ORGAN PERFUSION SYSTEMS
A disposable set of components for an organ perfusion system comprising a fluid supply duct for supplying fluid to the organ, a fluid removal duct for removing fluid from the organ, and a surrogate organ removably connected between the fluid supply duct and the fluid removal duct so as to form a fluid circuit, so that fluid can be circulated in the circuit in preparation for connection of the organ.
The present invention relates to perfusion systems for bodily organs, for example human organs, such as the liver, pancreas, kidney, small bowel, but also other organs including non-human organs.
BACKGROUND TO THE INVENTIONIt is known, for example from EP 1 168 913, to provide a system for extracorporeal organ perfusion, in which a human or non-human organ can be preserved, for example prior to transplant into a patient. The system typically comprises a reservoir for perfusion fluid, which may be blood or another perfusion solution, and a circuit for circulating the fluid through the organ.
SUMMARY OF THE INVENTIONThe present invention provides a set of components for an organ perfusion system, the set comprising a fluid supply duct for supplying fluid to the organ, a fluid removal duct for removing fluid from the organ, and a surrogate organ removably connected between the fluid supply duct and the fluid removal duct so as to form a fluid circuit, so that fluid can be circulated in the circuit in preparation for connection of the organ. The set may be disposable. For example it may be arranged for a single use.
The fluid supply duct and the fluid removal duct may be arranged for connection, directly, or indirectly, to an oxygen adding means so that oxygen can be added into fluid in the circuit.
The set may further comprise a measuring duct, which may be connected between the fluid supply duct and the fluid removal duct, or may be connected between two other suitable places in the circuit, and measuring means arranged to measure the content of at least one component of the fluid. The measuring duct may be arranged to bypass the organ. The measuring duct may be of a smaller diameter than the supply duct and the fluid removal duct.
The set may further comprise a pump arranged to pump fluid round the circuit. This may be located, for example, in the fluid removal duct.
The set may further comprise a fluid reservoir arranged to contain fluid for circulation in the circuit. The set may further comprise a pressure control duct arranged to connect the reservoir to a return port of an oxygen adding means.
The set may further comprise a fluid return duct arranged to return fluid produced by the organ or fluid, which may be perfusion fluid leaked, by the organ into the circuit. If the organ is a liver, the fluid may be ascites. For other organs the fluid may be a different fluid. The fluid return duct may be arranged for connection to the reservoir, whether the reservoir is part of the set or not. The set may further comprise a pump arranged to pump fluid in the fluid return duct. The set may comprise a fluid level sensor arranged to measure the level of the fluid produced by the organ. The set may comprise a sump, to which the fluid return duct is connected, for collecting the fluid produced by the organ.
The set may further comprise a collection system for collecting fluid produced by the organ. This may be a different fluid. For example, in the case of a liver it may be bile, or in the case of a kidney it may be urine. The set may further comprise measurement means for measuring the volume of the fluid produced by the organ.
The set may further comprising a further fluid supply duct removably connected to the surrogate organ. This is appropriate, for example, for perfusion of a liver, whereas other organs, such as the pancreas, only require one fluid supply duct. The further fluid supply duct may be arranged for connection to a reservoir, whether or not that forms part of the set.
The set may further comprise a connector for connection to a fluid supply. The connector may be arranged to be at the lowest point of the circuit when the circuit is in use. For example it may be in the fluid removal duct.
The set may further comprise an air vent. The air vent may be arranged to be located above the reservoir. The air vent can be used to vent air from the system as the circuit is filled with fluid.
The whole system may be arranged such that there are no, or substantially no, air traps within it. For example the whole of the perfusion circuit may be arranged to slope upwards from the connector for the fluid supply to the air vent, so that fluid can fill the circuit from the supply, no air pockets will be trapped in the circuit, and all air in the circuit will be vented out and replaced by fluid.
The set may further comprise a support panel arranged to support at least one of the ducts, which may be in the form of flexible tubing.
The support panel, an organ container and a pump may form separate units of the set. The units may be connected together by one or more of the ducts, which may be flexible. This may allow the units to be moved between a folded state for storage and an unfolded state for use, whilst connected together.
Indeed the present invention further provides a set of components for an organ perfusion system, the set comprising a support panel supporting a component, such as at least one flexible tube, forming part of the system, an organ container, and a pump, wherein the support panel, the organ container and the pump form separate units of the set which are connected together by one or more flexible tubes, so that the units can be moved between a folded state for storage and an unfolded state for use, whilst connected together. The flexible tube or tubes may form part of a perfusion circuit of the system.
The support panel may have a channel formed therein, in which the at least one flexible tube or duct is located. The support panel may further comprise a tab, which may be formed integrally with the panel, and may be arranged to retain the tube or duct in the channel. The channel may be divided into two channel sections which are spaced apart. The panel may have an aperture through it. The aperture may extend around three sides of the tab. The two channel sections may open into the aperture. This may enable a portion of the flexible tube or duct to be bent, fitted through the aperture, and then straightened so as to be retained in the channel by the tab.
The present invention further provides a support panel for supporting a length of flexible tubing or other flexible member, the panel having a channel formed therein, wherein the channel is divided into two channel sections which are spaced apart, and the panel has an aperture through it, between the channel sections, which extends around three sides of a portion of the panel which forms a tab, the two channel sections opening into the aperture so that a portion of the flexible member can be bent, fitted through the aperture, and then straightened so as to be retained in the channel by the tab.
The panel on either side of each of the channel sections may lie in a common flat plane. The tab may be flat and may be formed in the same plane. The depth of the channel may be greater than the sum of the diameter of the flexible member and the thickness of the tab, so that the flexible member can be straightened completely within the two channel sections.
The panel may comprise a recess arranged to receive an oxygenator in it. The panel may comprise a recess arranged to receive a fluid reservoir in it.
The present invention further provides a method of making a support panel according to the invention, the method comprising providing the panel with the two channel sections formed in it, and cutting the aperture through the panel so as to leave the tab.
At least one of the two channel sections may be formed with an end wall. The cutting step, or a separate cutting or other removal step, may remove the end wall.
The present invention further provides a perfusion system for the perfusion of an organ, the system comprising a perfusion fluid circuit for circulating perfusion fluid through the organ, the circuit comprising a fluid supply duct for supplying fluid to the organ and a fluid removal duct for removing fluid from the organ, the system further comprising a surrogate organ arranged to be connected between the fluid supply duct and the fluid removal duct so that fluid can be circulated in the circuit in preparation for connection of the organ.
The present invention further provides a method of preparing an organ perfusion system for perfusion of an organ, the method comprising providing a perfusion system with a surrogate organ connected into it, circulating perfusion fluid through the system including the surrogate organ in preparation for connection of the organ. The perfusion system may be any system according to the invention as described above. The perfusion system may comprise any set of components according to the invention as described above.
Preferred embodiments of the present invention will now be described by way of example only with reference to the accompanying drawings.
Referring to
The sling 10 is of moulded plastics or other suitable material and designed to be compliant so as to enable non-traumatic support of the organ whilst providing a degree of shock absorption during transport. The sling 10 has a perforated base 19 through which fluids leaking from the organ can flow out, and side walls 20 extending upwards from the base 19, and a rim 22 extending around the top of the side walls 20. A fluid sump 24 which, where the organ is a liver, forms an ascites sump, is located beneath the sling 10, and comprises a concave base 26 that tapers downwards to a drainage hole 28, which is formed through its lowest point. The sump 24 is arranged to catch fluid leaking through the base 19 of the sling. The sump 24 also comprises side walls 30 that extend upwards from the base 26, around the side walls 20 of the sling, and have a flange 32 around their top which supports the rim 22 of the sling 10. A removable cover 34, which is of moulded plastics, fits over the top of the sling 10 and has a rim 36 around its lower edge which fits against the rim 22 of the sling.
The sling 10 is supported within an organ container 40 which has the ascites sump 24 and a bile sump 42 supported in its base 44, and in this embodiment formed integrally with it. The organ container 40 has side walls 46 extending upwards from its base 44 and a removable cover 48. The bile sump 42 is about twice as deep as the ascites sump 24 and generally narrow and tubular in shape, and extends downwards from the base 44 of the container 40 with its rim 52 level with the rim 32 of the ascites sump 24 and the rim 22 of the sling.
The bile sump 42 is formed in two parts, an upper part 42a and a lower part 42b, both of which are integral with the base 44 of the organ container. The lower part 42b has a bile inlet port 54 formed in its side, towards its upper end 56, and a bile overflow port 58 formed in its upper end. A bile outlet port 60 is formed in the base 44 of the organ container close to the top of the bile sump, with an upper connector 60a for connection via a cannula to the liver, and a lower connector 60b for connection to a bile measurement system 62. The bile measurement system 62 is arranged to measure the volume of bile secreted by the liver before allowing it to flow into the bile sump 42.
As can best be seen in
The controller 18 is arranged to measure the rate at which bile is secreted by the liver by closing the pinch valve 76 so that bile builds up in the outlet duct 68, and then in the bile receiving duct 64 and overflow duct 70. When the level sensor 74 detects that the bile has reached the predetermined level, it is arranged to send a signal to the controller 18 which responds by opening the pinch valve 76, for example for a predetermined period, to allow the bile to drain out of the measurement system into the sump, and then closes it again so that bile can start to collect in the measurement system again. The controller 18 is also arranged to record in memory the times at which the bile reaches the predetermined level, and therefore the times at which the measurement system is filled. This information, together with the known volume of the system when it is filled to the predetermined level, allows the rate at which bile secreted over time to be monitored. For example the controller 18 may be arranged to calculate a flow rate each time the valve 76 is opened from the known volume of the system and the time interval between the valve opening and the previous valve opening. That flow rate can be displayed on the GUI 17, being updated each time a new calculation of flow rate is recorded. Alternatively the controller 18 may be arranged to store this flow rate information in memory, so that flow rate data for the whole perfusion process can be stored and then output or displayed via the GUI 17. As a further alternative, the controller may not perform any calculation but may generate an output which varies with the flow rate, and the GUI may be arranged to respond to the output by generating a display, such as a line graph, which is indicative of the flow rate, for example by having appropriately marked axes. It will be appreciated that, for organs other than the liver, this measurement system can be arranged to measure other fluids leaking from, or excreted by, the organ during perfusion, and to record and display the measured volume. For example the organ may be a kidney and the fluid may be urine.
Referring back to
In a modification to this embodiment, there is a further ascites level sensor in addition to the sensor 88, so that the sensors can detect when the ascites level reaches upper and lower levels. The controller 18 is arranged to start the ascites pump 84 when the ascites is detected as reaching the upper level, and to step the ascites pump 84 when the ascites level drops to the lower level. The controller is then arranged to record the timing of each time the pump is turned on, and this provides an indication of the total volume of ascites and the flow rate of ascites during perfusion. This information can be stored and displayed on the GUI 17 in the same way as the bile measurements. It will be appreciated that, for other organs, this measurement system can be used to measure the total volume or flow rate of other fluids leaking from, or excreted by, the organ during perfusion. This measurement can also be provided with only one ascites level sensor as shown in
The perfusion circuit 16 further comprises a first fluid supply duct 100, which when used for perfusion of a liver forms a portal duct, a second fluid supply duct 102, which when used for perfusion of a liver forms a hepatic artery duct, and a fluid removal duct 104, which when used for perfusion of a liver forms an inferior vena cava (IVC) duct. The system and its operation will now be described for perfusion of a liver, but it will be appreciated that it can equally be used for other organs. The portal duct 100 has one end connected to an outlet port 106 in the fluid reservoir and the other end attached to a portal vein connector 108. The portal duct 100 extends through a port 110 in the side wall 46 of the organ container 40 so that the portal vein connector 108 is located inside the container. A flow control valve 112, in the form of a pinch valve, having a variable degree of opening, is provided in the portal duct 100 and is connected to the controller 18. The controller 18 is arranged to vary the degree of opening of the pinch valve 112 so as to control the rate of flow of fluid from the reservoir 12 to the portal vein of a liver. A portal flow sensor 113 is provided in the portal duct 100 and is arranged to output a signal indicative of the flow rate of fluid in the portal duct 100. The output of the flow sensor 113 is connected to the controller 18 which can therefore monitor the flow rate in the portal duct. The controller 18 is also arranged to determine from the flow sensor 113 signal when the flow of fluid from the reservoir ceases due to the reservoir being empty. In response to detection of an empty reservoir the controller 18 is arranged to close the flow control valve 112 so as to prevent air from reaching the organ. The hepatic artery duct 102 has one end connected to a first outlet port 114 of the oxygenator 14 and the other end attached to a hepatic artery connector 116. The hepatic artery duct 102 extends through a port 118 in the side wall 46 of the organ container 40 so that the hepatic artery connector 116 is located inside the container. The IVC duct 104 has one end attached to an IVC connector 120, which is located inside the container 40, and extends out through a port 122 in the base 44 of the organ container 40, having its other end connected to an inlet port 124 of the oxygenator 14. A pump 123 is provided in the IVC duct 104 having its inlet connected by a part of the IVC duct 104 to the IVC connector 120, and its outlet connected to the inlet port 124 of the oxygenator 14. The pump 123 is, arranged to pump fluid from the IVC duct 104 into the oxygenator 124. The pump 123 is a variable speed pump and is connected to, and controlled by, the controller 18. An IVC flow sensor 125 is arranged to measure the rate of fluid flow rate in the IVC duct 104 and is arranged to output a signal indicative of the flow rate of fluid in the vena cava duct 104. The output of the flow sensor 125 is connected to the controller 18 which can therefore monitor the flow rate in the IVC duct 104.
Each of the connectors 108, 116, 120 is a quick-release connector arranged to allow the duct to which it is attached to be connected, either via a cannula to the appropriate vein or artery of the liver, or to a surrogate organ 126 which is arranged to complete the perfusion circuit prior to connection of the real organ. The surrogate organ 126 comprises two inlet ducts 128, 130 for connection to the portal duct 100 and the hepatic artery duct 102, and one outlet duct 132 for connection to the IVC duct 104. In this embodiment the surrogate organ is in the form of a simple Y-piece connector 134 which connects the two inlet ducts 128, 130 to the outlet duct 132 so that, when it is connected into the circuit, fluid can flow through it from the portal duct 100 and the hepatic artery duct 102 to the IVC duct 104.
Each of the portal duct 100, the hepatic artery duct 102 and the IVC duct 104 has a pressure sensor 136, 137, 138 in it, arranged to measure the pressure of fluid in the duct 100, 102, 104. Each of these pressure sensors 136, 137, 138 is arranged to measure pressure at a point close to the respective connector 108, 116, 120, and to output a signal indicative of the pressure at that point. Referring to
The port 118 in the organ housing 40 has a cylindrical wall 314 surrounding it on the outer side of the housing 40. The wall is thicker at its base than at its outer end, so that its inner diameter decreases from its outer end to its inner end. This inner diameter is slightly greater than the thicker parts 310 of the connector body, so that one end of the connector body, with the tubing pushed over it, can be pushed into the aperture within the cylindrical wall 314, so that the tubing is held between the cylindrical wall 314 and the thicker part 310 of the connector, as shown in
Referring to
Three clamps 420 are provided, one on each of the two inlet ducts 128, 130 of the surrogate organ, and one on the outlet duct 132 of the surrogate organ. Each of these clamps 420 is ratchet clamp that can be closed so as to pinch the duct and seal it to prevent the flow of fluid through it. The ratchet 422 on the clamp retains it in this closed position, but can be released to release the clamp and open the duct. Three similar ratchet clamps 424 are provided, one on each of the main inlet ducts 100, 102 and one on the outlet duct 104, close to the respective connector 108, 116, 120, and between the connector 108, 116, 120 and the pressure sensors 136, 137, 138. These six clamps can be used to seal the ends of the various ducts when the surrogate organ is being connected into, or disconnected from, the perfusion circuit.
Referring back to
Referring still to
A small diameter fluid analysis duct 190 has one end connected to the IVC duct 104, upstream of the pump 123, and in this case downstream of the IVC flow sensor 125, and the other end connected to the pressure control duct 142, upstream of the pressure control valve 146, so that fluid can flow through the fluid analysis duct 190 from the pressure control duct 142 to the IVC duct 104, bypassing the organ. A measurement system, in this case in the form of a blood gas analyser (BGA) 192 is arranged to measure various parameters of the fluid flowing through the fluid analysis duct 190. In this embodiment the BGA 192 is arranged to measure the oxygen content and the carbon dioxide content of the fluid flowing through it. Other parameters can also be measured and monitored. The BGA 192 is connected to the controller 18 and arranged to output signals each of which is indicative of the value of one of the parameters it measures, and the controller 18 is arranged to receive those signals so that the parameters can be monitored by the controller 18. The signals therefore include an oxygen level signal, a CO2 level signal, and a glucose level signal in this embodiment.
A priming bag or reservoir 194 is supported at a level which is above the top of the reservoir 12, and connected by a priming duct 196 to the perfusion circuit at a priming point which is in the vena cava duct 104 at its lowest point 104a. This is also the lowest point of the perfusion circuit 16, which allows the whole circuit 16 to be filled from the bottom, as will be described in more detail below.
Referring to
Referring to
Referring to
In other embodiments the cartridge is shaped from a flat panel by methods other than thermoforming, and in still further embodiments, the cartridge is not shaped from a flat panel, but is moulded in a form similar to that of
Referring back to
As shown in
Referring to
While the surrogate organ is present, and in particular while the controller 18 detects that the surrogate organ is present, the controller 18 operates in a preparation mode it which it is preparing the system for connection of the real organ. In this mode, the controller 18 is arranged to control the pump 123 so that it pumps fluid through the oxygenator at a constant flow rate, and monitor and adjust the various parameters of the fluid, as described above, so as to bring them within target ranges suitable for perfusion of a real organ.
To enable connection of the real organ, the pump 123 is stopped. The GUI 17 allows a user demand to be input to the controller 18 to stop the pump 123. When this demand is received by the controller, the controller is arranged to stop the pump 123 so that circulation of the perfusate stops. The surrogate organ 126 is then disconnected from the circuit, and the organ 250 connected into the circuit as shown in
With the real organ 250 present, the controller 18 is arranged to start to measure the volume of bile using the bile measurement system 62 as described above. It is also arranged to start draining ascites from the sump 26, and measuring the volume of that ascites, as described above. The controller is also arranged to record the total number times that the bile measurement system valve 76 is opened and the total number of times that the ascites pump 84 is activated to measure the total volume of bile and the total volume of ascites that are produced by the liver during perfusion. It is also arranged to measure the time between each pair of subsequent operations of the valve 76, and each pair of subsequent operations of the pump 84, and to calculate for each pair of operations, an associated flow rate of bile, and an associated flow rate of ascites, from the liver.
It will be appreciated that, if an organ other than the liver is connected into the system, the bile measurement system and the ascites measurement system can each be used to measure different fluids as produced by that organ. For example they can be used to measure urine from a kidney. Also in another embodiment of the system, a measurement system which is the same as the bile measurement system 62 described above is included in the ascites duct 80 upstream of the pump 84 to give a more accurate measurement of ascites.
In a still further embodiment, the bile measurement system 62 is provided without the rest of the perfusion system described above, and can then be connected to an organ, such as a liver, during surgery, to measure the volume or flow rate of fluid produced by the organ during surgery.
To set the system up for use, the disposable set is first unfolded and mounted on the support stand 500. The surrogate organ 126 is already connected into the circuit as part of the disposable set, as is the oxygenator 14, and the pump 123. The perfusion circuit is then filled with perfusate. To achieve this, the flow control valves 112, 146 in the portal duct 100 and pressure control duct are opened A perfusion bag 194 containing perfusate is connected to the upper end of the priming duct 196. The priming bag 194 is then raised to a level that is higher than top of the fluid reservoir 12. This causes perfusate fluid from the priming bag to flow into the perfusion circuit at the priming point 104a in the vena cava duct 104, and flow upwards through the whole perfusion circuit from that point. As the fluid level in the perfusion circuit rises, this fills the vena cava duct 104, the surrogate organ 126, the hepatic artery duct 102 and the portal duct 100, the through duct 150 of the oxygenator, and the pressure control duct 142, and the reservoir 12, with the ports 82, 178 in the top of the reservoir being used to vent air out of the system as it fills. The pump head can be independently moved and tapped relative to is driving motor to enable removal of any gas trapped within the pump head during filling. After filling, the ascites duct 80 is connected to the ascites return port 82 and the nutrient feed duct 174 is connected to the nutrient feed port 178, and the system is then complete and ready for use.
When the perfusion circuit 16 has been filled, the system is switched on, for example by a user inputting a start command using the GUI 17 and starts to run and the controller 18 is arranged to control the system as follows. When the system starts to run, the pressure control valve 146 in the pressure control duct is closed, so that pumping fluid through the oxygenator will tend to increase the pressure in the hepatic artery duct 102, and the flow control valve 112 in the portal vein duct is opened. Initially, therefore, the pump 123 pumps fluid through the hepatic artery duct 102, through the surrogate organ 126, and through the IVC duct 104. As the flow rate through the IVC duct 104 is the same as that through the hepatic artery duct 102 (as they are connected together through the oxygenator and there is no flow through the pressure control duct 142) there will be substantially no flow through the portal vein duct 100. The controller 18 is arranged initially to control the pump 123 to operate at a constant speed and to monitor the pressures in the hepatic artery duct 102 and the IVC duct 104 and compare them. Since the surrogate organ 126 is present, the pressure drop across it is low, in particular significantly lower than what it would be if a real organ were connected into the circuit, and this enables the controller 18 to detect the presence of the surrogate organ from the outputs from the difference between the pressures measured by the pressure sensors 136, 138.
While the surrogate organ is present, and in particular while the controller 18 detects that the surrogate organ is present, the controller 18 operates in a preparation mode it which it is preparing the system for connection of the real organ. In this mode, the controller 18 is arranged to control the pump 123 so that it pumps fluid through the oxygenator at a constant flow rate, and monitor and adjust various parameters of the fluid, so as to bring them within target ranges suitable for perfusion of a real organ.
To enable connection of the real organ, the pump 123 is stopped. The GUI 17 allows a user demand to be input to the controller 18 to stop the pump 123. When this demand is received by the controller, the controller is arranged to stop the pump 123 so that circulation of the perfusate stops. All ratchet clamps are closed so as to avoid leakage of fluid from either the perfusion circuit or the surrogate organ. The surrogate organ 126 is then disconnected from the circuit, and the organ 250 connected into the circuit as shown in
Referring to
Claims
1. A disposable set of components for an organ perfusion system, the set comprising a fluid supply duct for supplying fluid to the organ, a fluid removal duct for removing fluid from the organ, and a surrogate organ removably connected between the fluid supply duct and the fluid removal duct so as to form a fluid circuit, so that fluid can be circulated in the circuit in preparation for connection of the organ.
2. A set according to claim 1 further comprising a connector for connection to a fluid supply, wherein the connector is arranged to be at the lowest point of the circuit when in use.
3. A set according to claim 2 further comprising a priming reservoir and a priming duct arranged to connect the priming reservoir to the connector.
4. A set according to any foregoing claim further comprising a fluid reservoir arranged to contain fluid for circulation in the circuit.
5. A set according to claim 4 when dependent on claim 3 wherein the priming reservoir is arranged to be raised to a level that is higher than the top of the fluid reservoir thereby to cause fluid to flow from the priming reservoir into the fluid circuit.
6. A set according to claim 4 further comprising an air vent arranged to be located above the reservoir, and arranged to vent air from the system as the circuit is filled with fluid.
7. A set of components according to any foregoing claim further comprising oxygen adding means, wherein the fluid supply duct and the fluid removal duct are connected to an oxygen adding means so that oxygen can be added into fluid in the circuit.
8. A set according to any foregoing claim 1 further comprising a measuring duct connected between the fluid supply duct and the fluid removal duct and measuring means arranged to measure the content of at least one component of the fluid.
9. A set according to any foregoing claim further comprising a pump arranged to pump fluid round the circuit.
10. A set according to claim 4 further comprising a pressure control duct arranged to connect the reservoir to a return port of an oxygen adding means.
11. A set according to any foregoing claim further comprising a fluid return duct arranged to return fluid produced by the organ into the circuit.
12. A set according to claim 11 when dependent on claim 4 wherein the fluid return duct is arranged for connection to the reservoir.
13. A set according to claim 11 or claim 12 further comprising a pump arranged to pump fluid in the fluid return duct.
14. A set according to any of claims 11 to 13 further comprising a fluid level sensor arranged to measure the level of the fluid produced by the organ.
15. A set according to any of claims 11 to 14 further comprising a sump, to which the fluid return duct is connected, for collecting the fluid produced by the organ.
16. A set according to any foregoing claim further comprising a collection system for collecting fluid produced by the organ.
17. A set according to claim 16 further comprising measurement means for measuring the volume of the fluid produced by the organ.
18. A set according to any foregoing claim further comprising a further fluid supply duct removably connected to the surrogate organ.
19. A set according to claim 18 when dependent on claim 4 wherein the further fluid supply duct is arranged for connection to the reservoir.
20. A set according to any foregoing claim further comprising a bile measurement system.
21. A set according to claim 20 wherein the bile measurement system comprises a fluid collection volume and sensing means arranged to detect when a predetermined volume of the fluid has collected in the collection volume.
22. A system according to claim 21 further comprising control means arranged to remove the fluid from the collection volume when said predetermined volume is reached.
23. A system according to claim 22 wherein the control means is arranged to record each occurrence of the predetermined volume being reached thereby to record the total volume of the fluid flowing from the organ.
24. A system according to claim 23 wherein the control means is arranged to determine the time between subsequent occurrences of the predetermined volume being reached.
25. A system according to claim 24 wherein the control means is arranged to determine, from said time, a flow rate of the fluid from the organ.
26. A system according to any of claims 21 to 25 further comprising display means arranged to display information relating to the amount of the fluid that flows from the organ.
27. A system according to claim 26 wherein the display means is arranged to display a flow rate of the fluid.
28. A system according to claim 26 or claim 27 wherein the display means is arranged to display a total volume of the fluid.
29. A system according to of claims 21 to 28 wherein the bile measurement system further comprises an outlet from the fluid collection volume and a valve in the outlet.
30. A system according to claim 29 when dependent on claim 22 wherein the control means is arranged to open the valve to remove the fluid from the collection volume.
31. A system according to any of claims 21 to 30 wherein the bile measurement system comprises a level sensor arranged to sense when the fluid in the collection volume reaches a predetermined level.
32. A system according to any of claims 21 to 31 wherein the bile measurement system comprises a pump and the control means is arranged to operate the pump to remove the fluid from the collection volume.
33. A system according to any of claims 21 to 32 wherein the bile measurement system comprises an inlet duct, an outlet duct and an overflow duct connected together.
34. A system according to claim 33 wherein the collection volume is defined at least partly within the inlet duct.
35. A system according to claim 33 or claim 34 wherein the collection volume is defined at least partly within the overflow duct.
36. A system according to any of claims 33 to 45 wherein the bile measurement system is arranged to detect the level of the fluid in at least one of the inlet duct and the overflow duct.
37. A system according to any of claims 33 to 36 further comprising a sump wherein the outlet duct and the overflow duct are both connected to the sump.
38. A system according to any of claims 33 to 37 further comprising a connector for connecting the measuring means via a cannula to the organ.
39. A set according to any foregoing claim further comprising a support panel arranged to support at least one of the ducts.
40. A set according to claim 39 wherein the support panel, an organ container and a pump form separate units of the set which are connected together by one or more of the ducts, which are flexible, so that the units can be moved between a folded state for storage and an unfolded state for use, whilst connected together.
41. A set of components for an organ perfusion system, the set comprising a support panel supporting at least one flexible tube forming part of the system, an organ container, and a pump, wherein the support panel, the organ container and the pump form separate units of the set which are connected together by one or more of the flexible tubes, so that the units can be moved between a folded state for storage and an unfolded state for use, whilst connected together.
42. A set according to claim 40 or claim 41 wherein the support panel has a channel formed therein, in which the at least one flexible tube or duct is located, with a tab formed integrally with the panel and arranged to retain the tube or duct in the channel.
43. A set according to claim 42 wherein the channel is divided into two channel sections which are spaced apart, and the panel has an aperture through it which extends around three sides of the tab, the two channel sections opening into the aperture so that a portion of the flexible tube or duct can be bent, fitted through the aperture, and then straightened so as to be retained in the channel by the tab.
44. A support panel for supporting a length of flexible tubing, the panel having a channel formed therein, wherein the channel is divided into two channel sections which are spaced apart, and the panel has an aperture through it, between the channel sections, which extends around three sides of a portion of the panel which forms a tab, the two channel sections opening into the aperture so that a portion of the flexible tube or duct can be bent, fitted through the aperture, and then straightened so as to be retained in the channel by the tab.
45. A support panel according to claim 44 or a set according to claim 43 wherein the panel on either side of each of the channel sections lies in a common flat plane, and the tab is flat and formed in the same plane.
46. A support panel according to claim 45 wherein the depth of the channel is greater than the sum of the diameter of the tubing and the thickness of the tab, so that the tubing can be straightened completely within the two channel sections.
47. A method of making a support panel according to claim 44 or claim 45 comprising providing the panel with the two channel sections formed in it, and cutting the aperture through the panel so as to leave the tab.
48. A method according to claim 47 wherein at least one of the two channel sections is formed with an end wall, and the cutting step removes the end wall.
49. A method according to claim 47 or claim 48 wherein the channel sections are formed in the panel by thermoforming.
50. A perfusion system for the perfusion of an organ, the system comprising a perfusion fluid circuit for circulating perfusion fluid through the organ, the circuit comprising a fluid supply duct for supplying fluid to the organ and a fluid removal duct for removing fluid from the organ, the system further comprising a surrogate organ arranged to be connected between the fluid supply duct and the fluid removal duct so that fluid can be circulated in the circuit in preparation for connection of the organ.
Type: Application
Filed: Nov 8, 2012
Publication Date: Dec 25, 2014
Inventors: Stuart Brian William Kay (Cambridge), David George Robinson (Cambridge), Philip David Canner (Cambridge), Peter Alan Salkus (Cambridge), Leslie James Russell (Oxford), Peter John Friend (Oxford), Constantin C. Coussios (Oxford)
Application Number: 14/357,118
International Classification: A01N 1/02 (20060101);