Oxygen distributor

Abstract

An oxygen distributor (1) positionable, in use, in a wound for supplying oxygen to the wound has an oxygen delivery area (17) for, in use, receiving a supply of oxygen. At least one tube (19A) extends from the oxygen delivery area, having a tube wall with an oxygen-permeable, liquid-impermeable section. Oxygen delivered to the oxygen delivery area can flow away from the oxygen delivery area along the, or each, tube.

Claims

1. An oxygen distributor to supply oxygen to a wound, the oxygen distributor comprising: an oxygen delivery area to receive a supply of oxygen; and a plurality of tubes in fluidic communication with the oxygen delivery area, each of the plurality of tubes having a tube wall, wherein the tube wall of at least one of the plurality of tubes includes an oxygen-permeable, liquid-impermeable section, and wherein there is at least one open region defined between or among the plurality of tubes to enable exudate from the wound to flow away from the wound, the at least one of the plurality of tubes arranged such that oxygen delivered to the oxygen delivery area flows away from the oxygen delivery area along the at least one of the plurality of tubes for delivery to the wound via the oxygen-permeable, liquid-impermeable section.

2. The oxygen distributor of claim 1, wherein at least one of the plurality of tubes is curved.

3. The oxygen distributor of claim 1, wherein at least one of the plurality of tubes is substantially straight.

4. The oxygen distributor of claim 1, wherein the plurality of tubes comprise at least one substantially straight tube and at least one curved tube.

5. The oxygen distributor of claim 1, wherein the oxygen delivery area comprises a delivery tube.

6. The oxygen distributor of claim 5, wherein the plurality of tubes extend from different positions around or along the length of the delivery tube.

7. The oxygen distributor of claim 1, wherein the tube wall of at least one of the plurality of tubes further includes an oxygen-impermeable, liquid-impermeable section.

8. The oxygen distributor of claim 1, wherein the tube wall of each of the plurality of tubes is liquid-impermeable.

9. The oxygen distributor of claim 1, wherein each of the plurality of tubes has a tube wall including an oxygen-permeable, liquid-impermeable section, and wherein at least some of the plurality of tubes have closed ends.

10. The oxygen distributor of claim 1, wherein the at least one open region is defined between two tubes of the plurality of tubes.

11. The oxygen distributor of claim 1, wherein the at least one open region is defined between two tubes of the plurality of tubes, wherein the two tubes extend radially from the oxygen delivery area.

12. The oxygen distributor of claim 1, wherein the at least one open region comprises at least 50% of the total area of the oxygen distributor, the total area being defined by the perimeter of the oxygen distributor.

13. The oxygen distributor of claim 1, where the oxygen distributor is substantially rectangular in shape.

14. An oxygen distributor to supply oxygen to a wound, comprising: an oxygen delivery area to receive a supply of oxygen; a curved tube in fluidic communication with the oxygen delivery area and having a tube wall, wherein the tube wall includes an oxygen-permeable, liquid-impermeable section, and wherein the curved tube surrounds an open region that enables exudate from the wound to flow away from the wound, the tube arranged such that oxygen delivered to the oxygen delivery area flows away from the oxygen delivery area along the tube for delivery to the wound via the oxygen-permeable, liquid-impermeable section.

15. The oxygen distributor of claim 14, wherein the curved tube extends to a peripheral edge of the oxygen distributor.

16. The oxygen distributor of claim 14, where the oxygen distributor is substantially circular in shape.

17. The oxygen distributor of claim 14, wherein the open region comprises at least 50% of the total area of the oxygen distributor, the total area being defined by the perimeter of the oxygen distributor.

18. The oxygen distributor of claim 14, wherein the open region comprises at least 60% of the total area of the oxygen distributor, the total area being defined by the perimeter of the oxygen distributor.

19. The oxygen distributor of claim 14, wherein the tube wall further includes an oxygenimpermeable, liquid-impermeable section.

20. The oxygen distributor of claim 14, wherein the tube wall is liquid-impermeable.

Description

SPECIFIC DESCRIPTION OF THE PREFERRED EMBODIMENT

(1) An embodiment of the invention will now be described, by way of example, and with reference to the accompanying drawings in which:

(2) FIG. 1 is a top view of an oxygen distributor, in the form of an oxygen distribution web according to an embodiment of the invention.

(3) FIG. 2 is a vertical section, on A-A, of the oxygen distribution web of FIG. 1.

(4) FIG. 3 is a plan view of the oxygen distribution web in FIG. 1, showing the cutting area.

(5) FIG. 4 is a graph showing an increase in oxygen concentration at a simulated wound site, using the oxygen distribution web of FIGS. 1 to 3.

(6) An oxygen distributor in the form of a web 1 according to an embodiment of the invention is shown in FIGS. 1-3. An upper, oxygen-impermeable, liquid-impermeable layer 3 manufactured from co-extruded EVA/PVDC (NEXCEL® MF513) and a lower, oxygen-permeable, liquid-impermeable layer 5 manufactured from polyurethane porous film (TREDEGAR® BF519W) are cut to shape and sealed together in tracks to form strands of the web. Specifically, there is a central, inner track 7 in the form of a ring, six straight radial tracks or spokes 9 extending from the inner track, an outer, circumferential track 11, and a single straight track in the form of a tab 15 which protrudes outwardly from the circumferential track, aligned with one of the six radial tracks. The inner track defines a central exudate hole 8, and a further six exudate holes 12 are defined between the inner track, radial tracks and circumferential track. The circumferential track defines an outer edge of an oxygen distribution portion 29 of the web.

(7) Defined within the inner track 7 is an oxygen delivery area or manifold 17 in the form of a ring-shaped oxygen delivery tube. Emanating from the oxygen delivery area are five, radial tubes 19A, defined in five of the six radial tracks 9. Each of the five radial tubes branches to form a circumferential or branching tube 21 defined within the circumferential track 11. Each of the five radial tubes and their connected circumferential tubes forms an independent sub-network of tubes which, except at the oxygen delivery area, are not interlinked to other sub-networks. The circumferential tubes of neighbouring sub-networks are separated from each other by sealed portions 23 of the circumferential track, which create closed ends in the circumferential tubes. Nevertheless the circumferential track physically restrains the closed tube ends in the plane of the distributor.

(8) A long, straight radial tube 19B is defined in one of the radial tracks 9, across the circumferential track 11 and along the tab 15. This tube does not branch to form a circumferential tube. Rather, it extends from the oxygen delivery area 17 to the outer edge of the tab 15.

(9) FIG. 2 shows a cross section of one of the radial tracks 9 with one of the radial tubes 19A defined within it. On each side of the tube, the oxygen-impermeable, liquid-impermeable layer 3 is sealed to the oxygen-permeable, liquid-impermeable layer 5.

(10) Each tube 17, 19A, 21 is defined between the oxygen-impermeable, liquid-impermeable layer 3 and the oxygen-permeable, liquid-impermeable layer 5. Porous material in the form of polyurethane open cell foam 6 (CORPURA® MCF03) is distributed within each tube. The porous material is shown specifically in FIG. 3.

(11) An oxygen delivery means 13, in the form of a plastics conduit (liquid-impermeable and gas-impermeable) is positioned and sealed at one end within the long radial tube 19B. The oxygen delivery means has a delivery end 13A which is positioned at the oxygen delivery area 17. At its opposite end the oxygen delivery means has a connecting end 14 for connecting to an oxygen supply.

(12) For most of their length, each tube 17, 19A, 21 has a width of 1.5 to 2 mm. This is a minimum width of the tube. Where the tubes intersect to form junctions 25, the width may be greater than this and is about 4 to 5 mm. Each tube has a maximum height of approximately 1 to 2 mm.

(13) The maximum cross-sectional area of each tube is approximately 5 mm.sup.2 but for most of the length of each tube, where the tube has a minimum width, the cross-sectional area is approximately 1.5-3 mm.sup.2.

(14) The short radial tubes 19A have a length of approximately 15 mm and the long radial tube 19B has a length of approximately 50 mm, with the distance between the outer edge of the tab 15 and the delivery end 13A of the oxygen delivery means being approximately 46 mm.

(15) The diameter of the oxygen delivery web 1 defined between outer edges of the circumferential track 11 is approximately 60 mm.

(16) A cutting area 27 as shown by the shaded part in FIG. 3, is defined between the inner track 7 and the outer edge of the outer, circumferential track 11.

(17) The circumferential track defines the outer edge of an oxygen distribution portion 29 of the web, for delivering oxygen to a wound, which excludes the tab 15 and the oxygen delivery means 13.

(18) In use, the oxygen delivery means 13 is connected to an oxygen supply (not shown) and the oxygen distribution portion 29 of the web 1 is placed in a wound (not shown). A wound dressing such as an absorbent dressing, a gauze and/or compression bandage (not shown) is placed over the web. Oxygen at a pressure greater than atmospheric pressure is fed from the oxygen supply through the oxygen delivery means 13 to the oxygen delivery area 17. Oxygen is able to pass from the oxygen delivery area through each of the short radial tubes 19A, towards the periphery of the web and through each circumferential tube 21. As the oxygen passes through the oxygen delivery area, through each short radial tube and through each circumferential tube, it is able to permeate through the oxygen-permeable, liquid-impermeable layer 5 to the wound, thus distributing oxygen across the wound surface and increasing a concentration of oxygen at the wound site.

(19) Wound exudate produced at the wound site is able to pass through the exudate holes 8, 12 and away from the wound site. Typically, an absorbent dressing is placed over the web 1 to protect the wound and absorb exudate which has passed through the exudate holes.

(20) In certain circumstances, for example when dealing with small wounds, it is desirable to cut the web 1 to reduce its area. If this is required, cutting takes place in the predetermined cutting area 27.

(21) The tubes in the cutting area are arranged such that if a single straight cut is made across the cutting area 27 to reduce the area of the web, no more than four tubes can be cut across, and no more than two short radial tubes 19A are cut across. An example of a possible single, straight cut, cutting across a total of four tubes (including only two short radial tubes 19A) is shown by line A in FIG. 3.

(22) FIG. 3 also demonstrates how a significant area of the web can be cut whilst only cutting across one tube. Line B shows how the dressing can be cut across two of the sealed areas 23 in the circumferential track 11 and across one of the radial tracks 9 such that only one short radial tube 19A is cut across. Only one sub-network is therefore affected by the cutting.

Example

(23) Oxygen Distribution Web Performance in Raising and Maintaining an Oxygen Enriched Headspace

(24) Apparatus:

(25) Oxygen distribution web (as shown in FIGS. 1 to 3 above). Perspex® slab pre-drilled to house the oxygen delivery web. Alphasense® Ltd Oxygen sensor calibrated each evaluation (Alphasense Ltd supply the sensor calibrated for use in air and specifically designed for use in safety critical portable instruments used by those subject to life threatening oxygen levels in their work place). Digital Volt Meter (DVM) (serial No 1100391805) set to display milliamp (mA) current. A disc of hydrophobic, gas-permeable material sold under the trade mark Tredegar® (equivalent to the lower, gas-permeable, liquid-impermeable layer of the oxygen distribution web). Natrox™ oxygen supply device (serial No 110212-35)—For supplying a continuous flow (12 ml/hr) of humidified oxygen. Gauze pad—Crest Medical 8 ply. A single layer compression bandage. 2 ml of Synthetic exudate (5% Xanthum Gum with water).

(26) The oxygen sensor is configured to monitor oxygen concentration in air. Atmospheric oxygen (21%) produces a signal of ˜0.097 mA. This signal increases in proportion to the oxygen concentration present at the sensor surface.

(27) Method:

(28) The oxygen sensor is mounted flush with the surface of a Perspex® fixture. To protect the sensor from exudate, the disc of Tredegar® hydrophobic material is placed over the sensor and sealed using tape. Synthetic exudate is smeared on the Tredegar® surface and the oxygen delivery web is placed on this, followed by gauze and finally the single layer compression bandage. The sensor is calibrated in air and the Natrox™ oxygen supply is connected to the oxygen distribution web. The time is noted and periodic readings are taken.

CONCLUSIONS

(29) A DVM reading of 0.147 mA corresponds to an oxygen concentration of 29.76% at the ‘wound surface’, and this is achieved within 3 hours of connection to the Natrox™ oxygen supply.

(30) Therefore, the dressing combination above led to an approximate 50% rise in oxygen concentration at the ‘wound’ surface, which was maintained until the experiment terminated after 5 hours (See FIG. 4).