SYSTEM FOR IMPROVING FLUID DRAINAGE

Abstract

A low-cost and simple-to-use system and method to facilitate a prophylactic pleural lavage protocol at the time of thoracostomy tube placement for traumatic hemothorax in order to reduce the need for secondary intervention for the management of retained hemothorax. The invention may be used in conjunction with existing chest tubes and be administered at the time of initial chest tube placement, and continued at the bedside (by a bedside nurse) over the duration of chest drainage, as necessary. The system includes an operator device that semi-automatically administers a pleural lavage protocol consisting of saline instillation, and suction to slow the clotting process, prevent “gelling” of blood, and maintain drainability.

Claims

1. A system for pleural lavage, comprising: a fluid infuser; at least one suction source; a drainage collection chamber; a chest tube; a pleural lavage controller comprising a plurality of fluid ports including a first port connected to said chest tube, a second port for fluid communication with said fluid infuser, and a third port for fluid communication with one of said at least one suction source via said drainage collection chamber, wherein said second port and third port are manifolded to said first port; whereby said pleural lavage controller selectively allows/prevents a fluid from said fluid infuser, and suction from said suction source, over a duration of chest drainage.

2. A system for pleural lavage according to claim 1, wherein said fluid is saline.

3. A system for pleural lavage according to claim 1 wherein said fluid contains a pharmaceutical such as a fibrinolytic agent or antibiotic.

4. A system for pleural lavage according to claim 1, further consisting of a pressure regulator between said third port and said suction source.

5. A system for pleural lavage according to claim 1, further consisting of a seal between said third port and said suction source.

6. A system for pleural lavage according to claim 1, further comprising a fourth port in fluid communication with one of said at least one suction source, wherein said fourth port is manifolded with said second port and said third port to said first port.

7. A system for pleural lavage according to claim 6, further comprising a second drainage collection chamber connected between said fourth port and one of said at least one suction source.

8. The system for pleural lavage according to claim 1, wherein said fluid infuser comprises a fluid warmer.

9. The system for pleural lavage according to claim 1, wherein said fluid infuser is configured for emptying a 1000 cc fluid container in 30 seconds or less.

10. The system for pleural lavage according to claim 1, wherein said saline infuser is configured for emptying a 1000 cc fluid container in 20 seconds or less.

11. The system for pleural lavage according to claim 1, wherein said fluid infuser applies external positive pressure to said fluid to force fluid through the system.

12. The system for pleural lavage according to claim 11, wherein said external positive pressure is applied via gravitational acceleration or ambient air pressure.

13. The system for pleural lavage according to claim 11, wherein said external positive pressure is applied manually.

14. The system for pleural lavage according to claim 11, wherein said saline infuser comprises an electromechanical pressure infuser.

15. The system for pleural lavage according to claim 1, wherein said saline infuser comprises a pump for applying negative pressure on said fluid to draw it out of said container.

16. The system for pleural lavage according to claim 1, wherein said lavage controller comprises a plurality frustoconical fluid ports.

17. The system for pleural lavage according to claim 1, wherein said lavage controller comprises a housing with a plurality of chambers each corresponding to one of said first port, second port, and third port.

18. The system for pleural lavage according to claim 17, wherein two of said plurality of chambers branch to a third chamber at angles not in excess of 45 degrees.

19. The system for pleural lavage according to claim 1, wherein said lavage controller comprises a plurality of valves configured to selectively affect said fluid flow through said ports.

20. The system for pleural lavage according to claim 19, wherein said valves each comprise a detent button.

21. The system for pleural lavage according to claim 20, wherein each said detent button comprises a locking detent button.

22. The system for pleural lavage according to claim 21, wherein said detent button comprises a spring-return locking detent button.

23. The system for pleural lavage according to claim 20, wherein each said detent button comprises an open-bottom button with a closed top and sidewalls, and a post protruding downward from the top of the button.

24. The system for pleural lavage according to claim 23, wherein said housing comprises an annular slot for receiving the sidewalls of said detent button and a central tubular receptacle for receiving said post.

25. The system for pleural lavage according to claim 24, further comprising a spring in said receptacle for biasing said post.

26. The system for pleural lavage according to claim 24, wherein said post and said receptacle both have transverse apertures configured to selectively align by depression of said detent button.

27. A method of delivering pleural lavage to a patient using a fluid infuser, at least one suction source, a drainage collection chamber, and a chest tube, comprising the steps of: connecting a first tube to one of said at least one suction sources, via said drainage collection chamber; connecting a second tube to said fluid infuser; connecting a pleural lavage controller having one fluid port connected to a chest tube and manifolded to a plurality of fluid ports, each of said plurality of ports connected to said first and second tubes; operating said pleural lavage controller to sequentially apply a fluid from said fluid infuser, and suction from said suction source, over a duration of chest drainage.

28. A method of delivering pleural lavage to a patient according to claim 27 further comprised of a third tube connected to one of said plurality of ports; the third tube being in fluid communication with one of said at least one suction sources.

29. A method of delivering pleural lavage to a patient according to claim 28 further comprised of a second drainage collection chamber connected between said third tube and one of said at least one suction sources.

30. A pleural lavage controller, comprising: a housing comprising a plurality of fluid chambers, including a first fluid chamber and a second fluid chamber both in fluid communication with a third fluid chamber; a plurality of fluid ports each in fluid communication with one of said plurality of chambers, including a first port in fluid communication with said first fluid chamber, a second port in fluid communication with said second fluid chamber, and a third port in fluid communication with said third fluid chamber; a chest tube connected to said third fluid port; and a plurality of finger-valves in each of said plurality of fluid chambers for selectively admitting and preventing fluid flow-through from the corresponding fluid port to said third fluid port connected to said chest tube.

31. A pleural lavage controller of claim 30 further comprising a fourth fluid chamber that is in fluid communication with said third fluid chamber; said fourth fluid chamber being in fluid communication with said fourth port.

32. The pleural lavage controller according to claim 30, wherein each of said ports is frustoconical.

33. The pleural lavage controller according to claim 30, wherein said housing comprises distinct protrusions from said housing.

34. The pleural lavage controller according to claim 30, wherein said plurality of finger valves each comprise a detent button.

35. The pleural lavage controller according to claim 34, wherein each said detent button comprises a locking detent button.

36. The pleural lavage controller according to claim 34, wherein each said detent button comprises a spring-return locking detent button.

37. The pleural lavage controller according to claim 34, wherein each said detent button comprises an open-bottom button with a closed top and sidewalls, and a post protruding downward from the top of the button.

38. The pleural lavage controller according to claim 37, wherein said housing comprises an annular slot for receiving the sidewalls of said detent button and a central tubular receptacle for receiving said post.

39. The pleural lavage controller according to claim 38, further comprising a spring in said receptacle for biasing said post.

40. The pleural lavage controller according to claim 37, wherein said post and said receptacle both have transverse apertures configured to selectively align by depression of said detent button.

41. The pleural lavage controller according to claim 30, further comprising a flowmeter mechanically coupled to at least one of said plurality of finger-valves.

42. The pleural lavage controller according to claim 30, further comprising a pressure gauge mechanically coupled to at least one of said plurality of finger-valves.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] Other objects, features, and advantages of the present invention will become more apparent from the following detailed description of the preferred embodiments and certain modifications thereof when taken together with the accompanying drawings in which:

[0018] FIG. 1 is a perspective diagram illustrating a chest tube initially placed superiorly.

[0019] FIG. 2 is a perspective diagram illustrating how undrained blood tends to remain in the lower and posterior pleural space.

[0020] FIG. 3 is a perspective drawing showing how the system of the present invention connects to standard hospital equipment to enable switching between pressurized lavage, high pressure suction, and standard low pressure chest drain.

[0021] FIG. 4 is a perspective view of a balloon catheter being advanced through the chest tube via the lavage controller of the system of FIG. 3.

[0022] FIG. 5 is an isometric view of the lavage controller of FIG. 4 showing a spring-return locking detent valve.

[0023] FIG. 6 is a perspective illustration of controller 40 with a cutaway view of an exemplary spring-return locking detent valve.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

[0024] The present invention is a system to facilitate a prophylactic rapid pleural lavage protocol at the time of thoracostomy tube placement for traumatic hemothorax in order to reduce the need for secondary intervention for the management of retained hemothorax.

[0025] As seen in FIG. 3, the present system includes a rapid saline infuser 10 configured for infusion of saline into the pleural cavity. Preferably the saline infuser 10 and thoracostomy tube should be configured for emptying a 1000 cc saline bag in at most 30 seconds, and optimally should be configured for emptying a 1000 cc the same bag in 20 seconds, the latter enabling a 500 cc lavage in 10 seconds. It is also preferable for the saline infuser to warm the saline to substantially average body temperature prior to infusion. In the illustrated embodiment, the saline infuser 10 comprises a commercially available rapid infuser by Level 1™, Inc., which includes a fast flow rate fluid warmer capable of sustained flow rates in a range of from 30 ml/min to 1100 ml/min with a maximal rate of 1400 ml/min through a small bore peripheral venous catheter (typically 20 gauge needle with 0.6 mm internal diameter). These flow rate specifications depend on Poiseuille's law, the variables being the internal diameter (D) and length (L) of the chest tube, the viscosity of the liquid (h) and the pressure of the saline infuser 10. If the diameter of a tube is doubled, flow will increase by a factor of 16, implying that small increases in the size of drainage tubes will result in large increases in flow rates. Traditionally, large bore (>28 F, 9 mm internal diameter) catheters are recommended in almost all situations that required chest drainage. Given the substantial difference in internal diameter between a peripheral venous catheter and traditional thoracostomy tube, the rapid infuser will be capable of providing significantly higher flow rates through a thoracostomy tube. Similar commercial products are available from Belmont™ or Thermacor™. Alternatively, a manual pressure infusion bag may be used such as the Infu-Surg® pressure infusion bag. Manual pressure infusion bags are very low cost and ubiquitous at hospitals, and operate in the same manner and at the same pressures (˜300 mmHg) as the above-described rapid infusers. However, they lack the automation for warming and pressurizing the saline. Nevertheless, tests conducted by the present inventors demonstrated that, when pressurized to 300 mmHg, a manual pressure infusion bag was likewise capable of emptying a 1000 cc the same bag in 20 seconds. Still another option for the saline infuser is to use a suction/irrigation pump such as the StrykeFlow™ II system manufactured by Stryker, or a Stryker AHTO system. The StrykeFlow II is a battery-operated, fully disposable fixed-flow-rate pump that hangs from the saline bag and operates by generating negative pressure within the tubing to draw fluid from the IV bag. The Stryker AHTO, on the other hand, features a reusable pump, with three flow rate settings up to 4 L/min. However, the goal here is to impart a 500 mL lavage in just a few seconds and current surgical irrigation pumps are less-well suited for this. Finally, saline infuser 10 may also function via more passive/manual means such as gravity or ambient air pressure. For example, the saline infuser 10 may consist of simply a saline bag that is hung at a height above the patient such that it passively flows into the patient's pleural space. Similarly, the saline infuser 10 may simply be a funnel into which saline is poured. In addition to the saline infusion device 10, a conventional low pressure chest drain 30 is provided along with a conventional high-pressure suction unit 20. Typical chest drainage systems connect to a suction source and include a pressure regulator, seal, and collection chamber. The seal typically consists of a water seal or dry seal (one way valve) that allows air to exit from the pleural space on exhalation, while preventing air from entering the pleural cavity or mediastinum on inhalation. For present purposes the chest drainage system 30 may be a three-chamber drainage system such as the Pleur-evac™ available from Teleflex, Inc., and suction unit 20 may be a conventional surgical suction pump may be used such as a Medala™ Basic.

[0026] Three ports to a pleural lavage controller 40 are connected in fluid communication with the chest drainage system 30, suction unit 20, and rapid saline infuser 10 via tubes 51, 52, 53, respectively. If desired, an optional second collection chamber or chest drainage system 30 may be connected inline between suction unit 20 and port 42 to drain the contents of tube 52, as shown in dotted lines in FIG. 3. The ports of lavage controller 40 are manifolded to a single port that is connected to a standard chest tube 50 for administering a protocol consisting of saline instillation, chest drainage, and suction to slow the clotting process, prevent “gelling” of blood, and maintain drainability over the duration of chest drainage. Importantly, the lavage controller 40 facilitates easy transition from lavage via the rapid saline infuser 10, to high wall suction via the suction unit 20, to low pressure chest drain via the unit 30 all without breaking a sterile circuit. Moreover, using the lavage controller 40 a clinician can tailor the lavage protocol (e.g., amount of infused saline per lavage cycle, and number of lavage cycles at time of tube placement) and repeat the lavage at a later time based upon clinical indications. In addition, the lavage controller 40 provides flexibility for other future therapies/procedures to be administered through the chest tube 50 without breaking the sterile circuit, such as introduction of a fibrinolytic solution, and/or the use of a balloon catheter for tube clearance and/or pneumatic agitation at the distal tip of the chest tube 50, etc.

[0027] The present system may be easily assembled at the time of chest tube 50 placement to preserve sterility. For example, if the balloon catheter (FIG. 4) is to be used, there are two options:

[0028] 1) simply disconnect tube 53 from lavage controller 40 and introduce the balloon catheter via the same port 43 (this is convenient but may slightly compromise sterility of the circuit);

[0029] 2) provide a balloon catheter that is preconnected off of a Y in tube 53, but housed in a plastic sleeve until use. That is, when advancing the balloon catheter through the chest tube 50, the plastic sleeve scrunches up. Then when withdrawn from the chest tube 50 the balloon catheter remains housed in the plastic sleeve. This approach will prevent the user from ever breaking the sterile circuit.

[0030] FIG. 4 is a close-up view of the lavage controller 40 with three input ports 42, 43, 44 manifolded to a single port 45 that is connected to standard chest tube 50. FIG. 4 also depicts a balloon catheter 53 that has been inflated after introduction through the chest tube 50 via port 43 and through port 45. The lavage controller 40 generally comprises a molded housing 41 with three ports 42, 43, 44 manifolded to a single port 45 that is connected to standard chest tube 50.

[0031] Each of the four ports 42-45 comprises a frustoconically-shaped outward protrusion that tapers outwardly from the housing 41, and defined by a central lumen and annular-exterior ribs or steps. The frustoconical shape enables connection to variously-sized tubes 50-53 and the annular ribs/steps prevent dislodgement of the tubes 50-53 once inserted thereon.

[0032] As seen in FIG. 5, the housing 41 is shaped as a three-pronged trident with three distinct branching chambers each axially aligned with one port 42-44, all converging to an axis, and one coaxial trailing chamber for the port 45. The port 45 extends directly rearward and is axially aligned with and in fluid communication with the chamber. The three ports 42-44 are aligned with and in fluid communication with the chambers. Importantly, the three ports 42-44 and their respective chambers axially converge at shallow angles not exceeding 45 degrees to ensure “soft” fluid branching there through, effectively reducing the risk of clogging by minimizing torturous fluid pathways. Each chamber of the housing 41 is equipped with a spring-return locking detent valve 46, 47, 48 for stopping or allowing fluid flow from each port 42-44 to port 45. The spring-return locking detent valves 46, 47, 48 are marked with proper indicia for designating the port (HP for high pressure, LP for low pressure, and Ag/Tube for saline infusion), both to indicate which port 42-44 is being actuated and which tube to connect. Similarly, the port 45 is marked with proper indicia to indicate connection of the chest tube 50.

[0033] FIG. 6 is a perspective illustration of controller 40 with a cutaway view of an exemplary spring-return locking detent valve 47. Detent valve 47 comprises an oval open-bottom button with a closed top and vertical sidewalls. The sidewalls slide vertically into a conforming channel formed in housing 41. A vertical post 141 protrudes downward from the top of the button into a tubular receptacle formed in housing 41, which serves to selectively allow/stop fluid flow. A spring 142 underlies the post 141 and biases it to a normally-closed upward position shown. However, the post 141 has an aperture 143 traversing it, which aperture aligns with a conduit 144 through the housing 41 when the button and post 141 are depressed to allow fluid flow.

[0034] The illustrated detent valves 46-48 are preferably all biased by spring 142 to their normally-closed position. This generally prevents high pressure suction or lavage ports from inadvertent locking in an open position. However, it may be desirable to lock the valve 48 to low pressure chest drain 30 (See FIG. 3) in an open position, Any suitable locking arrangement may be used for this. For example, the valve 48 button may include an extensional flap or strap to engage a cooperating feature on the controller body 41. Alternatively a more complicated push-to-lock mechanism may be used similar to those in retractable pens. A variety of such mechanical locking means are disclosed such as by U.S. Pat. No. 8,157,242. Conversely, it may be desirable to lock all ports in a closed position to prevent someone from inadvertently introducing therapy. Again, any suitable locking arrangement may be used for this. For example, as shown in FIG. 6 while in their normally-closed (up) position the spring-return locking detent valves 46, 47, 48 may be twisted so that it no longer fits back inside the conforming channel formed in housing 41. Optionally, it may be desirable to prevent someone from opening more than one detent valve 46, 47, 48 at any time. A mutually exclusive locking arrangement can be accomplished with a suitable protrusion from each valve button that will interfere with a cooperating protrusion on another button if depressed. For the standard low pressure drain valve, we would want this to be lockable in the open position.

[0035] In addition to the foregoing, an integral flow meter, visual flow indicator or pressure gauge 70 may be included such as shown in FIG. 6 to provide immediate visualization of flow. Flow indicator 70 may be a conventional visual flow indicator such as a Bel-Art Roto-Flo™. Flow indicator 70 may be coupled at any port. For example, flow meter can be placed in line with the rapid saline infuser 10 (See FIG. 3) via tube 53 (See FIG. 4) to measure flow rate (rate of rotation) or even total volume (number of turns) instilled. The flow meter/indicator may optionally be linked to controller 40 (See FIG. 4) to provide an electrical or mechanical auto-stop feature after it rotates a predetermined number of times. Moreover, a pressure gauge may be optionally linked to controller 40 to provide a similar auto-stop feature.

[0036] Each of the spring-return locking detent valves 46, 47, 48 provide instantaneous control over the respective fluid flow to facilitate a prophylactic pleural lavage that enables easy transition from lavage, to high wall suction, to low pressure chest drain suction without breaking the sterile circuit. Moreover, the controller 40 (See FIG. 4) is simple and efficient to use, employing familiar tubing connections and control valves, and establishes a rapid, automated saline infusion process, thereby minimizing training requirements and barriers to adoption. The system as a whole can be deployed at the time of thoracostomy tube placement for traumatic hemothorax to reduce the need for secondary intervention for the management of retained hemothorax.

[0037] Having now set forth the preferred embodiments and certain modifications of the concepts underlying the present invention, various other embodiments as well as certain variations and modifications of the embodiments herein shown and described will obviously occur to those skilled in the art upon becoming familiar with said underlying concept. It is to be understood, therefore, that the invention may be practiced otherwise than as specifically set forth in the appended claims.