Source: https://patents.justia.com/patent/20130090614
Timestamp: 2019-12-14 16:30:45
Document Index: 567112669

Matched Legal Cases: ['§119', 'Application No. 60', 'Application No. 60', 'Application No. 60', 'Application No. 60', 'Application No. 60']

US Patent Application for Corporeal Drainage System Patent Application (Application #20130090614 issued April 11, 2013) - Justia Patents Search
Justia Patents Aspiration Collection Container Or Trap (e.g., Canister, Etc.)US Patent Application for Corporeal Drainage System Patent Application (Application #20130090614)
Corporeal Drainage System
Nov 28, 2012 - C. R. Bard, Inc.
A corporeal drainage system and a method of draining fluid from a bodily cavity. The corporeal drainage system includes a connection tube and a fluid receptacle in fluid communication with the connection tube. The fluid receptacle creates a negative pressure in the system by transitioning from a collapsed configuration to an expanded configuration. The system may include an activation member to initiate transitioning of the fluid receptacle.
This application is a division of U.S. patent application Ser. No. 11/248,082, filed Oct. 12, 2005, which claims the benefit under 35 U.S.C. §119(e) of U.S. Provisional Application No. 60/617,758, filed Oct. 12, 2004, each of which is expressly incorporated by reference as if fully set forth herein.
Fluid accumulation due to sickness or trauma may develop in areas within a mammalian body not designed to accommodate such accumulation. One particular area prone to abnormal accumulation is between sheets of tissue covering the outside of the lung and lining the chest cavity, known as the pleural space. While a normal functioning pleural space contains approximately 5-20 mL of fluid, fluid turnover occurs on an hourly basis such that approximately 5-10 L of fluid passes through the pleural space every day. Thus, any disruption in fluid turnover may result in over-accumulation of fluid in the pleural space, known as pleural effusion. The symptoms of pleural effusion include dyspnea, tachycardia, cough, breathing difficulty and chest pain as the lungs are prevented from fully expanding upon breathing. Pleural effusion is a condition secondary to trauma, cancer, nephrotic syndrome, kidney disease, pancreatitis, congestive heart failure and cirrhosis, and as such, patients affected with pleural effusion will usually die within three months of onset. Consequently, treatment of pleural effusion is generally provided for patient quality of life in his/her final days.
There are numerous methods to treat pleural effusion and/or other unwanted fluid accumulation in a mammalian body. Fluid drainage procedures, such as thoracentesis, may be used to provide patient relief. Thoracentesis involves the introduction of a needled catheter into the pleural space through an incision in the chest cavity, after which fluid is drawn out using a syringe or a vacuum source. Drawbacks with this procedure, however, include the fact that the needle may inadvertently puncture a lung, leading to aggravation of the problem, and the fact that fluid readily re-accumulates in the pleural space after the procedure is performed such that it may become necessary for a patient to undergo the procedure every few days. Pleurodesis is a procedure in which fluid is prevented from accumulating due to the sealing of the space between pleura with either sterile talc or an antibiotic, after first draining the existing fluid. Another method to treat pleural effusion is to surgically implant a chest tube or catheter such that fluid accumulation can constantly or periodically be removed without invasive surgery. The implanted catheter may be connected to an external catheter or drainage tube by a one-way valve mechanism, which permits fluid drainage through the use of a negative pressure source, such as a vacuum. One example of such a catheter system is described in U.S. Pat. No. 5,484,401 to Rodriguez et al., which is expressly incorporated by reference as if fully set forth herein.
While catheter-based systems have been described in the prior art, and indeed are being utilized by patients in the US, significant drawbacks exist. For example, although effective and clinically acceptable, existing catheter-based systems suffer from one or more of the following deficiencies: 1) the catheter/drainage tube connection is not secure and can be easily pulled apart (while not life threatening, accidental disconnection will cause loss of vacuum pressure mandating set-up with a new system; also, such disconnects can be the cause of pleural or peritoneal infection); 2) the clamp supplied on the drainage tube is difficult to use and is not an effective means of controlling fluid flow; 3) the system is useless in the event of an accidental loss of vacuum (effective safety mechanisms designed to prevent such accidental or premature loss of vacuum are missing); 4) the clamp sealing the vacuum chamber (which must be removed in order to activate drainage) is difficult for older patients and care givers to detach; 5) the collection chambers provided with the drainage systems (typically 500 mL) are not adequately sized for peritoneal drainage where fluid collection volumes can reach 2000 mL.
Thus, there is a need for an improved system for corporeal drainage, which will provide beneficial aspects, including those that will facilitate the use thereof regardless of patient location or condition.
FIG. 1 is a perspective view of a corporeal drainage system, showing a container in an open position for positioning of a disposable fluid collection bag.
FIG. 2 is a perspective view of the corporeal drainage system of FIG. 1, showing the container in a semi-closed position.
FIG. 3 is a perspective view of the corporeal drainage system of FIG. 1, showing the container in a closed position.
FIG. 4 is a bottom perspective view of another embodiment of a corporeal drainage system, showing in phantom a latch tab and latch clasp. The fluid receptacle is shown in an expanded state.
FIG. 5 is a top perspective view of the corporeal drainage system of FIG. 4.
FIG. 6 is a top perspective view of the corporeal drainage system of FIG. 4, shown in a collapsed state in which the latch tab is connected to the latch clasp.
FIG. 7 is a side plan view of another embodiment of a corporeal drainage system, showing a fluid receptacle in the form of a bottle in an expanded state.
FIG. 8 is a side plan view of the corporeal drainage system of FIG. 7, showing the bottle in a collapsed state.
FIG. 9 is a perspective view of the corporeal drainage system of FIG. 8, showing a distal end of a connection tube inserted into a container holding an amount of fluid to simulate the drainage of a bodily cavity.
FIG. 10 is a perspective view of the corporeal drainage system of FIG. 9, following expansion of the bottle and transfer of the fluid from the container into the bottle.
FIGS. 11-13 are perspective views of the corporeal drainage system of FIGS. 9-10, illustrating a passive siphoning process.
FIG. 14 is a side plan view of a fluid receptacle for use with a corporeal drainage system, in which the fluid receptacle also is configured to initiate a negative pressure in the system.
FIG. 15 is a longitudinal cross-sectional view of the fluid receptacle of FIG. 14 in a collapsed state.
FIG. 16 is a longitudinal cross-sectional view of the fluid receptacle of FIG. 14 in an expanded state.
FIGS. 17A-C illustrate a hand pump for use with a corporeal drainage system, the pumps in the figures all having a bulbous configuration.
FIG. 18 is another embodiment of a hand pump for use with a corporeal drainage system, the hand pump having a tubular configuration.
FIG. 19 is one embodiment of a corporeal drainage system, incorporating the hand pump of FIG. 18.
FIG. 20 is one embodiment of a corporeal drainage system, illustrating a connection system between an implanted catheter and a fluid flow conduit.
FIGS. 21-26 illustrate various examples of connection systems for use with a corporeal drainage system.
Accordingly, a corporeal drainage system is described herein that provides beneficial aspects to a target user. In one aspect of the invention, a corporeal drainage system utilizes an inline pump that connects to both the implanted catheter and drainage tube via unidirectional check valves. In another aspect, an inline drip chamber is provided for a corporeal drainage system to monitoring drainage from a bodily cavity. In one embodiment, the inline pump made of a transparent material such that it serves the dual purpose of providing both an inline pump and a drip chamber.
In another aspect of the invention, a corporeal drainage system is configured for use as a passive siphoning system, in which a negative pressure is created following initial activation, in order to alleviate work required by a user in operating the system. In one embodiment, following initial activation (e.g., pump is primed, collapsible container is initially expanded from a collapsed state, etc.), the system is positioned at a level below the reservoir or cavity to be drained to create a siphon system where the weight of the fluid in the tubing acts to drag fluid out of the elevated reservoir. In another aspect of the invention, a corporeal drainage system includes a semi-reusable collection system having a multiple use outer rigid container with single use disposable inner plastic collection bag liners that has the capacity to reactivate the required vacuum for use. In still another aspect of the invention, a corporeal drainage system is configured as a single use, low cost collection system with a pre-loaded force, in which the fluid receptacle also acts as a catalyst for producing a negative pressure in the system. In one embodiment the collection system includes a bottle that is locked in a collapsed state for shipping and storing and can be activated by unlocking. In another embodiment, the collection system includes a disposable bag that can be primed or activated to produce a negative pressure, while also serving as a fluid receptacle.
In another aspect of the invention, a corporeal drainage system is provided such that an implanted catheter can be securely connected to an external fluid flow conduit with minimal effort through use of a convenient connection system. In one embodiment, the connection system includes a catheter connector that can be connected to a drainage line connector.
In one embodiment, a corporeal drainage system includes an implantable catheter, a connection tube, a connection system, including a catheter connector attached to a proximal end of the catheter and a drainage line connector attached to a distal end of the connection tube, and a pump, including a first unidirectional check valve and a second unidirectional check valve, wherein the first unidirectional check valve is positioned at one end of the pump to connect the pump to the fluid receptacle and the second unidirectional check valve is positioned at an opposite end of the pump to connect the pump to the connection tube.
In another embodiment, a corporeal drainage system includes a catheter including a catheter connector at a proximal end thereof, a connection tube including a drainage line connector at a distal end thereof, the drainage line connector and catheter connector being configured for sealing attachment to one another, and a disposable fluid receptacle in fluid communication with the connection tube, the fluid receptacle being configured to create a negative pressure within the system upon activation thereof.
A method of draining fluid from a bodily cavity using a corporeal drainage system having a fluid receptacle includes attaching a connection tube to the proximal end of an implanted catheter, initiating a negative pressure in the system such that fluid flows from the bodily cavity in a direction toward the proximal end of the catheter, and placing the fluid receptacle at a level below the bodily cavity.
The embodiments described herein are directed to a corporeal drainage system designed to effectively provide a user the ability to drain fluid from their body in a non-clinical setting with a minimum amount of effort. The embodiments of the invention generally contain a connection tube having a proximal end that is either detachably or permanently connected to a pump or container and a distal end that is fashioned with a connector device that permits quick, easy and secure attachment to a device or mechanism inserted within a bodily cavity, including, for example, an indwelling device such as an implanted catheter or port. The connector device may be a standard luer connector or other like connectors as known to one skilled in the art. For example, if an implanted catheter has at its proximal end a female needleless injection port, the connection tube can have at its distal end a male luer connector. Particular connection systems to sealingly connect an implanted catheter to a fluid flow conduit in a corporeal drainage system are disclosed in commonly owned U.S. Provisional Application No. 60/720,443, filed Sep. 26, 2005, entitled “Catheter Connection System,” the complete contents of which are expressly incorporated by reference as if fully set forth herein.
The connection tube may be made of polyurethane or other material known to one skilled in the art suitable for a bodily fluid conduit. The connection tube should be of sufficient length to accommodate all users, such that the container may be placed on the ground or at a location beneath the cavity to be drained without undue discomfort. If the system is configured with a connection tube that is detachable from the container, different lengths can be provided by the treating clinician depending on height of the user and/or other parameters, such as likely location for the draining operation, length of the catheter extending outside of the patient's body, etc. Currently, the standard contemplated length of the connection tube is in the range of approximately 3 ft to 5 ft. The implanted catheter may be any standard medical catheter suitable for insertion into a bodily cavity, having at its proximal end a connector that attachably cooperates with the connector device attached to the connection tube (e.g., male or female luer connector). For example, suitable catheters include peritoneal catheters, thoracic drainage catheters, etc. Moreover, in the embodiments of the invention, a fluid receptacle, which may take the form, for example, of a container, disposable bottle and/or disposable bag can hold approximately 1 L of fluid, although certainly a wide range of volume capability is contemplated for the fluid receptacles of the present invention (e.g., in the range of approximately 0.5 L to 5 L).
Referring now to FIGS. 1-3, a corporeal drainage system 10 includes a vacuum pump 12, a vacuum box/container 14, a drainage bag 16 and a connection tube 30. The connection tube 30 is as described above. The vacuum pump 12 may include a flexible membrane 20 and a pair of one-way check valves 22 (FIG. 3) and can be fashioned in various shapes and sizes. The one-way check valves 22, 24, may be any type of unidirectional flow valve as is well-known to one skilled in the art. The vacuum pump 12 is operatively associated with the container via a first one-way check valve 22, which permits evacuation of air while maintaining a vacuum as it is created within the system 10. In particular, the first one-way check valve 22, permitting movement of air from the container, connects the vacuum pump 12 to the container 14. A second one-way check valve 24, positioned on the vacuum pump 12, permits release of air from the pump 12. Thus, creation of a negative pressure in the system 10 includes first activating the pump 12 through compression thereof (e.g., pressing downward on the flexible membrane 20), which evacuates the air inside the vacuum pump 12 through the second check valve 24 positioned on the pump 12, and second releasing the pump 12 (e.g., removing the applied pressure from the flexible membrane 20), which permits expansion thereof by pulling air from the container 14 through the first check valve 22.
The vacuum pressure provided to the system 10 is dependent on a number of factors, such as, for example, the number of times the pump 12 is activated (e.g., the number of times pressure is applied to the flexible membrane 20 and subsequently released), which can be varied based on the type of material used and the surface area of the pump 12 (rebound force of the pump (F)/surface area (A)=pressure (P)). Literature suggests that a negative pressure of approximately 30 mm Hg is the maximum that most bodily cavities in mammals are capable of withstanding. Thus, with such a relatively small amount of pressure demanded for the system, the volume of the pump and the material choice for the pump, including wall thickness and durometer, must be carefully considered so that a balance is struck between the number of pumps needed and amount of force necessary for a single activation of the pump. Such selection of wall thickness and durometer will also permit one to control the negative pressure placed into the system, which can be limited to provide a safety function (i.e., the amount of negative pressure possible can be limited by material selection such that even if the maximum amount was achieved by the user, said amount would not exceed the maximum permissible for the bodily cavity to be drained). Given the fact that system 10, and other systems described herein, will likely be used by patients with diminished strength and energy, these considerations can play an important role in the design of the system. In an exemplary embodiment, the flexible membrane 20 of pump 12 is made of 55 Shore A polyvinylchloride with a wall thickness in the range of approximately 0.05 in to approximately 0.5 in.
In order to maintain a consistent flow of fluid from the bodily cavity in prior art systems, the pump needs to be activated at least intermittently by the user. As previously mentioned, however, the target user may be unable or unwilling to do so. Thus, an advantage of the system described herein is that it is designed with the ability to act as a siphon after initial activation. Specifically, once the user has activated the pump a few times (e.g., in the system 10 described above, when the user has collapsed the flexible membrane 20 and subsequently allowed air from the system to re-expand it two or more times), the user may then place the container (e.g., container 14) on the ground (or any location below the body cavity from which drainage is taking place), which effectively creates a passive siphon system that utilizes the weight of the fluid within the catheter and/or connection tube 30 to pull fluid out of the bodily cavity (elevated reservoir). This ability to create a passive system requires only minimal effort from the user, which allows the system to be used in a non-clinical setting by a wide range of users, regardless of physical condition.
The vacuum box/container 14, while illustrated in a rectangular box form, may take on virtually any shape. The container 14 may include a lid 18 that is hinged to a body, as shown in FIGS. 1-3, in order to simplify the removal and installation of a disposable bag 16, although many configurations without a hinged lid 18 are also possible and within the scope of the invention as would be apparent to one skilled in the art. Due to the configuration of the system 10 that includes a disposable bag 16, the system can be used numerous times. An aperture configured for passage of the connection tube 30 is positioned on a side of the container, having associated with it a grommet 26 made of a material, such as silicone rubber, to provide a sealing function for the aperture. In one embodiment, the container also has a gasket positioned around the lid or disposable bag opening such that when said lid or opening is closed, an enhanced seal is provided. The connection tube 30 is detachable from the container 14 in one embodiment to facilitate cleaning of the container 14 (see FIG. 1). In other embodiments, the connection tube 30 is permanently connected to the container 14. The container 14 may be made of a rigid plastic material, although many other rigid materials are also suitable, such as, for example, polycarbonate, high density polypropylene, nylon, Lexan®, stainless steel, etc. In the event that the system is designed to be reusable, such as the embodiment shown in FIGS. 1-3, the material choice should be one that may be readily cleaned (e.g., dishwasher safe).
FIGS. 4-6 illustrate another embodiment of a corporeal drainage system 40, including a disposable bottle 42 made of a material, such as a clear rubber or other elastomer, that serves the dual purpose of acting both as a fluid receptacle and a catalyst or initiator for producing a negative pressure in the system. The term “bottle” as used herein means any type of container that can be filled with fluid, at least a portion of which can be collapsed, at least in part, to evacuate air therefrom. The bottle 42 in FIGS. 4-6 is in the form of a ball, having an activation knob 44 on the exterior of one end and a latch tab 48 on the interior of an opposite end. The activation knob 44 is operatively connected to a latch clasp 46 positioned adjacent the knob on the interior of the bottle 42. The bottle 42 may be molded in an open configuration and then collapsed for shipping. Upon collapse of the bottle 42, the latch clasp 46 and the latch tab 48 connect to lock the bottle in a collapsed condition, pending activation (e.g., by pressing, turning, etc.) of the activation knob 44. In this collapsed state for shipping, the bottle has a pre-loaded force so that unlocking of the latch clasp from the latch tab results in activation of the system with minimal physical effort required of the user.
When the user is ready to initiate drainage of a bodily cavity, the connection tube 30 is attached to an implanted catheter via the connector 32 (e.g., luer member), or connection system as described in commonly owned U.S. Provisional Application No. 60/720,443, and the activation knob 44 is activated, unlatching the latch clasp 46 from the latch tab 48 and permitting the bottle 42 to expand, pulling fluid from the bodily cavity in the process. In order to generate sufficient force to draw the fluid out of the bodily cavity, the wall thickness of the bottle 42 must be carefully considered. In an exemplary embodiment, the bottle 42 is approximately the size of a softball, is made of an elastomeric material, and has a wall thickness in the range of approximately 0.05 in. to approximately 0.5 in. In this embodiment, the material of the bottle 42 is disposable, such that once the fluid has been extracted from the bodily cavity, the bottle 42 can be disposed of; each use requiring a new bottle. In other embodiments, the bottle 42 may include an opening such that a disposable bag or other fluid-holding container can be inserted and removed therefrom.
FIGS. 7-13 illustrate another embodiment of a corporeal drainage system, including a bottle. In this embodiment, the bottle 52 of system 50 includes rigid sides, including a top section 54, middle section 56 and base section 58, and flexible connecting walls, including first connecting wall 62 positioned between the top section 54 and middle section 56 and second connecting wall 64 positioned between middle section 56 and base section 58. The connecting walls 62, 64 are configured to collapse within the rigid sides 54, 56, 58 upon activation of the system 50. The top section 54 has a connection member 60, which is configured to be removably attached to connection tube 30. Both top section 54 and base section 58 have respective pull tabs 66 and 68 attached thereto, the pull tabs functioning to facilitate the expansion of the bottle 52, following collapse, upon initiation of a drainage procedure. FIG. 7 illustrates the bottle 52 prior to collapse, while FIG. 8 illustrates the bottle 52 following collapse. As is apparent from FIG. 8, in this embodiment, the connecting walls 62, 64 collapse substantially within the rigid sides 54, 56, 58 to provide a small profile for storage and shipping.
FIG. 9 shows bottle 52 in its collapsed form, as shipped and stored, with the connection tube 30 attached to the connection member 60 at one end with an opposite end inserted into a container 38 with an amount of fluid therein, which exemplifies the draining of a bodily cavity. As discussed, the system 50 is activated by pulling on the pull tabs 66, 68 to expand the bottle 52, as illustrated in FIG. 10. The expansion of the bottle 52 results in the fluid from the container 38 being suctioned into the bottle 52. When the bottle is fully expanded, as shown in FIG. 10, a suitable amount of suction has been imparted to the system 50 such that a majority of fluid from the container 38 is transferred to the bottle 52. The amount of force required to expand the bottle 52 to an expanded state is dependent on a variety of factors, including the material of the bottle, as discussed above. The amount of expansion of bottle 52 necessary to drain a particular bodily cavity is variable and also depends on a number of factors, including the amount of fluid to be drained. FIGS. 9-10 illustrate an active siphoning process, in which the siphoning or transfer of fluid from the container 38 to the bottle 52 is directly attributable to the expansion of the bottle 52 (i.e., the pulling force applied to the pull tabs 66, 68 as they are pulled in opposite directions). However, the transfer of fluid from container 38 to bottle 52 can also be accomplished through a passive siphoning process, requiring much less force. This alternative method of siphoning, for which system 50 is also designed, is explained in more detail with reference to FIGS. 11-13.
Through experimentation, it was noted that a pulling force of approximately 20 lbs was required to fully expand bottle 52, in order to drain fluid from a bodily cavity. Because such a force requirement may be prohibitive to some users, another method of creating a vacuum was explored. It was discovered that an initial pulling force, significantly less than the 20 lbs necessary to fully expand the bottle 52, acted to begin the fluid flow through the catheter and connection tube. FIG. 11 shows the bottle 52 in its collapsed state, positioned at the same level as the container 38 with a level of fluid therein. In the experiment, once fluid began to enter the bottle 52, the bottle 52 was dropped to the floor or at a level below the container 38. FIG. 12 shows the bottle 52 after an initial pulling force, less than 20 lbs, has been applied to the system 50 (i.e., the pull tabs 66, 68 have been pulled in opposite directions), the bottle 52 being positioned at a level below the container 38. The action of providing an initial pulling force coupled with the action of dropping the bottle below the container generated a siphon within the system 50, pulling fluid from the container 38 and eventually filling the bottle 52. As the transfer of fluid from the container 38 to the bottle 52 takes place, the bottle 52 continues to expand until fully expanded as illustrated in FIG. 13.
Thus, the experiment showed that a reduced pulling force, less than the force required to fully expand bottle 52, could be utilized with similar results, thereby overcoming the potential problem of requiring a user to provide a larger pulling force than could be achieved by the user. It should be noted that the amount of negative head pressure (i.e., the level or distance of a bottle or container positioned below the drainage reservoir (bodily cavity)) controls the fill rate of the bottle and amount of suction acting on the drainage catheter. Therefore, as the bottle expands and increases in weight, fluid flow rate increases. As such, in one embodiment, a bottle, such as bottle 52, is hung or otherwise suspended with a weight attached to the base thereof to increase flow rate. In another embodiment, a bottle is made of a clear material so that, in addition to the audible flow indication, a visual flow indication would be provided to the user.
FIGS. 14-16 illustrate another embodiment of a corporeal drainage system. In this embodiment, system 70 includes a disposable bag 72 without an associated container, the disposable bag 72 being made of a disposable material so that it serves as a fluid receptacle. The disposable bag 72 is also configured such that it can be directly manipulated (similar to the bottle 52 of FIGS. 7-13) to produce a negative pressure for the purposes of fluid drainage from a bodily cavity. The disposable bag 72 is fashioned with rigid members 74 attached to opposing sides of the bag 72, the rigid members 72 having pull tabs 76 connected thereto. The rigid surface area of the rigid members 74 compared to the flexible surface area of the flexible portion of bag 72 is calculated such that a sufficient amount of vacuum can be generated by pulling the rigid members 74 in opposite directions (thereby expanding the bag). FIG. 14 is a perspective view of the system 70, showing one side of the bag 72 with rigid member 74 and pull tab 76, and a connection member 78 attached to one end of the bag 72, configured for releasable attachment to connection tube 30. FIG. 14 illustrates a lengthwise cross-sectional view of the disposable bag 72 in a collapsed state prior to initiating drainage (i.e., prior to imparting a negative pressure to the system 70). FIG. 15 illustrates a lengthwise cross-sectional view of the disposable bag 72 in an expanded state, following a pulling force being applied to the pull tabs 76 (i.e., the pull tabs 76 are pulled in opposite directions). As with the system 50 described above, system 70 can be operated as both active (i.e., utilizing only a pulling force to expand the bag 72) and passive (i.e., providing an initial pulling force to begin fluid flow and subsequently positioning the bag 72 below the level of fluid to be drained).
FIGS. 17-18 illustrate another embodiment of a pump utilized in a corporeal drainage system. In this embodiment, the pump is in the form of a small hand pump (which may be made small enough in size to be considered a “finger pump”) with a rebound area that is able to generate a large suction with a relatively small force. FIG. 17A-C illustrate embodiments of a small hand pump having a bulbous configuration. In FIG. 17A, the pump 80 includes a configuration with luer-type connectors at proximal and distal ends to facilitate attachment of the pump in-line to connect a connection tube and fluid receptacle, a connection tube and an implanted catheter, etc. The pump 80 includes two unidirectional valves, one at the proximal end and one at the distal end, to provide the ability of creating a negative pressure in a corporeal drainage system. The body 82 of the pump 80 can be made of a flexible material, such as, for example, silicone. FIGS. 17B and 17C illustrate two variations of the body 82 of the pump 80, FIG. 17B having a configuration in which the largest diameter of the bulb body 84 is positioned nearer the proximal end than the distal end, and FIG. 17C having a symmetrical configuration in which the largest diameter of the bulb body 84 is approximately equidistant from the proximal and distal ends. FIG. 18 illustrates a tubular-shaped hand pump 90, requiring a minimal force to begin fluid flow. To initiate fluid flow using hand pump 90, a user grasps between fingers (e.g., between the thumb and index finger) and squeezes one or more times. In one embodiment, hand pump 90 has a length in the range of approximately 1 in. to approximately 6 in. and a diameter in the range of approximately 0.25 in. to approximately 2 in. While hand pumps 80 and 90 are shown in particular configurations, it should be appreciated that many sizes and shapes are possible and would be within the scope of this invention.
The hand pumps 80 and 90 can be placed in-line into a system, connecting the connection tube 30 to either a reusable container with a disposable bag therein, a disposable bottle, or a disposable bag (e.g., zero volume collapsed bag), as described above. In one embodiment, the hand pump 90 is incorporated into system 100, as illustrated in FIG. 19. A pair of one-way check valves 92, 94 respectively connect the hand pump 90 to the connection tube 30 and the fluid receptacle 102 (e.g., container, bottle, bag, etc.). In this embodiment, the hand pump 90 is includes a body made from a material that is transparent. Thus, by placing the hand pump 90 in-line in system 100, the pump 90 also acts as a “drip chamber” so that the user is able to visually monitor the flow of fluid from the bodily cavity to the fluid receptacle 102. Operation of system 100 includes first activating the hand pump 90 by squeezing the sides together and subsequently releasing one or more times (e.g., five or six times), which creates a negative pressure in the connection tube 30 as air is transported through the one-way check valves 92, 94 in a direction toward the fluid receptacle 102 until fluid begins flowing therein. Thereafter, as explained above in connection with a passive siphoning process, the fluid receptacle 102 is dropped to a level below the bodily cavity being drained (e.g., placed on the floor). The minimal force required to begin fluid flow in system 100 as described is advantageous to the target user due to strength and stamina concerns discussed above. The relative small size of the system (especially in the case that the system includes a zero volume collapsed bag) facilitates shipping and storage.
As discussed above, the corporeal drainage system may include a connection system for easy, fast and secure connection between an implanted catheter and a connection tube as described herein (e.g., connection tube 30). Particular connection systems for the corporeal drainage system described herein are disclosed in commonly owned U.S. Provisional Application No. 60/720,443, filed Sep. 26, 2005, entitled “Catheter Connection System,” the complete contents of which are expressly incorporated by reference as if fully set forth herein. One example of a corporeal drainage system incorporating a catheter connection system is illustrated in FIG. 20, which shows corporeal drainage system 110 prior to the initiation of a drainage process, including fluid receptacle 112, pump 114, first fluid flow conduit 116, connecting the pump 14 to the fluid receptacle 112, second fluid flow conduit 118, and drainage line connector 120. A catheter connector 130 is connected to an implanted catheter 140, the catheter connector 130 and drainage line connector 120 being configured to fluidly connect second conduit 118 to catheter 140, as described more completely in commonly owned U.S. Provisional Application No. 60/720,443. To utilize the corporeal drainage system 110, the connection between the catheter connector 120 and drainage line connector 130 is first established, followed by activation of the system by priming (e.g., squeezing) the pump 114 one or more times to initiate fluid flow from a bodily cavity. The fluid receptacle 112 is either initially positioned below the cavity to be drained or is positioned below the cavity to be drained following activation of the system.
FIGS. 21-22 illustrate a connection system according to one embodiment. FIG. 21 shows a catheter connector 200 including a body 210 defining a tapered feature 220 and flow apertures 230. A sealing element 240 is provided to abut the tapered feature 220 to effectively seal the flow apertures 230. A retaining element 250 may be provided to resist movement of the sealing element 240 toward a distal end 260 of the body 210. FIG. 22 shows the catheter connector 200 coupled to a drainage line connector 270. The drainage line connector 270 includes a positioning sleeve 280 and an actuating member 290 so that when the drainage line connector 270 is connected to the catheter connector 200, the actuating member 290 deforms the sealing element 240 away from the tapered feature 220 and allows fluid flow through a gap 225 there between.
FIGS. 23-24 illustrate another example of a connection system comprising a sealing element positioned between at least two components, wherein the components are coupled to one another by at least one hinge clip. The connection system includes a catheter connector 300 and a drainage line connector 310. The drainage line connector 310 comprises a drain body 320 including hinge clips 330 pivotably affixed to the drain body 320. Each of the hinge clips 330 include an engagement feature 332 configured to engage a complimentary coupling feature 340 of the catheter connector 300. As shown in FIG. 23, the catheter connector 300 may include a plug body 350 that defines a tapered feature 360. In one embodiment, the tapered feature 360 is formed separately from the plug body 350. In such a configuration, tapered feature 360 may be affixed (e.g., adhesively bonded, ultrasonically welded, solvent welded, or otherwise affixed) to the plug body 350. In another embodiment, the tapered feature 360 may be formed integrally or monolithically with the plug body 350. A sealing element 370 may abut the tapered feature 360 to effectively seal a bore 380 of the sealing plug body 350 at one end. A retaining sleeve 390 may facilitate coupling of the deformable sealing element 370 to the sealing plug body 350. Also, the retaining sleeve 390 may extend beyond the deformable sealing element 370 and the tapered feature 360 toward the drainage line connector 310. Such a configuration may inhibit inadvertently deforming the deformable sealing element 370. The drainage line connector 310 may include an actuating member 395 configured to deform the deformable sealing element 370 upon assembly of the drainage line connector 310 and the catheter connector 300 (see FIG. 24). As shown in FIG. 24, the actuating member 395 may abut and deform the sealing element 370 away from the tapered feature 360 to allow for fluid flow from the bore 380 of the catheter connector 300 to a bore 315 of the drainage line connector 310.
FIGS. 25-26 illustrate yet another example of a connection system comprising a catheter connector 400 including a body 410 defining a protruding feature 420, apertures 430, and a sealing element 440 positioned between the protruding feature 420 and a closure element 450. The sealing element 440 forms a seal along a mating surface 460 defining an aperture through the closure element 450. A force F (e.g., generated by an actuating member of a drainage line connector) may be applied to at least a portion of the sealing element 440 to deform the sealing element 440 and allow fluid to flow through a gap 470 formed between the sealing element 440 and the closure element 450.
In another embodiment of a corporeal drainage system, the drainage line connector 130 is attached to a connection tube, such as connection tube 30, which is connected to a fluid receptacle that also acts as a pump for the system (i.e., the initiator of negative pressure), such as illustrated in FIGS. 4-6, 7-13 and 14-16 and described above. Use of such a system would begin with attachment of the drainage line connector 130 to the catheter connector 120, followed by activation of the system, as described herein.
1. A corporeal drainage system, comprising:
a connection tube;
a fluid receptacle in fluid communication with the connection tube, the fluid receptacle creating a negative pressure in the system by transitioning from a collapsed configuration to an expanded configuration; and
an activation member to initiate transitioning of the fluid receptacle.
2. The corporeal drainage system according to claim 1, wherein the fluid receptacle comprises a rigid material, selected from the group consisting of polycarbonate, high density polypropylene, nylon, Lexan®, and stainless steel.
3. The corporeal drainage system according to claim 1, wherein the activation member comprises a first locking member and a second locking member releasably coupled to the first locking member in the collapsed configuration.
4. The corporeal drainage system according to claim 3, wherein the first and second locking members are positioned on an interior surface of the fluid receptacle.
5. The corporeal drainage system according to claim 4, wherein the first locking member is operatively coupled to an activation switch positioned on an exterior surface of the fluid receptacle.
6. The corporeal drainage system according to claim 5, wherein the activation switch comprises an activation knob, wherein the first locking member comprises a latch clasp, and wherein the second locking member comprises a latch tab.
7. The corporeal drainage system according to claim 1, wherein the fluid receptacle comprises flexible side walls connected to a rigid section, at least a portion of the flexible side walls collapsed within the rigid section in the collapsed configuration.
8. The corporeal drainage system according to claim 7, wherein the fluid receptacle comprises opposing first and second rigid end sections connected to the flexible side walls.
9. The corporeal drainage system according to claim 8, wherein the activation member comprises a first pull tab and a second pull tab respectively connected to the first rigid end section and the second rigid end section.
10. The corporeal drainage system according to claim 1, wherein the fluid receptacle comprises opposing rigid sides connected by a flexible bag, the activation member comprising pull tabs attached to the rigid sides.
11. A method of draining fluid from a bodily cavity, comprising:
providing a corporeal drainage system including a connection tube and a fluid receptacle in fluid communication with the connection tube, the fluid receptacle having a collapsed configuration and an expanded configuration;
creating a negative pressure by transitioning the fluid receptacle from the collapsed configuration to the expanded configuration; and
drawing fluid from the bodily cavity into the connection tube.
12. The method according to claim 11, further comprising placing the fluid receptacle at a level below the bodily cavity.
13. The method according to claim 11, wherein creating a negative pressure includes pulling two opposing sides of the fluid receptacle away from one another.
14. The method according to claim 11, wherein the corporeal drainage system further includes an activation member, the creating a negative pressure comprising activating the activation member.
15. The method according to claim 14, wherein the activation member comprises a first locking member and a second locking member releasably coupled to the first locking member in the collapsed configuration, the creating a negative pressure comprising uncoupling the first and second locking members.
Publication number: 20130090614
Patent Grant number: 8814839
Inventor: C. R. Bard, Inc. (Murray Hill, NJ)
Application Number: 13/688,000