Controller For An Extremity Hyperbaric Device

Abstract

A controller is operable to selectively supply gas to, and evacuate gas from, regions of a hyperbaric wound treatment chamber. The controller operates to inflate a passage or rib of the device to provide that the device is made sufficiently rigid for inserting a limb therethrough, and inflate an inflatable cuff to create a seal against the limb. The controller also operates to evacuate ambient air trapped within the chamber, and optionally partially evacuate the passage or rib, after the seal is created by the inflatable cuff, and then introduce oxygen into the chamber, and optionally inflate the passage or rib. The cuff, when inflated and creating a seal against a limb, optionally is at least partially within the chamber, and the treatment gas is supplied to the chamber to maintain the seal of the cuff against the limb.

Claims

1. A method of operating a hyperbaric wound treatment device, wherein the device includes a chamber having an open end and an inflatable limb sleeve coupled to the chamber, the sleeve being positionable at least partially within the chamber at the open end, the method comprising: inserting a limb through the sleeve and into the chamber at the open end; and inflating the sleeve to an inflated condition when the limb is positioned within the sleeve, thereby sealing the sleeve about the limb.

2. The method of claim 1, wherein the sleeve is positionable such that a portion of the limb is insertable through the sleeve and into the chamber without the portion of the limb contacting the sleeve.

3. The method of claim 1, wherein the sleeve includes an outer wall and an inner wall defining an interior region therebetween, wherein the inflating includes supplying a gas under pressure to the interior region.

4. The method of claim 1, wherein the inflating includes introducing a gas into the sleeve until at least a partial seal is formed between the limb and the sleeve.

5. The method of claim 1 further comprising: supplying a gas into the chamber at a pressure sufficient to cause a portion of the sleeve within the chamber to form at least a partial seal between the limb and the sleeve, wherein the sleeve is positioned at least partially within the chamber.

6. The method of claim 1, wherein the sleeve includes an inner wall and an outer wall, wherein the outer wall has a thickness greater than a thickness of the inner wall, the method further comprising: inflating the sleeve to cause stretching of the inner wall while the outer wall remains substantially non-stretched.

7. The method of claim 6, wherein, when the sleeve is inflated to the inflated condition, the method further comprising: supplying a gas into the chamber at a pressure sufficient to have the pressure in the chamber exceed the pressure within the sleeve, whereby the pressure in the chamber causes the inner wall to form at least a partial seal against the limb.

8. The method of claim 7, wherein the pressure within the sleeve is up to about 1 psi.

9. The method of claim 6, wherein the inner and outer walls define respective inside and outside diameters, and wherein the inside diameter is reduced based on the inflating of the sleeve while the outside diameter is substantially unchanged.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] The various objects, advantages and features of this invention will be more fully apparent from a reading of the following detailed description in conjunction with the accompanying drawings in which like reference numerals refer to like parts, and in which:

[0018] FIG. 1 is a perspective view of an exemplary controller in accordance with one aspect of the present invention.

[0019] FIG. 2 is a view of the interior of the controller of FIG. 1.

[0020] FIG. 3 is a partial schematic, block diagram of exemplary control circuits under control of a control module of a controller in accordance with an embodiment of the present invention.

[0021] FIG. 4 is a flow chart of a process in accordance with an aspect of the present invention.

[0022] FIG. 5 is a partial schematic, block diagram of a controller coupled to a hyperbaric wound treatment device, in accordance with an aspect of the present invention.

[0023] FIG. 6 is a schematic illustration of an embodiment of a hyperbaric wound treatment device.

[0024] FIG. 7 is an illustration of an embodiment of a portion of the hyperbaric wound treatment device of FIG. 6.

[0025] FIG. 8 is a schematic illustration of another embodiment of a hyperbaric wound treatment device.

[0026] FIG. 9 is a schematic illustration of an embodiment of a seal for a hyperbaric wound treatment device.

[0027] FIG. 10 is a schematic illustration of a topical hyperbaric wound treatment device for use with a controller in accordance with the present invention.

DETAILED DESCRIPTION

[0028] FIG. 1 is a perspective view of a hyperbaric controller 10 adapted to control the operations of a flexible hyperbaric wound treatment device, in accordance with an aspect of the present invention. The controller 10 is desirably portable and can be easily picked up and moved to different operating locations by an operator. A housing 11 for the controller 10 includes side panels 12A, 12B, end panels 13A, 13B, a bottom panel (not shown) and a top panel 14. Although the embodiment of the invention discussed below and illustrated in the drawings is a flexible type wound treatment chamber, it is to be understood that the controller, in accordance with the present invention, also be may be utilized with a rigid type of wound treatment chamber, such as described in U.S. Pat. No. 5,060,644.

[0029] Referring to FIG. 1, the top panel 14 has indicators or pilot lights 68, 70, 72, which indicate operating modes or cycles such as fill ribs, fill cuff, and hyperbaric therapy, respectively, and switches 26, 28, 34 which control the operation of the controller 10 and are labeled cuff fill, stop and start, respectively. Thus, the controller 10 includes switches that are easy to understand and easy to use, and indicators that alert the user as to the particular operation being performed. In an alternative embodiment, in addition to the pilot lights, the indicators of the controller 10 may be in any other form, such as audio, visual or both.

[0030] Referring also to FIG. 2, air solenoid control valves 36, 38, 40 and pressure relief valves 42, 43, 44 are mounted to the rear side panel 12B of the housing 11. A vacuum pump 41 is mounted to the end panel 13A and a power supply 58, including a power switch 74 and a 120 VAC power supply cord 23, is mounted to the end panel 13B. The air solenoid control valves can be Clippard MME-3PDS (Clippard Instrument Laboratory, Cincinnati, Ohio), the pressure relief valves can be an Airtrol RV-5300-10-W/K (Airtrol Components Inc. New Berlin, Wis.) and the vacuum pump can be a Medo VP0125-V1005-D2-0511 (Medo USA, Hanover Park, Ill.). In addition to the air solenoid control valves, the controller 10 may incorporate any type of valve or the like to perform its operations, as known in the art. Further, in addition to the pressure relief valves, other types of valves may be utilized. In addition to the solenoids mentioned herein, proportional solenoids may also be utilized.

[0031] Still referring to FIG. 2 and also referring to FIGS. 3 and 5, treatment gas, such as oxygen, from a supply source (not shown) is admitted into the controller 10 via a port 45b, which is mounted to the side panel 12A, and routed to the supply ports of the respective control valves 36, 38, 40. Input and output ports 45c, 45d, and input and output port assembly 45e, are mounted to the side panel 12A and connected to the control valves 38, 36 and 40, respectively. The assembly 45e includes a conventional pressure sensor 145e, which is electrically connected to a microprocessor 60 of the controller 10. Pressure relief valves 42, 43, 44 are connected to the flow paths, respectively, between the control valves 36, 38 and 40 and the ports 45d, 45c and the port assembly 45e. The vacuum pump 41 is connected to the exhaust ports of the air control valves 38, 40. The exhaust ports of the relief valves 42, 43, 44, the vacuum pump 41 and the cuff control valve 36 are routed to a vent port 45a mounted to the side panel 12A. Tubing to interconnect the ports and port assemblies, the control valves, the relief valves and the pump can be conventional diameter tubing. Tubing for the exhaust lines connected to the vent port 45a can be conventional diameter tubing. Any device or configuration may be utilized to control the flow of gas, including air and treatment gas, being introduced into or evacuated from a chamber, a cuff or a rib of a wound treatment device.

[0032] Referring to FIGS. 2 and 3, the power cord 23 is fed to a switch 74 and to the power supply module 58 to generate +12V and +5V for powering electronic control circuits 90 in the controller 10. Control module 22 is attached to the top panel 14 and includes a programmable microprocessor 60 which is coupled to the control circuits 90 of the controller 10. As discussed in detail below, the microprocessor 60 of the control module 22 is operable to control the control circuits 90, which are coupled to the valves 36, 38, 40, to provide that gas may be conveyed to and from a hyperbaric wound device, through the valves 36, 38, 40. In one embodiment, the control module 22 can include a portion or all of the electronic circuitry of the control circuits 90 that connects to the control valves of the controller 10, and the operation of the microprocessor, the valves and the control circuits in combination can provide for conveyance of gas to and from a hyperbaric wound device. Any type of power configuration or power source may be utilized. For instance, the power source may be a battery.

[0033] Still referring to FIG. 3 and further referring to FIG. 5, the control circuits 90 are used to control the operation of each of the control valves 36, 38, 40 which provide for flow of gas, such as oxygen, to a flexible hyperbaric device 100. The 120 VAC power is applied by the main power switch 74 to power the supply module 58, which provides +12 V and +5 V for operating the control circuits 90. The control module 22 operates the functions of the controller 10, such as time, sequence, pressure sequence and intermittent compression. Intermittent compression is determined and regulated by the control module 22, optionally based on the pressure detected in a chamber 114 of the device 100 by the pressure sensor 145e, in accordance to techniques well known in the art.

[0034] The programmable microprocessor 60 provides for software program control of the controller 10. Although described in greater detail below, the microprocessor 60 generally includes instructions for operating the hyperbaric device 100, including a cuff 112, a rib 110 and the chamber 114, when in use. In one embodiment, the microprocessor 60 includes instructions on cycling, and cycles the gas in the chamber 114 of the device 100, desirably based on a signal received at B7 representative of the pressure in the chamber 114 as detected by the pressure sensor 145e. The microprocessor 60 receives a start signal from the switch 34, which is activated when the operator starts to prepare a patient for hyperbaric therapy. The microprocessor 60 provides output signals at ports A2, B1, B2, B3 to control the base of each transistor 62.sub.1, 62.sub.2, 62.sub.3, 62.sub.4, respectively. In an alternative embodiment, cycling may be done according to information input by the operator. The operator sets and adjusts the time for the therapy as desired. For example, for deep vein thrombosis (DVT), no cycling is performed.

[0035] The output current from the output signal ports A2, B1, B2, B3 is current limited with resistors 61.sub.1, 61.sub.2, 61.sub.3, 61.sub.4, respectively. The value of each of the resistors 61.sub.1, 61.sub.2, 61.sub.3, 61.sub.4 is desirably 1K ohms. Each control relay 52, 54, 56, 57 has a flyback diode 66 to suppress voltage transients which could otherwise damage the microprocessor 60. In addition to controlling the relays 52, 54, 56, 57, the microprocessor 60 also controls the three pilot lights fill ribs 68, fill cuff 70 and hyperbaric therapy 72. Each of the pilot lights 68, 70, 72 indicates to an operator of the controller 10 an operational cycle in which the controller 10 is actually operating. The pilot lights 68, 70, 72 are switched by transistors 62.sub.5, 62.sub.6, 62.sub.7, respectively, in response to an ON and OFF signal from the microprocessor 60. The microprocessor 60 may be Model PIC 16F84A, 8 bit microcontroller, with 1K bytes of internal ROM memory storage, manufactured by Microchip Technology, Inc. of Chandler, Ariz. The switching transistors 62.sub.1-62.sub.7 are commonly available 2N3904. The control relays may be Model G2R-1S-ASI-DC12 manufactured by Omron Electronics LLC of Schaumburg, Ill. The microprocessor 60 may be any type of computer, processor or an electronic component capable of performing instructions stored within it.

[0036] FIG. 6 shows a topical hyperbaric wound treatment device 100, as disclosed in U.S. Patent Pub. No. 2006/0185670, the disclosure of which is incorporated by reference, having a main chamber 114 including an interior 214 and an exterior 216. The chamber 114 is closed at one end 218 and open at the other end 220, and sized and shaped to define the interior 214 for receiving a patient's limb, for example, a leg 222. Adjacent the other end 220 is an inflatable cuff seal 112 for sealing against the limb 222.

[0037] Referring also to FIG. 7, the chamber 114 is defined by a collapsible bag including an outer sheet 224 and an inner sheet 226 defining a space 225 between the two sheets 224 and 226. The device 100 includes fluid ports 120, 121 and 122 which are in communication with the interior of the cuff 112, the space 225 and the interior 214 of the chamber 114, respectively, and through which gas can be conveyed based on operation of the controller 10. The ports 45c, 45d and port assembly 45e of the controller 10 are connected in fluid communication with the ports 121, 120, 122, respectively, of the device 100.

[0038] In one embodiment, gas can be delivered by the controller 10 to the space 225 between the sheets 224, 226 to inflate the device 100 to a rigid state and maintain the device 100 in the rigid state when gas pressure in the interior of the chamber 114 is cycled between about ambient pressure and above ambient pressure. In another embodiment, treatment gas inside the chamber 114 may be cycled by the controller 10 between at least about atmospheric or ambient pressure to a pressure of about up to 50 mm of mercury above atmospheric or ambient pressure.

[0039] Referring to FIG. 6, the device 100 may further include a plurality of interconnected pockets 230 or miniature chambers formed between the sheets 224, 226. The pockets can be formed by securing portions of the sheets of material together at selected, discrete locations. The sheets can be secured together at selected portions by any suitable means, such as by adhesively sealing the sheets together, heat sealing or ultrasonically welding the sheets together at selected, discrete points in an array resembling a waffle pattern. The present invention is not limited to a particular pattern for forming the interconnected pockets 230, and other patterns can be utilized.

[0040] FIG. 8 shows an additional embodiment of the present invention. Rather than utilize interconnected pockets 230, a hyperbaric treatment device 210 can have inflatable ribs 110 that extend at least partially along the sides of the device 210. In this embodiment, the two sheets 224 and 226 may be affixed together in a linear fashion creating long passages or inflatable ribs 110 between the two sheets 224 and 226. The ribs 110 can encircle the chamber 114 entirely or partially, and there may be any number of such ribs 110. The ribs 110 may be formed in any of the manners listed previously.

[0041] FIG. 4 is a flow chart 75 including operations that the microprocessor 60 may perform to control the operation of the controller 10. For purposes of illustrating the features of the invention, the operation of the controller 10 is described in connection with the hyperbaric device 100. Referring to FIG. 4, and also to FIGS. 1, 5 and 6, at block 76 an operator initiates a hyperbaric bag preparation cycle by turning on the main power switch 74, which initializes the microprocessor 60 and associated electronic control circuits 90. The operator presses the start switch 34, which sends a signal to the microprocessor 60. A signal is provided at the port B3 to turn-on the rib-fill valve 38, and also at the port A3 to turn-on the fill ribs pilot light 68. Oxygen, another gas, such as nitrogen, or ambient air, is supplied at the port 45c and inflates the ribs 110, with any excess oxygen flowing through the rib pressure relief valve 43 to the vent port 45a. In one embodiment, the valve 38 may control gas flow to and from the interconnected pockets 230 of the device 100

[0042] Next at block 78, the microprocessor 60 starts a timer for five minutes and checks to determine if the stop switch 28 is activated, which indicates that an operator wishes to arrest the preparation procedure. In the case where the stop switch 28 has been pressed, the microprocessor 60 commands the air solenoid control valves 36, 38 and 40 to the rest state, turns off the vacuum pump 41, if it is running, and extinguishes the pilot lights 68, 70 and 72, if they are illuminated. After the five minute timer has expired, in block 80 the microprocessor 60 commands the ports B3 and A3 to turn off the rib-fill air solenoid control valve 38 and extinguish the fill ribs pilot light 68, respectively.

[0043] With the ribs 110 now fully inflated, the patient's limb is placed in the chamber 114 at block 83 and the cuff fill switch 26 is activated. When the signal from the cuff fill switch is received by the microprocessor 60, the microprocessor 60 provides a signal at the port A2 to turn on the cuff-fill valve 36 and also provides a signal at the port A1 to turn on the Fill Cuff pilot light 70. It is to be understood that the cuff 112 may be inflated using air from the surrounding atmosphere, or other gas, such as nitrogen and the like.

[0044] Next, at block 85, the microprocessor 60 starts a timer for two minutes and checks to determine if the stop switch 28 is activated, which indicates that an operator wishes to arrest the preparation procedure. After the two minute timer has expired, the microprocessor 60 leaves both ports A1 and A2 switched on, which maintains oxygen flowing through the cuff-fill air solenoid control valve 36 and the valve 45d, and keeps the Fill cuff pilot light 70 illuminated. Excess oxygen flowing to the cuff 112 is vented by the pressure relief valve 42 and exits the controller 10 through the vent port 45a. With the cuff 112 now fully inflated, the flexible hyperbaric bag 100 is now sealed to the patient's limb.

[0045] Next, at block 86, the vacuum pump 41 is utilized to remove existing ambient air from the chamber 114. In some instances, the inflated ribs 110 can withstand this ambient air evacuation and stay rigid.

[0046] However, in other instances, depending on the size of the vacuum pump chosen, it may be advantageous to simultaneously evacuate the gas in both the chamber 114 as well as the ribs 110. This simultaneous evacuation can occur, because the evacuation of the chamber 114 places pressure on the chamber 114 walls and pulls them inwardly. Although the ribs 110 can remain inflated while the chamber 114 is evacuated, it has been found that this can place undue stress on the ribs 110. This stress results from the ribs 110 trying to stay rigid while the evacuation of the chamber 114 pulls the ribs 110 inwardly toward the wound. Therefore, to remove this undue stress on the ribs 110, evacuating the ribs 110 for a short period allows the ribs 110 to be pulled inwardly without the gas in the ribs 110 trying to counteract the pressure on the walls as the chamber 114 evacuation occurs. The ribs 110 and the chamber 114 can be evacuated in a manner such that the walls of the chamber 114 will not contact the wound. Thus, at block 86, the microprocessor 60 port B1 is commanded to +5 V, which in turn saturates the junction of transistor 62.sub.4 which engages the relay 57 causing the vacuum pump 41 to start removing gas from the ribs 110 and also gas from the therapy chamber 114. The gas may be evacuated up to about 95% of the gas initially within the chamber 114 prior to the commencement of the evacuation, such that about 5% of the gas, such as ambient air, initially within the chamber 114 remains within the chamber 114 following evacuation.

[0047] Alternatively, additional gas may be supplied to the ribs 110 to overcome the pressures within the chamber 114 during evacuation.

[0048] Next, at block 87, the microprocessor 60 starts a timer for five minutes and checks to determine if the stop switch 28 is activated, which indicates that an operator wishes to arrest the preparation procedure. At block 88, after the five-minute timer has expired, the microprocessor 60 commands the port B1 to turn off the vacuum pump 41. Now that the ribs 110 have been deflated and the chamber 114 has been evacuated, at block 89, the microprocessor 60 commands the port B2 to activate therapy chamber air solenoid control valve 40, and the port B3 to activate the valve 38. Treatment gas, such as oxygen, flows from the port 45b, through the valve 40 and the port assembly 45e and into the therapy chamber 114. In one embodiment, the ribs 110 are simultaneously inflated with air or gas when the treatment gas is supplied to the chamber 114. However, in the event that the ribs 110 had not been deflated, in block 89, only the chamber 114 is filled with oxygen and the treatment begins.

[0049] Next, at block 90, the microprocessor 60 starts a timer for five minutes and checks to determine if the stop switch 28 is activated. If during this block or at any time during the hyperbaric therapy session, the pressure in therapy chamber 114 exceeds 50 mm Hg above one atmosphere of pressure (ATA) or 810 mm Hg, oxygen is vented by the pressure relief valve 44 and exits the control box 10 through the vent port 45a.

[0050] At block 91, after the five minute timer has expired, the microprocessor 60 commands the ports B2 and A1 to turn off the air solenoid control valve 40 and extinguish the Fill Cuff pilot light 70, respectively. The microprocessor 60 also commands port B6 on to illuminate Hyperbaric Therapy pilot light 72. Then the microprocessor 60 continues to determine if the stop button 28 has been pressed in block 92. Finally, at block 93, if the stop button 28 has been depressed because of either an emergency situation or the hyperbaric therapy treatment is completed, the microprocessor 60 commands ports A2 and B6 to shut off the oxygen flow to the cuff 112 and extinguish hyperbaric therapy pilot light 72. The oxygen in the cuff 112 now vents to the atmosphere via the exhaust port of air solenoid control valve 36, leaving controller 10 through the vent port 45a. Although timers can be used throughout, in an embodiment of the present invention, a timer may not be required or utilized for some or all of the blocks described herein. In the event a timer is not incorporated, depressing the stop button may simply halt the process currently underway. In another embodiment, instead of timers, event driven sensors, such as pressure sensors, or the like may be used.

[0051] The objects and illustrative embodiments of the hyperbaric therapy are fully disclosed in U.S. Pat. Pub. No. 2006/0185670A1 entitled Hyperbaric oxygen devices and delivery methods, the disclosure of which is incorporated herein by reference.

[0052] In one embodiment, the controller 10 may also have a built-in safety feature should the pressure in the chamber 114 during treatment exceed its preset pressure, for example, a maximum pressure of 100 mm Hg above ATA, or 860 mm Hg. In such embodiment, referring to FIGS. 3 and 5, the controller 10 includes a port B8 connected through a 1K resistor 61.sub.8 to a base of a transistor 62.sub.8, and a control relay 59 with a flyback diode 66 couples the collector of the transistor 62.sub.8 to a dump (exhaust) air solenoid control valve 39. The controller 10 commands the port B8 to open the valve 39, which is in fluid communication with the port assembly 45e, when the Stop switch 28 is activated, to cause the chamber 114 to automatically decompress to 0 mm Hg and avoid the risk of a tourniquet effect. The tourniquet effect may be caused by the therapy pressure being set above capillary closure in the human body (16-33 mm Hg), or if a malfunction occurs, such that the pressure sensor does not operate correctly or the chamber 114 stays at a constant pressure above about 22 mm Hg. This safety feature of the controller 10 offers benefits to patients who suffer from chronic wounds, have very fragile vascular systems in their lower extremities and are at high risk of capillary closure. In an alternative embodiment, the controller 10 commands the port B8 to open the valve 39, based on a signal provided by the pressure sensor 145e, which is representative of the pressure within the chamber 114.

[0053] In another aspect of the present invention as shown in FIG. 9, the cuff 112 of the hyperbaric treatment device 100 can be positioned partially or wholly inside the chamber 114 when in an inflated condition. Referring to FIG. 9, the cuff 112 includes a tubular inflatable sleeve 240 that can provide a hermetic seal against the limb when the limb is inserted through the sleeve 240 and into the chamber 114. The sleeve has a length L as well as an inside diameter Id and an outside diameter Od. The sleeve 240 further includes an inside wall 242, an outside wall 244 and a side wall 246 that connects the inside and outside walls, 242, 244. The inside diameter Id is formed from the inside wall 242, and the outside diameter Od is formed from the outside wall 244.

[0054] The sleeve 240 is inflated using an air valve 248 disposed on the sleeve 240. In one embodiment, the valve 248 is coupled in fluid communication with the valve 45d of the controller 10. Air or any suitable gas is introduced between the inside and outside walls, 242, 244 to inflate the sleeve 240. Prior to inflation, the inside diameter Id is X. Upon inflation, the inside diameter is less than X. This ensures that the sleeve 240 diameter, prior to inflation, is large enough to accommodate a limb sliding through the sleeve 240, but the diameter can be decreased enough to snugly encircle another portion of the limb that is not for treatment. In one embodiment, the sleeve 240 is configured to have a sufficiently large diameter in a non-inflated or partially inflated condition, such that a portion of a limb to be inserted into the chamber 114 for treatment can be slid through the sleeve 240, when the sleeve 240 is in such condition, without the portion of the limb contacting the sleeve inside wall 242, while providing that the diameter also can be decreased enough to snugly encircle another portion of the limb that is not for treatment.

[0055] In one embodiment, the outside wall 244 and the side wall 246 may have a thickness greater than the thickness of the inside wall 242. This difference in thickness ensures that when the sleeve 240 is inflated, the thicker walls generally resist flexure and maintain their size and dimension, allowing the inside wall 242 to absorb the inflation. Thus, due to its smaller thickness, the inside wall 242 will stretch and accommodate the inflation, allowing the inside diameter Id to decrease to a size sufficient to seal against a limb. This also allows the sleeve 240 to seal well against any variations in the limb size or shape, such as a knee or ankle.

[0056] In one embodiment, the sleeve wall thicknesses are larger than the thickness of the chamber walls, formed by the sheets 224 and 226. This is because the sleeve 240 must withstand the pressures within the sleeve due to inflation of the sleeve 240 and pressure on the outside of the sleeve from the gas in the chamber 114. Thus, the sleeve 240 is acted on by pressures from inside the sleeve 240 and inside the chamber 114. The pressure within the sleeve 240 is much smaller than the maximum pressure in the chamber 114. Therefore, the pressures internal and external to the sleeve 240 do not cancel out.

[0057] An advantage of placing the sleeve 240 within the chamber 114 is to ensure that the incidence of the sleeve 240 sliding off the limb is reduced. The gas inside the chamber 114 places positive pressure on the outside wall 244 and retains the sleeve 240 in place on the limb. During inflation, the sleeve 240 can be inflated up to 1 psi of pressure. Thus, less pressure is required to maintain the sleeve 240 on the limb than with other types of wound treatment seals or sleeves placed on the outside of the chamber 114.

[0058] This type of sleeve 240, placed inside the chamber 114, can be incorporated with reusable chambers, chambers having rigid structures such as disclosed in U.S. Pat. No. 5,060,644 which is hereby incorporated by reference, as well as single use chambers where these sleeves 240 can replace the latex seals that are now used. This is especially advantageous in that some patients have an adverse reaction to latex.

[0059] Still referring to FIG. 9, in an alternative embodiment of the device 100, the outside wall 244 of the sleeve 240 is attached to an interior wall surface 249 of the chamber 114. In addition, the sleeve 240 is made of sufficiently flexible material, such that the sleeve 240 can be folded or rolled into itself, when the sleeve 240 is not inflated or minimally inflated. In one desired embodiment, the sleeve 240 can be folded so that the sleeve 240 is not within the interior 114 of the device 100 when the interior 114 is not inflated or minimally inflated.

[0060] References to the hyperbaric chamber device 100 are exemplary only and it should be noted that the controller 10 described herein can be used with any type of hyperbaric chamber. For example, the controller 10 can be used with reusable chambers, a topical hyperbaric chamber such as a torso or abdominal chamber or a single use hyperbaric chamber having several internal rings that form a plurality of chambers within the chamber 114. The controller can also be configured for use with chambers that treat wounds by means of evacuation or chambers that perform compression therapy or a combination of a variety of treatments.

[0061] In an embodiment of the present invention, the controller 10 described herein can be utilized with a topical hyperbaric chamber device 300, as illustrated in FIG. 10. See U.S. Pat. No. 5,154,697, which is also incorporated by reference herein. Referring to FIG. 10, the topical device 300 includes a top sheet 302 and a bottom sheet 304 defining an interior region 314. In addition, the topical chamber 300 includes an opening 306 having a seal 308 for affixing to a patient and in communication with the region 314. Further, the topical chamber 300 includes couplers 310 that connect to the vacuum pump 41 and a valve of the controller 10. Once affixed to a patient, the topical chamber 300 can be operated by the controller 10 in a manner similar to that of the device 100.

[0062] Although the invention herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and application of the present invention. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present invention as defined by the appended claims.