FLUID WARMING SYSTEM FOR HEATING A FLUID PRIOR TO DELIVERY OF THE FLUID TO A PATIENT
Background of the Invention
The field of this invention concerns heating fluids and, in particular, heating fluids for delivery to a patient.
One ofthe problems typically encountered in heating transfusion, infusion or irrigation fluids for delivery to a patient is that such fluids are typically stored at room temperature, which is much lower than a patient's body temperature. Introduction of cold fluids into a patient may well cause discomfort, shock, or another type of trauma. Storage of quantities of warmed fluids, however, is potentially unnecessarily expensive in terms ofthe energy costs. In addition, the temperature control involved in the storage of warmed fluids is problematic, because the temperature of such fluids still must be maintained while the fluids are transported from the storage area and delivered to the patients.
Various techniques have been used for heating a fluid in-line prior to delivery to a patient. Electrical resistive heating has been used to heat transfusion fluids, in particular. See, for example, U.S. Patent No. 4,906,816 by Van Leerdam; U.S. Patent No. 4,847,470 by Bakke; and U.S. Patent No. 4,532,414 by Shah et al.. Typically, a bag or a conduit containing a fluid to be warmed may be placed inside an enclosure. Heating plates contained inside the enclosure may be pressed or clamped against the fluid container. Electrical current is supplied to the heating plates, such that the plates warm the fluid container. When the desired heating is accomplished, the fluid container may be released or removed from the enclosure, and the warmed fluid may be delivered to the body.
Such devices can be cumbersome and awkward, however, because they require that an operator place the fluid container inside the enclosure, clamp or press the heating plates against the fluid container, and subsequently remove the fluid container before the fluid may be delivered to the body. In addition, the temperature monitoring of such devices may be limited, because they typically only measure the temperature ofthe fluid containers and/or heating elements.
Other various techniques have been used for heating a fluid in-line prior to delivery to a patient. See for example, U.S. Patent No. 5,362,310 by Semm, U.S. Patent No. 4,038,519 by Foucras, and U.S. Patent No. 1,995,302 by Goldstein issued in 1935. Typically, heating wires may be wrapped around or inside the walls of tubes or hoses. Such techniques may require lengthy warm-up times and/or lengthy heating tubes to achieve desired changes in fluid temperature, however, because wrapped heating wires may not
provide efficient heat transfer. In addition, the temperature monitoring ofsuch devices may be limited because they typically measure the temperature ofthe heating hose.
Accordingly, there exists a need for devices and methods for heating fluids, particularly for transfusion and/or irrigation purposes.
Summary of the Invention
Devices and methods are disclosed for heating a fluid to normothermic temperatures prior to the delivery ofthe fluid to a patient. The present invention is based on the recognition that an electrically resistive heating element can be molded into a flow- through structure, and this structure can be inserted in a flow-line for warming fluids to normothermic temperatures prior to the delivery of such fluids to a body. The term "normothermic temperatures", as used herein, encompasses equilibrium body temperatures in the range of about 34 °C to 45 °C.
In one embodiment ofthe invention, a fluid to be warmed prior to delivery to a patient can be passed through a polymeric flow-through structure disposed in the delivery fluid flow line. An electrically resistive heating element for heating the fluid is molded into the flow-through structure. In another embodiment, a temperature monitoring element, such as a thermistor, can be used to monitor the temperature ofthe fluid. In still another embodiment, the thermistor probe can be inserted directly into the fluid stream exiting the flow-through structure to measure the outlet fluid temperature.
In other embodiments of the present invention, the flow-through structure can consist of a chamber. The chamber can further consist of a disposable shell. The heating element can be inserted into a center wall in the chamber such that fluid can flow on both sides ofthe heating element for maximum heating efficiency. Alternatively, the heating element can be inserted into one or both ofthe chamber side walls. The chamber can contain baffles for providing a restricted labyrinth flow path for optimizing heating uniformity (e.g., by creating a turbulent flow stream). Alternatively, the chamber can provide a completely unrestricted flow path or can contain baffles for providing an unrestricted labyrinth flow path.
In still other embodiments ofthe invention, the flow-through structure can consist of flow-through tubing. The tubing can further be disposable. The heating element can be disposed along the outer side ofthe wall ofthe tube; in the center ofthe tubular wall; or along the inner fluid-side ofthe wall ofthe tube.
In further embodiments ofthe invention, the flow-through structure can have a capacity for a fluid flow ranging from about 10 ml/min to about 1000 ml/min. The fluid can flow by gravity or mechanical means into the flow-through structure. A biocompatible protective layer can be disposed between the heating element and the fluid. A flexible insulating material can also be disposed to surround a portion ofthe heating element or the flow-through structure to reduce heat losses. Flexible tubing can be used to deliver the fluid to and from the flow-through structure for increased ease and flexibility.
In still further embodiments ofthe invention, the electrically resistive heating element can include, but is not limited to, an etched metal foil, a carbon dispersion resistor or a dye-cut resistor. The heating element can have a capacity of at least about 50 Watts. In one embodiment ofthe invention, the heating element can heat the fluid a maximum of about 50 ° C above the fluid's storage temperature.
In another aspect ofthe invention, a system including a polymeric flow- through structure and an electrically resistive heating element, and further including an external controller can be used to warm a fluid prior to delivery to a patient. The controller can control the power supplied to the heating element through an electrical connection element having pads or other electrical connections disposed on the flow-through structure. The system can also include an attachment mechanism for attaching the controller to the flow-through structure to receive this electrical connection element. In addition, the system can include a mounting mechanism for mounting the controller to a support pole. The flow- through structure can consist of a chamber or a tube.
In yet another aspect ofthe invention, the temperature ofthe fluid can be monitored during operation of the system. In one embodiment, a temperature sensor can be deployed in the fluid flow path. Alternatively, the temperature ofthe heating element can be monitored. For example, the electrical resistance ofthe heating circuit can be monitored and used to calculate indirectly the temperature ofthe heating element and, hence, the fluid.
The temperature monitoring element and/or the resistance sensor can be integrated into the flow-through structure, but physically separate from the heating element. Alternatively, the temperature monitoring element and/or the resistance sensor can be integrated onto the controller.
The system can be equipped with a number of operational safety and control features to provide for safe and easy operation ofthe invention. The system can have a power shut-off circuit loop for automatically shutting off power and/or an alarm for sounding when a fault condition occurs. Fault conditions can include the outlet temperature ofthe
fluid, the resistance ofthe heating element and/or the fluid resistance exceeding a pre¬ determined limit. Further, additional temperature monitoring and control can be accomplished with an infrared temperature sensor disposed on the controller which senses outlet fluid temperature through a window on the structure outlet or elsewhere in the fluid line. The system can also be equipped with a LED two-digital display ofthe outlet fluid temperature for easy visual temperature monitoring. In addition, the system can be equipped with one or more lights for indicating whether the desired pre-determined outlet fluid temperature has been reached.
Because ofthe simplicity and safety ofthe present invention's operation and its precise measurement of fluid temperature, the present invention represents a valuable addition to the art of biological fluid warming, and in particular, the art of irrigation fluid warming.
Brief Description of the Drawings
FIG. 1 A is a schematic illustration ofthe flow-through structure ofthe present invention wherein the flow-through structure includes a chamber disposed in a gravity-fed fluid delivery line;
FIG. IB is a schematic illustration ofthe chamber flow-through structure of the present invention disposed in a mechanically-fed fluid delivery line;
FIG. 2 A is a cross-sectional, top view of a disk-shaped chamber flow-through structure;
FIG. 2B is a cross-sectional, side view of a chamber flow-through structure showing the heating element disposed on a side wall ofthe structure;
FIG. 3 is a cross-sectional side, view of a chamber flow-through structure with a heating element disposed on the center wall ofthe structure;
FIG. 4 is a cross-sectional, top view of a disk-shaped chamber flow-through structure with horizontal baffles for an unrestricted labyrinth flow path;
FIG. 5 is a cross-sectional, top view of a rectangular chamber flow-through structure with slanted baffles for a restricted labyrinth flow path;
FIG. 6 shows an etched metal foil resistor for use as a heating element in accordance with the invention;
FIG. 7 shows a carbon dispersion resistor for use as a heating element in accordance with the invention;
FIG. 8 shows a dye-cut resistor for use as a heating element in accordance with the invention;
' FIG. 9 A is a perspective view ofthe system ofthe present invention including a chamber flow-through structure mounted on a vertical support pole;
FIG. 9B is a front view of a controller capable of attachment to a chamber flow-through structure ofthe system ofthe present invention;
FIG. 9C is a back view ofthe controller of FIG. 9B;
FIG. 10 is a schematic diagram showing the internal circuit loop for the system ofthe present invention including a chamber flow-through structure for monitoring and controlling temperature and power equipped with an infrared temperature sensor;
FIG. 11 is a schematic illustration of another flow-through structure ofthe present invention wherein the structure includes a tube disposed in a gravity-fed fluid delivery line;
FIG. 12A is a more detailed view ofthe tubular flow-through structure of FIG. i i;
FIG. 12B is a cross-sectional view of yet another tubular flow-through of FIG. 11:
FIG. 13 is a cross-sectional view of yet another tubular flow-through structure ofthe present invention showing a heating element disposed in the center ofthe wall ofthe tubular flow-through structure;
FIG. 14A is a perspective view of a system ofthe present invention including a tubular flow-through structure mounted on a vertical support pole;
FIG. 14B is a front view ofthe controller ofthe system with the tubular flow- through structure shown in FIG. 14A;
FIG. 14C is a back view ofthe controller of FIG. 14 A; and
FIG. 15 is a schematic diagram showing the internal circuit loop for the system ofthe present invention including a tubular flow-through structure for monitoring and controlling temperature and power equipped with an infrared temperature sensor.
Detailed Description ofthe Invention
The present invention provides an electrically resistive heating element molded into a polymeric flow-through structure for warming fluids in-line to normothermic temperatures prior to delivery to a patient. FIG. 1 A illustrates a perspective view ofthe device 10 ofthe present invention having a flow-through structure 6 consisting of a chamber 12 disposed in association with a source of fluid 8 and a fluid delivery line consisting of two IV bag spikes 14, a Y connector 16, a gravity-fed fluid line 18 entering the chamber 12, a fluid line 20 exiting the chamber, and a luer connector 22 for connecting the fluid line 20 to a device such as irrigator or IV line for delivering the fluid 8 into a patient. Alternatively, the fluid entering the device ofthe present invention can be delivered by mechanical means 24, as shown in FIG. IB.
FIG. 2A illustrates an inside frontal view of a chamber flow-through structure 12 having an electrically resistive heating element 26, an inlet port 28 and an outlet port 30. The fluid inlet port 28 directs the fluid to the bottom ofthe chamber flow-through structure 12 and the fluid outlet port 30 allows the fluid to exit from the top ofthe flow-through structure to facilitate air escape during priming ofthe chamber. FIG. 2B, which is an inside side view ofthe chamber flow-through structure 12, shows the electrically resistive heating element 26 disposed on a side wall 32 ofthe chamber flow-through structure 12 such that the fluid flows along one side of this element 26. A temperature monitoring element 34, such as a thermistor or a thermocouple, can be used to monitor the temperature ofthe fluid 20 exiting outlet port 30. A probe 36 ofthe temperature monitoring element 34 can be inserted directly into the fluid line 20 exiting the chamber flow-through structure 12 to measure the outlet fluid temperature. A resistance sensor 38 can be integrated into the chamber flow-through structure 12 but physically separate from the heating element to measure the fluid temperature. A liquid detection sensor 11 can also be employed to measure the resistance of the fluid in the chamber flow-through structure.
The chamber flow-through structure 12 can consist of a disposable shell with a capacity for a fluid flow ranging from about 10 ml/min to about 1000 ml/min. The chamber flow-through structure 12 can be manufactured through any number of known , such as injection molding with any FDA approved medical grade thermoplastic (e.g. polypropylene, polyethylene, nylon or PVC). The chamber flow-through structure can also be made of different shapes, and the rectangular and disk shapes shown in Figs. 1 A and 2 A, respectively, are illustrated for exemplary purposes only.
Although FIG. 2A shows the heating element 26 inserted into a chamber sidewall 32, the heating element 26 can also be inserted into either (or both) ofthe chamber side walls 32 and 40. Alternatively, FIG. 3 shows that the heating element 26 can be inserted into a center wall 42 ofthe chamber flow-through structure 12 such that fluid can flow on both sides ofthe heating element 26 for maximum heating efficiency. The heating element 26 can be contained between two layers 48 of a laminate material, such as polyimides or polyesters, that will have thermal properties such that they will not melt or otherwise degrade at the temperature of heater operation. In addition, FIG. 3 illustrates that a biocompatible protective layer 44, which does not further hinder the heat transfer to the fluid, can be disposed between at least one portion ofthe heating element and the fluid. Again, this layer can be made of any biocompatible material with high thermal conductivity (e.g. polypropylene, polyethylene, nylon or PVC). This layer can be applied to the heating element by a plasma coating process. FIG. 3 also illustrates that an insulating material 46 can be disposed to surround at least a portion ofthe outer surface ofthe heating element 26 or the chamber flow-through structure to reduce heat losses.
FIG. 4 shows that horizontal baffles 50 may be inserted into the chamber flow- through structure 12 to form an unrestricted labyrinth flow path 52. The unrestricted labyrinth flow path 52 does not allow the fluid to flow straight through the chamber flow- through structure 12. but at the same time, does not restrict the flow to a single defined flow path. Gaps 54 between the baffles and the chamber walls eliminate fluid dead spots or eddies that would normally occur when the flowing fluid is forced around a corner. FIG. 5 shows the chamber flow-through structure 12 with slanted baffles 56 forming a restricted labyrinth flow path 5.8. In a restricted labyrinth flow path 58, slanted baffles 56 force the fluid to flow in a defined labyrinth path. As in the unrestricted labyrinth flow path, the gaps 60 between the slanted baffles 56 and the walls of the chamber flow-through structure eliminate the fluid dead spots or eddies that normally occur when flowing fluid is forced around a corner. In addition, the slanted baffles 56 facilitate the escape of air during the priming process.
The electrically resistive heating element 26 is made up of a conductor which heats up in response to an applied electric current. This heating element 26 can include, but
is not limited, to an etched metal foil 62, as shown in FIG. 6, a carbon dispersion resistor 64, as shown in FIG. 7, or a dye-cut resistor 66, as shown in FIG. 8. Different heating element shapes also can be used depending upon the shape and/or form ofthe flow-through structure. The heating element can have a capacity of at least about 50 Watts. This power requirement can be accomplished with a variety of resistance/voltage/current configurations. The area of the heating element can be about 15 cm^ to about 600 cm^. In one embodiment ofthe invention, the heating element can heat the fluid a maximum of about 50 °C above the storage temperature ofthe fluid.
The present invention also provides a system including a polymeric flow- through structure, an electrically resistive heating element, and an external controller for heating fluids prior to delivery to a patient. FIG. 9 A shows an outside view of this system 70 wherein the system 70 includes a chamber flow-through structure 12 attached to the controller 72, which, in turn, is mounted to a vertical support pole with a mounting mechanism 74. The controller 72 can monitor the temperature ofthe outlet fluid and control the power supply to the heating element through an electrical connection element 76 having pads 78A, 78B, & 78C disposed on the front ofthe controller, shown in FIG. 9B, and pads 80A, 80B, & 80C disposed on the back ofthe chamber flow-through structure, as shown in FIG. 9C. Alternatively, other electrical connections such as prongs, jacks, plugs or the like can be used. All electrical connections can be safety interlocked to the proper installation of the disposable. The attachment mechanism 82 for attaching the front ofthe controller 72 to back ofthe chamber flow-through structure 12 to receive this electrical connection element is also shown in Figs. 9B and 9C.
FIG. 9B further illustrates that the front ofthe controller 72 can be equipped with a LED two-digital display 84 ofthe outlet fluid temperature for easy visual temperature monitoring. In addition, the front of the controller 72 can be equipped with one or more lights 86 for indicating a fault condition and or whether the desired pre-determined outlet fluid temperature has been reached, a power ON/OFF switch 88 and a RESET switch 89 for easy operator access. The controller 72 can be AC line powered and switchable to operate at either 110 Vac or 220 Vac line voltage. The AC input power can be overload protected by dual (two line) fuses.
An internal circuit loop 90 for controlling temperature of and power to a chamber flow-through structure is shown in FIG. 10. The controller 72 supplies power from the power module 92 via electrical line 94 through electrical connection pads 80B and 78B to the heating element 26. The resistance of heating element 26 can be monitored via line 96 through electrical connection pads 80A and 78A by a resistance sensor 38 which can be disposed on the controller 72. Alternatively, a resistance sensor 38A (shown in dotted lines
in FIG. 10) can be located on the chamber flow-through structure 12. In addition, if the alloy which makes up the conductor ofthe heating element 26 has a large temperature coefficient of resistance, the electrical resistance ofthe heating element 26 itself can be used to measure the temperature ofthe heating element and correlated to fluid temperature. Using this method, an upper limit on the resistance ofthe heating element 26 can be used as an over temperature sensor for the fluid.
The probe 36 ofthe temperature monitoring element 34 can be disposed in the outlet port 30 to monitor the temperature ofthe fluid 20 exiting the chamber flow-through structure 12. This information is transmitted back to the power module 92 via line 98 through electrical connection pads 80C and 78C. Alternatively, the temperature monitoring element 34A (shown in dotted lines in FIG. 10) can be disposed on the controller and its probe 36A can be inserted into a sleeve 37 or other portion ofthe outlet port 30 of the chamber flow-through structure 12. This information can be transmitted back to the power module 92 via line 98 A. The actual temperature ofthe fluid can then be relayed via line 100 to the temperature display panel 102 and/or relayed via line 104 to at least one light 86A indicating whether the temperature has reached the desired level. Additional temperature monitoring and control can be accomplished with an infrared temperature sensor 108 disposed on the controller 72 which senses outlet fluid temperature through a window 110 on the chamber flow-through structure outlet port 30 or elsewhere in the fluid line. This information can be relayed to the power module 92 via line 112 and also used for the temperature monitoring. A liquid detection sensor 11 can be employed to measure the resistance ofthe fluid in the tube. If sensor 11 detects a lack of fluid (e.g., a high resistance) a shut-off signal can be relayed via line 136 and electrical connection pads 132 D and 134 D to the power module 92. The power ON/OFF switch 88 can be relayed to the power module 92 via line 114. The RESET switch 89 can be relayed to the power module 92 via line 116.
If the resistance or temperature exceeds a pre-determined level, the power module 92 can automatically shut off power to the heating element 26. In addition, the power module can sound an alarm 1 18 via line 120 and or illuminate a warning light 86B via line 122 to warn the user of a fault condition.
FIG. 11 illustrates a perspective view of another embodiment ofthe invention including a device 140 ofthe present invention having a flow-through structure 138 consisting of a tube 142 disposed in association with a source of fluid 8 and a fluid delivery line consisting of two IV bag spikes 14, a Y connector 16, a gravity-fed fluid line 18 entering the tube 142, a fluid line 20 exiting the tube, and a luer connector 22 for connecting the fluid line 20 to a device such as irrigator or IV line for delivering the fluid 8 into a patient. Alternatively, the fluid entering the device 140 can be delivered by mechanical means. The
tube 142 can consist of a disposable tubing with a capacity for a fluid flow ranging from about 10 ml/min to about 1000 ml/min. The tube 142 can be manufactured through any number of known continuous or batch methodologies, such as extrusion processes with any FDA approved medical grade thermoplastic (e.g., silicone, polyurethane or PVC). The tube 142 can be various lengths (e.g., from about 6 inches to several feet).
FIG. 12A illustrates an inside view of a tubular flow-through structure 142 having an electrically resistive heating element 144, an inlet port 146 and an outlet port 148. A temperature monitoring element 150, such as a thermistor or a thermocouple, can be used to monitor the temperature ofthe fluid 20 exiting outlet port 148. A probe 152 ofthe temperature monitoring element 150 can be inserted directly into the fluid line 20 at outlet port 148 to measure the outlet fluid temperature. A sensor 158 can be integrated into the tubular flow-through structure 142 but physically separate from the heating element to measure the resistance ofthe heating element which can then be correlated to the fluid temperature. A liquid detection sensor 160 can also be employed to measure the resistance of the fluid in the tube.
FIG. 12B, which is an inside side view ofthe tubular flow-through structure 142, shows the electrically resistive heating element 144 disposed on an inner side 162 ofthe wall ofthe tubular flow-through structure 142. Alternatively, the heating element 144 can also be inserted into the outer side 164 ofthe wall ofthe tubular flow-through structure 142. In addition, FIG. 13 shows that the heating element 144 can be inserted into the center 166 of the wall ofthe tubular flow-through structure 142. The heating element 144 can be contained between two layers 168 of a laminate material, such as polyimides or polyesters, that will have thermal properties such that they will not melt or otherwise degrade at the temperature of heater operation. In addition, FIG. 13 illustrates that a biocompatible protective layer 170, which does not further hinder the heat transfer to the fluid, can be disposed between at least one portion ofthe heating element and the fluid. Again, this layer can be made of any of a variety of known biocompatible materials (e.g., polypropylene, polyethylene, nylon or PVC). This layer can be applied to the heating element by a plasma coating process. FIG. 13 also illustrates that an insulating material 172 can be disposed to surround at least a portion ofthe outer surface ofthe heating element 144 or the tubular flow-through structure 142 to reduce heat losses.
The present invention also provides a system including a polymeric flow- through structure consisting of a tube, an electrically resistive heating element coupled to the tube, and an external controller for heating fluids prior to delivery to a patient. FIG. 14A shows an outside view of this system 180 with the tubular flow-through structure 142 attached to the controller 182, which, in turn, is mounted to a vertical support pole with a
mounting mechanism 184. The controller 182 can monitor the temperature ofthe outlet fluid and can control the power supply to the heating element through an electrical connection element 186 having pads 188 A, 188 B, & 188 C disposed on the front ofthe controller, shown in FIG. 14B, and pads 190 A, 190 B, & 190 C disposed on the back ofthe tubular flow-through structure, as shown in FIG. 14C. Alternatively, other electrical connections such as prongs, jacks, plugs or the like can be used. All electrical connections can be safety interlocked to the proper installation ofthe disposable tubular flow-through structure 142. The attachment mechanism 192 for attaching the front ofthe controller 182 to back ofthe tubular flow-through structure 142 to receive this electrical connection element is also shown in Figs. 14B and 14C.
FIG. 14B further illustrates that the front ofthe controller 182 can be equipped with a LED two-digital display 191 ofthe outlet fluid temperature for easy visual temperature monitoring. In addition, the front ofthe controller 182 can be equipped with one or more lights 194 for indicating a fault condition and/or whether the desired predetermined outlet fluid temperature has been reached, a power ON/OFF switch 196 and a RESET switch 199 for easy operator access. The controller 182 can be AC line powered and switchable to operate at either 110 Vac or 220 Vac line voltage. The AC input power can be overload protected by dual (two line) fuses.
An internal circuit loop 200 for controlling temperature of and power to a tubular flow-through structure 142 is shown in FIG. 15. The controller 182 supplies power from the power module 202 via electrical line 204 through electrical connection pads 188B and 190B to the heating element 144. The resistance of heating element 144 can be monitored via line 206 through electrical connection pads 190A and 188 A by a resistance sensor 158 which can be disposed on the controller 182. Alternatively, a resistance sensor 158A (shown in dotted lines in FIG. 16) can be located on the tube 142. In addition, if the alloy which makes up the conductor ofthe heating element 144 has a large temperature coefficient of resistance, the electrical resistance ofthe heating element 144 can be used to measure the temperature ofthe heating element 144, and hence, the temperature ofthe fluid. Using this method, an upper limit on the resistance ofthe heating element 144 can be used as an over temperature sensor.
The probe 152 ofthe temperature monitoring element 150 can be disposed in the outlet port 148 to monitor the temperature ofthe fluid 20 exiting the tubular flow-through structure 142. This information is transmitted back to the power module 202 via line 208 through electrical connection pads 190C and 188C. Alternatively, the temperature monitoring element 150A (shown in dotted lines in FIG. 15) can be disposed on the controller and its probe 152 A can be inserted into a sleeve 154 or other portion ofthe outlet
port 148 ofthe tubular flow-through structure 142. This information can be transmitted back to the power module 202 via line 208 A. The actual temperature ofthe fluid can then be relayed via line 210 to the temperature display panel 191 and/or relayed via line 214 to at least one light 194A indicating whether the temperature has reached the desired level. Additional temperature monitoring and control can be accomplished with an infrared temperature sensor 218 disposed on the controller 182 which senses outlet fluid temperature through a window 220 on the tube outlet port 148 or elsewhere in the fluid line. This information can be relayed to the power module 202 via line 212 and also used for the temperature monitoring. A liquid detection sensor 160 can be employed to measure the resistance ofthe fluid in the tube. If sensor 160 detects a lack of fluid (e.g., a high resistance) a shut-off signal can be relayed via line 236 and electrical connection pads 232 D and 234 D to the power module 202. The power ON/OFF switch 196 can be relayed to the power module 202 via line 244. The RESET switch 199 can be relayed to the power module 202 via line 216.
If the resistance or temperature exceeds a pre-determined level, the power module 202 can automatically shut off power to the heating element 144. In addition, the power module can sound an alarm 240 via line 242 and/or illuminate a warning light 194B via line 222 to warn the user of a fault condition.
In sum, the present invention benefits from the recognition that an electrically resistive heating element can be molded into a flow-through structure, and this structure can be inserted in a flow-line for warming fluids to normothermic temperatures prior to the delivery ofsuch fluids to a body. Further, the devices and methods ofthe present invention have several advantages over the traditional devices and techniques for heating such fluids. For example, the incorporation ofthe heating element inside the polymeric, flow-through structure provides that device can be inserted in one simple step directly in the fluid delivery line. In contrast, the traditional techniques may require multiple steps such as placing a bag or conduit of fluid inside an enclosure, pressing or clamping heating plates against the fluid container, and subsequently, removing the heating plates prior to fluid delivery.
Further, the coupling of an electrically resistive heating element, which is highly efficient in terms of heat transfer, to a polymeric, flow-through structure, such as a chamber or a tube, provides that the desired fluid heating can be accomplished quickly with a relatively compact device. In contrast, the traditional techniques involving wrapping heating wires around hoses may not be efficient in terms of heat transfer, and thus may require long warm-up times and lengthy hoses to accomplish the desired fluid heating.
In addition, in comparison with the traditional techniques for warming delivery fluids, the devices and methods ofthe present invention provide unique and accurate temperature monitoring and control. For example, the device can employ a probe of a temperature monitoring element inserted directly in the flow line ofthe fluid exiting the flow- through structure. Alternatively or additionally, the device can employ an infrared sensor for sensing the outlet fluid temperature through window molded in the exit port ofthe flow- through structure. In contrast, the traditional techniques typically only monitor the temperature ofthe heating plate and/or fluid container.
It will be understood that the above description is provided by way of illustration and not by way of limitation. For example, other structure shapes, flow paths, resistance and temperature monitoring and control configurations can be selected consistent with the present invention. The invention is further characterized according to the following claims.