have to be sufficiently stiff so that they are capable of being manipulated as they are advanced in the trachea, and can include stiffening elements (for example in the form of a length of wire) to provide the desired stiffness. Even with these features, anatomical differences between patients can make it difficult for the user to locate the device as required quickly. The device of the present invention with separate bronchial tubes has the advantage that it corresponds more closely to a patient's anatomy which can mean that proper location of the device can be clearly recognisable by feel by the user.

The relative ease with which the device of the invention can be located, in particular with reduced need for extensive manipulation by the user, can mean that the device can be made less rigid than with known devices. This can mean that a patient's airway is less likely to be damaged as the device is advanced through the trachea. A patient might therefore be less likely to suffer adverse cough or other respiratory complications after use of the device of the invention compared with previously known devices.

The reduced need for manipulation during location of the device in a patient's trachea can also give rise to the advantage that the device can be made with thinner walls than with known devices. This can enable the device of the invention to provide less resistance to air flow. It can also facilitate the placement of other apparatus in the device, for example suction catheters (especially of relatively large size).

A further advantage of the reduced likelihood of trauma that arises from the use of more flexible materials is that the device of the invention can be left in situ within a patient's airway for longer periods than is the case with known devices. This provides the possibility of using the device in situations other than during anaesthesia and surgery. For example, the device of the invention might be used for ventilation of a patient who is sedated during recovery from surgery or from trauma, or on an intensive care unit.

The ability to isolate and ventilate either of a patient's lungs has the advantage of reduced inventory for hospitals: the device of the present invention avoids the need to stock separate components for isolation of the left and right lungs respectively.

The positive engagement of the two bronchial tubes of the device of the invention with a patient's carina can enable each of the bronchial tubes to be kept shorter than in known devices which have just one bronchial tube. Such short tubes can provide satisfactory isolation of the individual bronchi. They can enable access to be gained to structures close to the junction between each bronchus and the trachea, for example for ventilation of the right upper lobe bronchus or to drain collected fluid from it.

If a user needs to confirm that the device of the invention has been properly located in a patient's trachea, its position might be confirmed using conventional auscultation techniques, for example a stethoscope. It might be determined by observing differential chest movements, especially after the formation of one or more seals using the cuffs on the device. Bronchoscopic or x-ray techniques can be used to verify that the bronchial tubes have been properly located in the respective bronchi. It can be preferred for the bronchial tubes (or seals on the tubes) to have markings which enable them to be identified after location in the patient's airway, so that the surgeon can determine which of the tubes has been located in the respective bronchi. For example, the tubes can be provided with colour coded markings.

The provision of separate bronchial tubes in the device of the invention has the further advantage that both bronchi can be accessed by other components which are advanced into the lung via the tracheal tube (for example a suction catheter) which can be advanced along the appropriate bronchial tube. This is in contrast to known devices with just one bronchial tube which can only be used reliably to advance a suction catheter tube or other apparatus into the bronchus in which the bronchial tube is located.

The arrangement of the tracheal and bronchial tubes will generally be arranged so as to provide a comfortable fit in the patient's airways. The angle between the bronchial tubes will generally be at least about 55°, preferably at least about 65°, for example about 70°. The angle between the right bronchial tube and the tracheal tube will preferably be greater than the angle between the left bronchial tube and the tracheal tube. Preferably, the difference between the two said angles is at least about 15°, for example about 20°. Matching the patient's anatomical features in this way is relatively more important in the case of the embodiment in which the tracheal tube sections and the bronchial tubes are used themselves for the flow of breathing gas, when it will be desirable for the size of the components to be as large as reasonably possible to optimise flow of gas. The tracheal tube will generally have a rounded cross-section, especially substantially circular. Preferably, the cross-sections of the first and second tracheal tube sections are approximately D-shaped, the tube sections being arranged so that the rounded walls face outwardly and provide the outer walls of the tracheal tube. The flattened walls of the D- shaped tracheal tube sections can then provide a web which extends along the tracheal tube, generally approximately along the centre of the tube so as to divide it into tube sections of approximately equal sizes. The web along the centre of the tracheal tube can help to support the tracheal tube against collapse when exposed to transverse compressive forces or other forces which might tend to cause the tube to kink. The contribution to the structural integrity of the device from the dividing web can allow the wall thickness of the curved outer walls to be kept small. This can mean that the resistance to flow of air through the tube can be minimised.

Preferably, the device has a bore in the tracheal tube between the flat walls of the tracheal tube sections. The bore can enable the tracheal tube to be split so as to separate the tracheal tube sections which can then provide the bronchial tubes. The device can therefore provide a continuous passage for flow of breathed gas without any discontinuity at the junction between the tracheal tube and the bronchial tubes. This enables resistance to airflow at the junction due to such a discontinuity to be avoided.

It is preferred for the cross-sections of the tracheal tube sections and the bronchial tubes to be approximately the same, at least at the junction between the tracheal tube and the bronchial tubes. Preferably, the cross-sections of the first and second bronchial tubes, and especially also the tracheal tube sections, are approximately D-shaped, at least at the junction between the tracheal tube and the bronchial tubes. However, the bronchial tubes can be formed into a different shape towards their free ends; for example, bronchial tubes that have a D-shaped cross-section can be formed (for example at an elevated temperature) to make their cross-section more round, especially closer to circular.

Preferably, each tracheal tube section and its corresponding bronchial tube are formed continuously as single components so that there is no discontinuity between them which could provide resistance to airflow. Preferably, the tracheal tube sections are formed as a single component so that the bronchial tubes are formed by splitting a two chamber tube along part of its length. However, in an alternative arrangement, the tracheal tube can be formed by attaching two tracheal tube sections together, for example by means of an adhesive or by heating the material of the tube sections locally to cause it to fuse, or mechanically such as by binding, for example using a wound tape.

Preferably, the sealing cuff or cuffs are inflatable and the device includes conduit means for supplying an inflation fluid to the cuffs. The inflation fluid can be a gas or a liquid. An example of a suitable inflation fluid is air, especially as pumped with a syringe or manually squeezable bladder. An alternative fluid might be a saline solution, which can be introduced using a syringe. Preferably, the conduit means comprises separate conduits for supplying inflation fluid separately to each of the sealing cuffs. The conduit means can be a part of a structure which is separate from the tracheal tube and the bronchial tubes. Preferably, however, the conduit means comprises one or more bores that is formed in the wall of the tracheal tube. Such a bore can be formed in the tube wall by a process such as extrusion.

The device of the invention can provide the advantage of isolation of the separate bronchi when it has sealing cuffs on just one or two of the tracheal tube and the two bronchial tubes (whether isolation is achieved by blocking one bronchus against gas flow so that breathing gas is supplied to the other bronchus through the patient's natural airway, or by supply of breathing gas to one bronchus through one of the bronchial tubes, as discussed above). For example, sealing cuffs might be provided on each of the bronchial tubes, or on the tracheal tube and the first bronchial tube or the second bronchial tube. When the device is intended for supply of breathing gas through the tracheal tube sections and the bronchial tubes, it is preferred that it has sealing cuffs on each of the tracheal tube, and the first and second bronchial tubes so that seals can be made as desired between any of the trachea and the tracheal tube, the first bronchial tube and the left bronchus, and the second bronchial tube and the right bronchus. An advantage of providing sealing cuffs on the tracheal tube and on both of the bronchial tubes is that the device can be used to isolate the individual bronchi even in the event of one of the sealing cuffs becoming damaged, or one of the seals provided by the sealing cuffs failing, for example as a result of the sealing cuff being dislodged within the trachea or the bronchus.

When the device includes a sealing cuff on the right bronchial tube, it is preferred that the cuff is arranged on the right bronchial tube so as to reduce obstruction of the right upper lobe bronchus. The sealing cuff can have a substantially constant depth across the tube and be inclined to the axis of the tube. Alternatively or in addition, the sealing cuff might have a reduced depth in the vicinity of the right upper lobe bronchus. It is also possible for obstruction of the right upper lobe bronchus to be avoided by trimming the bronchial tube short of the bronchus, preferably on a plane that is inclined to the axis of the right main bronchus.

Preferably, the configuration of the device can be changed between an in-use configuration in which bronchial tubes splay outwardly, and an insertion configuration in which the bronchial tubes are closed together for insertion of the device into a patient's trachea. This enables the advantages of the invention that arise from the separate bronchial tubes to be obtained even with a device in which the in-use configuration would otherwise make it difficult to advance the device into a patient's larynx and through the trachea.

Preferably, the device of the invention is capable of being resiliently deformed from one of its configurations towards the other configuration, and then of recovering at least partly back to the original configuration. For example, changing the configuration of the device from the in-use configuration to the insertion configuration can involve deforming the device resiliently, and changing the configuration from the insertion configuration to the in-use configuration involves allowing the device to relax. The reverse arrangement might be used instead. Preferably, the device is used with means for changing the configuration between the insertion and in-use configurations. For example, the invention might include means for forcing diverging bronchial tubes inwardly towards one another so that the device can be advanced into the trachea, especially when the bronchial tubes have a relatively large size, such as when they are intended to provide the passageway for breathing gas to flow into and out of the bronchi. A preferred example of an insertion instrument which is suitable for this purpose is a sleeve which the device can fit into when the bronchial tubes are forced together, which can be retracted once the device has been advanced to a desirable position in the trachea leaving the device in place where the bronchial tubes can diverge. Another insertion instrument might comprise a drawstring which extends to about the ends of the bronchial tubes which can be tensioned from the proximal end of the device. For example, the drawstring might extend between the bronchial tubes and, when tensioned, cause the bronchial tubes to be forced inwardly towards one another. The drawstring might extend to the ends of the bronchial tubes along the outside facing edges thereof and, when tensioned, cause the bronchial tubes to diverge. Features of an assembly which comprises a device according to this invention and an insertion instrument for the device are disclosed in the patent application filed with the present application which claims priority from UK patent application no. 0030476.6 and features which are disclosed in that document can be applied to the device referred to in this specification and its installation.

The device of the invention can be configured for oral introduction or through a tracheotomy stoma. The length of the tracheal tube will be greater when the device is intended for oral introduction than for when the device is intended for introduction through a tracheotomy stoma, generally as known in existing bronchial ventilation devices. The device can include an adjustable flange for fixation to the patient's neck when it is intended for introduction through a tracheotomy stoma.

The device of the invention can be provided in a range of sizes. When breathing gas is to be supplied through the bronchial tubes, it is preferred that the cross-sectional area of each of the bronchial tubes is at least about 15 mm². Devices that are suitable for use by adult patients can have a bronchial tube cross-sectional area of at least about 22 mm², or at least about 25 mm², or larger such as at least about 35 mm² or more.

The device of the invention can be used in open thoracic surgery such as for example a lobectomy, closed thoracoscopic procedures such as lung resection, treatment of pleural disease and sympathectomy. It can also be used in oesophageal surgery and thoracic aortic surgery. It can be used for ventilation of patients on an intensive care unit as discussed above, in particular because of the reduced risk of trauma in a patient's tissues because of the use of more flexible materials that those used hitherto.

Embodiments of the present invention will now be described, by way of example, with reference to the accompanying drawings in which:

Figure 1 is a side view of a ventilation device according to the invention.

Figure 2 is a cross-sectional view of the tracheal tube of the device shown in Figure 1.

Figure 3 is a front view of a patient's thoracic region (with the trachea exposed) showing a device as shown in Figure 1 during placement using a first introducer.

Figure 4 is another front view of the patient's thoracic region, showing the device in place in the patient's bronchi.

Figure 5 is a side view of another device with a second introducer.

Figure 6 is a side view of a device as shown in Figure 5 in place in the configuration in which it might be used in a patient's bronchi.

Figures 7a and 7b show a device in a patient's airway, in which the seals on the tubes are inflated to close the bronchi against flow of breathing gas.

Referring to the drawings, Figures 1 and 2 show a ventilation device 2 which comprises a tracheal tube 4 and first and second bronchial tubes 6, 8. The device is formed from a polymeric material such as polyvinyl chloride by extrusion. As shown in Figure 2, the trachea tube comprises first and second tube sections 10, 12. Each of the tube sections is substantially D-shaped when viewed in cross-section. A narrow bore 14 is provided between the facing flat walls of the tube sections. The bronchial tubes are provided by slitting the narrow webs 16, 18 which extend between the facing flat walls of the trachea tube sections in the extrusion, and by trimming the webs from the slit extrusion. Preferably, the bronchial tubes are reformed while heated to an elevated temperature so that their cross-section becomes more rounded. Preferably, the ends of the bronchial tubes are rounded to minimise risk of snagging on airway tissue.

The bronchial tubes are made to diverge, as shown in Figure 1 , by heating the device to a temperature slightly below the temperature at which the polymer loses its form, and then forming the device to the desired configuration in which it is held while the device is allowed to cool.

The cross-sectional area of each of the trachea tube sections, and therefore also of the bronchial tube sections, is about 20 mm². Smaller device might be appropriate for smaller patients, including children.

The second bronchial tube 8 is intended to be placed in the right bronchus in a patient. It has an opening 20 in its side wall for ventilation of the right upper lobe bronchus. Obstruction of the right upper lobe bronchus can also be avoided by making the right bronchial tube short, especially by trimming it inclined to the axis of the bronchial tube.

Inflatable sealing cuffs 22, 24, 26 are provided on each of the bronchial tubes and on the tracheal tube. Each of the sealing cuffs is formed from a thin sheet of a polymeric material such as a polyester, which is bonded to the respective tube around its periphery. Each of the cuffs can be inflated into contact with the trachea or the bronchus in which it is located when in use, to form a seal. The seals can be inflated by means of a fluid, especially air which is admitted using a manually operated pump or a syringe as is known. Bores 28, 30, 32 are provided in the extrusion for the inflation fluid to be supplied to the sealing cuffs (see Figure 2).

Figure 3 shows the device described above within an insertion sleeve 40 which forces the bronchial tubes 6, 8 towards one another so that the cross-section of the device in the region of the bronchial tubes is similar to that of the tracheal tube. This allows the device to be advanced through the patient's trachea 42. A lubricant can be provided between the sleeve and the device, for example a lubricant such as a typical sterile gel. The insertion sleeve has a 15 mm diameter connector 43 at its proximal end which can engage a corresponding connector on ventilation apparatus so that the sleeve can be used to ventilate the patient's lungs. The sleeve also has laterally extending wings 44 which can be gripped to apply transverse force to the sleeve to cause it to split along its length.

As shown in Figure 4, the device of the invention can be restored to its in-use configuration after it and the insertion sleeve 40 have been advanced sufficiently through a patient's trachea. This will generally be appropriate when the distal end is close to the carina 44. The sleeve can be withdrawn by the user, or the device advanced through the sleeve so that at least the bronchial tubes and possibly also a part of the tracheal tube extend from it. Removal of the sleeve can be facilitated by making it splittable. For example, the sleeve might have a line of weakness extending along its length along which it can be split. Splitting the sleeve can be initiated proximally by the user.

Figure 5 shows a device 60 constructed generally as described above with reference to Figures 1 and 2. The device includes two additional bores in the extrusion, similar to the bores 28, 30, 32 shown in Figure 2, for a drawstring 66. The line extends continuously from the proximal end of the tracheal tube through one of the bores, across the end of distal ends of the bronchial tubes 6, 8, and through the other of the bores to the proximal end of the tracheal tube. The line can then be manipulated by the user.

In the configuration shown in Figure 5, the bronchial tubes are forced together so that the device can be advanced through a patient's trachea. This is achieved by applying tension to the drawstring 66, as indicated by the arrows 68.

When the device shown in Figure 5 has been advanced to the vicinity of the carina 69, tension on the drawstring 66 can be relaxed allowing the bronchial tubes 6, 8 to diverge. Continued advancement of the device into the trachea causes the bronchial tubes to pass into the bronchi, the drawstring 66 resting over the carina. Fluid can then be supplied to the sealing cuffs 22, 24, 26 through the bores in the tracheal tube to cause the cuffs to inflate to form seals to the patient's tissue. The patient's bronchi can then be ventilated selectively. The bronchial tubes can also be used to direct a suction catheter tube 74 reliably into the left or right bronchus, for example into the right bronchus as shown in Figure 6.

In an alternative construction, a drawstring can extend along the ventilation device and be fixed to the ends of the bronchial tubes. The tubes are configured so that they tend towards a configuration in which they are close together. The device is made from a resilient material so that the configuration of the device can be changed to one in which the tubes diverge. Changing the configuration of the device is achieved by applying tension to the drawstring; this can be done when the device has been advanced through the patient's airway until the end of the device is in the vicinity of the carina. Tension applied to the drawstring causes the bronchial tubes to diverge so that they can be advanced into the bronchi.

Figures 7a and 7b show a device in which the bronchial tubes 80, 82 are intended for blocking a patient's bronchi against flow of breathing gas. The tubes are open at their distal ends 84 to provide a lumen for passage of a small quantity of breathing gas, or for insertion of an instrument such as a bronchoscope. The tubes can however be closed at their distal ends Each of the tubes has an inflatable cuff 86, 88 on it which can be inflated by means of gas that is supplied to it through a conduit in the wall of the respective tube. When the tubes are open at their distal ends, each tube will be a double lumen tube, with one lumen being for inflation gas and the other lumen being open at the distal end. In the illustrated embodiment, the bronchial tubes are formed integrally with respective tracheal tube sections. The cross-sectional area of the bronchial tubes is kept as small as reasonably possible, consistent with being able to supply sufficient gas to the cuffs 86, 88 to be able to inflate them. Other features of the devices described with reference to Figures 1 to 6 (for example materials, shapes, construction details etc) can be included in the device shown in Figures 7a and 7b.

In each of Figures 7a and 7b, the device is shown located in a patient's airway with the bronchial tubes extending past the carina, located in respective bronchi. Figure 7a shows the cuff 86 within the left bronchus inflated so that the left bronchus is occluded against flow of breathing gas. The patient is then able to breathe through the right bronchus. The arrangement is reversed in Figure 7b.

Claims

CLAIMS:

1. A bronchial ventilation device which comprises first and second bronchial tubes for insertion into the left and right bronchi respectively, and a tracheal tube which includes first and second tracheal tube sections which communicate with the first and second bronchial tubes respectively, the device including at least one sealing cuff which enables a seal to be formed between (a) the tracheal tube and the trachea, (b) the first bronchial tube and the left bronchus, or (c) the second bronchial tube and the right bronchus, to enable isolation and separate ventilation of the two bronchi.

2. A device as claimed in claim 1, in which the cross-sections of the first and second tracheal tube sections are approximately D-shaped, the tube sections being arranged so that the rounded walls face outwardly and provide the outer walls of the tracheal tube.

3. A device as claimed in claim 1 , in which each of the bronchial tubes is closed at its distal end.

4. A device as claimed in claim 3 , which includes a sealing cuff on each of the bronchial tube sections, and in which there is no sealing cuff on the tracheal tube.

5. A device as claimed in claim 1, which includes a bore in the tracheal tube between the walls of the tracheal tube sections.

6. A device as claimed in claim 1, in which the cross-sections of the first and second bronchial tubes are approximately D-shaped.

7. A device as claimed in claim 1, in which the cross-sections of the first tracheal tube section and the first bronchial tube are substantially the same.

8. A device as claimed in claim 1 , in which the sealing cuff is inflatable and the device includes conduit means for supplying an inflation fluid to the cuff.

9. A device as claimed in claim 8, in which the conduit means comprises separate conduits for supplying inflation fluid separately to each of the sealing cuff.

10. A device as claimed in claim 8, in which the conduit means comprises a bore that is formed in the wall of the tracheal tube.

11. A device as claimed in claim 1 , which includes a sealing cuff on the right bronchial tube, the right bronchial tube sealing cuff arranged on the right bronchial tube so that it reduces obstruction of the right upper lobe bronchus.

12. A device as claimed in claim 1, which includes sealing cuffs which enable seals to be formed between at least two of (a) the tracheal tube and the trachea, (b) the first bronchial tube and the left bronchus, and (c) the second bronchial tube and the right bronchus, to enable isolation and separate ventilation of the two bronchi.

13. A device as claimed in claim 1, which includes sealing cuffs on each of the tracheal tube, and the first and second bronchial tubes.

14. A device as claimed in claim 1, in which the configuration of the device can be changed between an in-use configuration in which bronchial tubes splay outwardly, and an insertion configuration in which the bronchial tubes are closed together for insertion of the device into a patient's trachea.

15. A device as claimed in claim 14, in which changing the configuration of the device from the in-use configuration to the insertion configuration involves deforming the device resiliently, and changing the configuration from the insertion configuration to the in-use configuration involves allowing the device to relax.

16. A device as claimed in claim 14, which includes means for changing the configuration between the insertion and in-use configurations.