Inflatable Stent

Abstract

An inflatable stent for use in the repair and maintenance of pipes such as water or gas supply pipes, or for use as a medical device comprises an inflatable portion having an inner and outer membrane. When inflated, the inner and outer membranes are radially spaced apart to define an annular space there between. The inner membrane defines a passage between a first and second end and the outer membrane defines a first diameter (D1) of the stent. The inner and outer membranes are connected by a plurality of connecting members in the annular space. End caps are disposed on the first and second ends of the stent which connect the inner and outer membranes. The inflatable portion further comprises an inflatable pipe or lumen engaging portion that defines a second, larger diameter (D2) of the stent, when inflated.

Claims

1. An inflatable stent comprising an inflatable portion that comprises: an inner membrane of a flexible sheet material defining a first end and a second end of the inflatable portion, and a passage there between when inflated; and an outer membrane of a flexible sheet material disposed about the inner membrane, the outer membrane defining a first diameter of the stent when inflated; wherein, when inflated, the inner and outer membranes are radially spaced apart to define an annular space there between; the inner and outer membranes are connected by a plurality of connecting members in the annular space, and by first and second end caps that connect the membranes at the respective first and second ends of the inner membrane; and wherein the inflatable portion is further provided with at least one inflatable pipe or lumen engaging portion that defines a second, larger diameter of the stent, when the inflatable portion is inflated.

2. The inflatable stent of claim 1 wherein the inflatable portion of the stent is provided with a plurality of inflatable pipe or lumen engaging portions.

3. The inflatable stent of claim 1 wherein an inflatable pipe or lumen engaging portion is provided at or near each end of the inflatable portion of the stent; optionally wherein at least one further inflatable pipe or lumen engaging portion is provided at another location along the length of the stent.

4. (canceled)

5. The inflatable stent of claim 1 further provided with a port providing fluid communication from the passage through the annular space and out of the outer membrane, at a location between the inflatable pipe or lumen engaging portions.

6. The inflatable stent of claim 1 wherein the inflatable pipe or lumen engaging portions are inflatable and are larger diameter, when inflated, parts of the outer membrane.

7. The inflatable stent of claim 1 wherein the inflatable pipe or lumen engaging portions are inflatable and formed as separate chambers; optionally wherein the inflatable pipe or lumen engaging portions are inflatable by being in fluid communication with the annular space and inflate when the annular space, or a part of the annular space, is inflated.

8. (canceled)

9. The inflatable stent of claim 1 further provided with a deployment rod for deploying the stent along a deployment path; optionally wherein the deployment rod includes an inflating tube for passage of an inflating fluid into the annular space.

10. The inflatable stent of claim 1 further provided with an inflating tube for passage of an inflating fluid into the annular space.

11. (canceled)

12. The inflatable stent of claim 9 wherein the deployment rod for deploying the stent passes through the passage and connects to the stent at the end distal or at the end proximal to that of a user deploying the stent.

13. The inflatable stent of claim 1 provided with a sealing membrane to block flow through the passage or redirect flow through a side port or a selected end of the stent.

14. The inflatable stent of any one of claim 1 wherein both the inner membrane and the outer membrane of the inflatable portion are generally cylindrical in form when inflated.

15. The inflatable stent of claim 1 wherein the connecting members are a plurality of membrane portions each extending from the inner membrane to the outer membrane; optionally wherein the membrane portions extend outwards from the inner membrane to the outer membrane and run along the axial length of the stent.

16. (canceled)

17. The inflatable stent of claim 15 wherein the membrane portions run along substantially the whole length of the inner membrane.

18. The inflatable stent of claim 15 wherein the membrane portions divide the annular space into a series of axially extending cells around its circumference; optionally wherein the axially extending cells are all in fluid communication with each other.

19. (canceled)

20. The inflatable stent of claim 18 wherein at least one end cap defines a circumferential space at an end of the stent that is in fluid communication with all of the cells or a selected cell or cells.

21. The inflatable stent of claim 18 wherein a plurality of membrane portions, or all of the membrane portions are made from a single sheet of flexible sheet material connecting alternately along the axial length of the inner membrane and then along the axial length of the outer membrane in a zig-zag arrangement to divide the annular space into cells.

22. The inflatable stent of claim 18 wherein a plurality of membrane portions, or all of the membrane portions are made from a single sheet of flexible sheet material bonding circumferentially along a portion of the inner membrane before extending radially to the outer membrane where it is bonded circumferentially along a portion before returning to the inner membrane, and so on to provide axially extending cells having a generally trapezoidal cross section.

23. The inflatable stent of claim 1 further comprising a second inflatable portion with a passage there through, wherein the inflatable portion and the second inflatable portion are connected to each other via a tubular portion of flexible sheet material, to provide flow through the stent as a whole.

24. A method of by-passing a section of pipe or a lumen, the method comprising: obtaining access to a section of pipe at two locations, one upstream and one downstream, to either side of a section of pipe to be by-passed; deploying an inflatable stent, according to claim 1, and having a passage there through, into each of the two locations; inflating the stents so as to obtain substantially sealing engagement with the inner walls of the pipe; providing a by-pass pipe running externally of the pipe from the upstream location to the downstream location; and providing a route of fluid communication from upstream to downstream through the passages of the inflatable stents and via the by-pass pipe to by-pass the said section of pipe.

25. The method of claim 24 further wherein: a third inflatable stent is provided and deployed through one of the access locations in the direction of the by-passed section of pipe, allow venting and or inspection of the by-passed section via a fluid communication.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0067] FIGS. 1a to 1d show an inflatable stent and various details of its structure;

[0068] FIGS. 2a, 2b show an alternative stent structure;

[0069] FIGS. 3a to 3f show an inflatable stem fitted with pipe or lumen engaging inflatable portions;

[0070] FIGS. 4a to 4c show optional features for an inflatable stent;

[0071] FIG. 5 shows an inflatable stent with wo inflatable portions;

[0072] FIG. 6a shows a prior art pipe by-pass system; and

[0073] FIG. 6b shows a pipe by-pass system making use of inflatable stents,

DESCRIPTION OF SOME EMBODIMENTS WITH REFERENCE TO THE DRAWINGS

[0074] FIG. 1 shows in schematic perspective view an inflatable stent 1, without the pipe or lumen engaging portions of a stent of the invention (see FIGS. 3, 4 and 5 and the description below for these).

[0075] The stent 1 is shown in its inflated state and is cylindrical, The stent 1 has an inner membrane 2 defining first and second ends 4, 6 and a passage 8 allowing through flow of fluid. In FIGS. 1 to 4 as follows the stent has only one inflatable portion 9. FIG. 5 (discussed below) shows an alternative arrangement with two inflatable portions,

[0076] Outer membrane 10 is spaced apart from inner membrane 2 and defines a first diameter D1 of the stent (FIG. 1b). Also visible in FIG. 1a is a port or valve 14 located in in one of the end caps 16, 18 provided at either end of the stent. Port 14 has been used to inflate the stent by filling it with inflation fluid,

[0077] Cross section view FIG. 1b (at dashed line A) shows the annular space 20 between membranes 2 and 10. Annular space 20 is divided, by connecting members 22 into a series of cells 24 that are axially extending (i.e. running in the direction from the first to the second ends). These can be more clearly seen in magnified view (FIG. 1c) of part B in FIG. 1b and further in FIG. 1d as discussed below.

[0078] The connecting members 22 take the form of portions of membrane sheet (“membrane portions”). The membrane portions 26 extend from the first end 4 to or towards the second end 6. They connect the inner and outer membranes 2, 10 and are joined in sealing engagement with them. FIG. 1d shows the same perspective view as FIG. 1a but with the inner membrane absent, to allow viewing of the connecting members 22 (membrane portions 26) which take the form of rectangular portions of flexible membrane sheet that run spaced apart and parallel between the ends 4,6 in this example, The extreme ends 28 of membrane portions 26 do not extend to meet and seal to end cap 16. Thus when inflating the device through inflation port 14, all the cells 24 are in fluid communication via the space between the extreme ends 28 arid the end cap 16. A similar arrangement may be provided at the other end 6 of the stent 1, which may aid in even and reproducible inflation from a deflated state.

[0079] FIG. 2a shows, in a cross section view like that of FIG. 1b, an alternative arrangement of connecting members 22. In this arrangement connecting members 22 also take the form of membrane portions 26 extending and connecting between the inner and outer membranes 2, 10. In contrast to FIG. 1c, the membrane portions 26 do not each extend along a radius. In FIG. 2a the cells 24 are generally trapezoidal in cross section but they alternate in location of the base 30 of each trapezoid around the circumference of the stent (see magnified view of part B in FIG. 2b). The arrangement in FIG. 2 may be formed by use of a single sheet of membrane material running circumferentially in a zig zag fashion in the annular space 20 with alternate bonding to the inner 2 and then the outer 10 membrane.

[0080] FIG. 3a shows in schematic perspective a stent 1 of the same general construction as those of FIG. 1 or 2 with like parts numbered the same, The stent of FIG. 3a also includes two inflatable pipe or lumen engaging portions 32. The pipe or lumen engaging portions 32 are spaced apart arid attached to the outer membrane 10 they define a second, larger, diameter D2 of the stent, as indicated in end view FIG. 3b. In this example both portions 32 define the same diameter D2, In other examples where the stent may not be a regular cylinder and/or the pipe or lumen engaging portions may have different sizes, the second diameter D2 may be defined as the largest provided.

[0081] FIG. 3c shows the stent 1 of FIGS. 3a, 3b in elevation. As can be seen in this view the pipe or lumen engaging portions 32 each have a largest diameter in the middle part (indicated on the figure by centre line 34) and relatively broad edges 36 where sheet material pieces are joined together. Dashed circles indicate the location of passages 38 communicating with the annular space to allow inflation. The structure is also shown in schematic cross section FIG. 3d taken through line X-X of FIG. 3c.

[0082] As can be seen in FIG. 3d the inflated pipe or lumen engaging portion 32 is attached to the outer membrane 10 at two regions 40 of bonding (e.g. RF welding). The two regions of bonding 40 run circumferentially around the diameter of outer membrane 10. In this example gap 42 between edges 44 of connecting member sub portions 46, 48 of connecting member membrane portion 22 allows access to make the circumferential bonds at the bonding regions 40 during the manufacturing process. Gap 42 also provides fluid communication between cells 24 (see FIG. 1c) defined by connecting members 22. In this example pipe or lumen engaging portion 32 is otherwise free from attachment to the rest of the stent and so can readily inflate radially outwards in direction Y. This may aid in making more positive (e.g. sealing) engagement with the wall of a pipe or lumen in use, for example if the pipe or lumen has some variance in diameter or is oval rather than a perfect circle in diameter.

[0083] FIG. 3e shows the same stent 1 as is shown in the other FIG. 3; but with only one of the two pipe or lumen engaging portions 32 shown. This allows viewing of the passages 38 that communicate with the annular space to allow inflation of the pipe or lumen engaging portion. In this example passages 38 are spaced circumferentially about outer membrane 10 and in alignment with the largest diameter part (indicated on the figure by centre line 34) of the pipe or lumen engaging portions 32,

[0084] FIG. 3f shows in a detail similar to FIGS. 1c and 2b a method of bonding membrane portions 26 to inner and outer membranes 2, 10, In this example end parts 41 of the membrane 26 illustrated are fused by RF welding to the inner and outer membranes.

[0085] FIGS. 4a, 4b and 4c show schematically some alternative arrangements that may be employed in inflatable stents.

[0086] In FIG. 4a a part of an inflatable portion 9 of a stent 1 is shown in part elevation view with the outer membrane 10 removed (position suggested by dashed lines 10a) to allow viewing of membrane portions 26. In this example they extend circumferentially in alignment with end cap 16 to divide the annular space 20 into cells 24 that each extend circumferentially with one cell 24 after another along the length of the inflatable portion,

[0087] In FIG. 4b an inflatable portion 9 of a stent 1 is shown in partial cross-section elevation view. End cap 18 has a profile projecting from the end 6 of inner membrane 2. This may serve to reduce pressure from a fluid flow suggested by arrow F acting to displace the inflatable portion from its selected location in a pipe or lumen.

[0088] In FIG. 4c a stent 1 having an inflatable portion 9 is shown in elevation. In this example the stent 1 is fitted with a deployment rod 50 that extends through the passage 8 of inflatable portion 9. The deployment rod 50 includes within it an inflating tube 52 that emerges from the rod 50 and connects to the valve 14 at the distal end (18 in this example) of the stent 1. When the stent 1 (typically in a deflated state rather than inflated as shown in the figure) is being inserted along a pipe or lumen by pushing the rod 50 in the direction of arrow I, then the connection of the inflating tube 52 to valve 14 results in the stent being pulled into position by rod 50.

[0089] At the proximal end 16 of the stent a number of cords 54 attach to the circumference of the outer membrane 10 arid to a more proximal (to a user) connection point 56 on the connecting rod, After use, when a user withdraws the stent by pulling in the direction W (typically after deflating or partially deflating) then the cords 54 allow the inflating portion 9 to be pulled from end 16 back out of the pipe or lumen.

[0090] Also included in this example is a camera and light assembly 58, which may also include other components such as gas sensors. The assembly 58 allows viewing of a pipe or lumen ahead of the stent 1.

[0091] FIG. 5 shows a stent 1 including two inflating portions 9 that are connected by a tube of reinforced flexible sheet material 60. The inflating portions are of the same general form as those shown in FIGS. 3, but only one inflatable pipe or lumen engaging portions 32 is provided on each portion 9. A port 62 can provide access to the passage 8, via end 16 or end 18 if required, For example; by a sensor or camera for inspection; for a delivery tube for filler material to reinforce or repair a pipe, or to allow purging and/or venting and/or monitoring of the external space between the inflatable portions 9,

[0092] FIG. 6a shows schematically a prior art arrangement for by-passing a pipe 64, such as a mains gas or water pipe. In this example access to pipe 64 has been made via flanged ‘tee’ connections 68 leading to hydrant valves 70, onto which an under pressure delivery system casing 72, for inflatable stopper bags 74, has been fitted. In FIG. 6a the bypass system is shown in use. Inflatable bags 74 have been inserted with the assistance of a delivery tube 76 that includes a ‘nose’ or stop 78 at its lower end. This nose 78 aids in delivery of the bags 74, and also, in the position shown, can aid in preventing inflating bags 74 being displaced by pressure and flow of fluid in the pipe 64.

[0093] Inflatable bags 74 have been inflated by inflating fluid delivered via ports 80 and appropriate inflating tubes (inflating tubes and other small details not shown in this schematic view). In some prior art systems the inflating fluid for bags 74 can be the fluid of the pipe 64, typically extracted at ports 82 and fed via a pump into ports 80. Bags 74 are provided with pipes 84 that connect through casing 72 to bypass pipe 86. Thus the flow along pipe 64 is diverted via by pass pipe 86 as indicated by arrows F, to allow work to be carried out in the bypassed pipe section 88. It will be understood that the flow direction may be reversed from that shown or there may be no flow, depending on the usage of the fluid in the pipe.

[0094] FIG. 6b shows an alternative by-pass making use of inflatable stents of the invention, shown in cross-section and generally of the form shown in FIG. 3a. Two inflatable stents 90 are allowing the by-pass flow F and each has an end 92 connecting from passage 8 to give sealed fluid communication to tube 94; and hence to by-pass pipe 86. In this example the ends 92 reduce in size from the larger diameter of passage 8 to the smaller diameter of tube 94. Thus section of 88 of pipe 64, between tee connections 88 is by passed. This arrangement allows secure placement of the stents 90 in pipe 64. Passages 8 and ends 92 can aid in providing good flow through in the by-pass via tubes 94. Furthermore the stents 90 are relatively low (inflated) volume devices that can readily be inflated to higher pressures, such as are required for higher pressure pipe systems.

[0095] FIG. 6b also shows optional inflatable stents 96, shown in cross-section and generally of the form shown in FIG. 3a. Each is placed via the respective delivery system through connections 68 as used for stents 90, but in the direction of the by-passed (isolated) section 88 of pipe 64, These stents 96 include an end 92 connecting from passage 8 to allow venting along a tubing connecting through and out of casing 72 as suggested by arrows V (venting tubes and other small details not shown in this schematic view). In this example the ends 92 reduce in size from the larger diameter of passage 8 to the smaller diameter of a vent tube. The section 88 can thus be vented if desired. Inspection by camera or other sensors through stents 96 can also be contemplated. In an alternative arrangement only one stent 96 may be employed, with venting and/or inspection available from the respective side of section 88.

[0096] If required the space between a stent 90 and a stent 96 may also be vented. For example, via a tubing connecting to a port on casing 72.