System and method for effecting non-standard fluid line connections

Abstract

A Luer-like non-standard quick disconnect medical fluid connector that cannot be engaged with a standard Luer fitting.

Claims

1. A medical fluid connector system comprising: a unitary male connector body defining: an inner hollow male cone; and an outer annular sleeve surrounding the male cone and radially spaced therefrom, the sleeve being internally threaded, the male cone extending axially beyond the sleeve, wherein the unitary male connector body includes structure that prevents engaging a standard female Luer fitting with the unitary male connector body, the structure including an inner diameter of the sleeve that is greater than an inner diameter of a sleeve of a standard male Luer fitting; the system also comprising a unitary female connector body comprising: a female cone; and at least two non-contiguous radially elongated triangular threads external to the female cone and configured for engaging the threads of the outer annular sleeve.

2. The system of claim 1, wherein the structure includes an outer diameter of the male cone that is greater than an outer diameter of a male cone of a standard male Luer fitting.

3. The system of claim 1, wherein the structure includes a thread pitch of the outer annular sleeve that is greater than a thread pitch of a sleeve of a standard male Luer fitting.

4. A medical fluid connector system comprising: a unitary female connector body defining: a female cone; and at least two radially diametrically opposed radially elongated triangular threads radially beyond the female cone and configured for engaging threads of a sleeve of a male connector body.

5. The system of claim 4, comprising: a unitary male connector body defining: an inner hollow male cone; and an outer annular sleeve surrounding the male cone and radially spaced therefrom, the sleeve being internally threaded for receiving the radially elongated thread of the female body, the male cone extending axially beyond the sleeve, wherein the male body includes structure that prevents engaging a standard female Luer fitting with the body.

6. The system of claim 5, wherein the structure includes an outer diameter of the male cone that is greater than an outer diameter of a male cone of a standard male Luer fitting.

7. The system of claim 6, wherein the structure further includes: an inner diameter of the sleeve that is greater than an inner diameter of a sleeve of a standard male Luer fitting; and a thread pitch of the sleeve that is greater than a thread pitch of a sleeve of a standard male Luer fitting.

8. The system of claim 5, wherein the structure includes an inner diameter of the sleeve that is greater than an inner diameter of a sleeve of a standard male Luer fitting.

9. The system of claim 5, wherein the structure includes a thread pitch of the sleeve that is greater than a thread pitch of a sleeve of a standard male Luer fitting.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a perspective view of a non-limiting intravascular heat exchange catheter, schematically showing a medicament source and heat exchange fluid source in an exploded relationship with the catheter;

(2) FIG. 2 is a perspective view showing two sets of male and female connectors in accordance with present principles; and

(3) FIG. 3 is a cross-sectional diagram as seen along the line 3-3 in FIG. 2.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

(4) Referring initially to FIG. 1, a therapeutic catheter system, generally designated 10, is shown for establishing and maintaining hypothermia in a patient, or for attenuating a fever spike in a patient and then maintaining normal body temperature in the patient. The catheter can also be used to maintain a patient's temperature during surgery.

(5) While FIG. 1 shows an exemplary embodiment of one heat exchange catheter, it is to be understood that the present invention applies to any of the catheters and accompanying heat exchange controllers disclosed in the above-referenced patents, including but not limited to the helical shaped devices disclosed in Alsius'U.S. Pat. Nos. 6,451,045 and 6,520,933. Also, one of the spiral-shaped or convoluted-shaped catheters disclosed in Alsius' U.S. Pat. Nos. 6,749,625 and 6,796,995, both of which are incorporated herein by reference, can be used.

(6) It is to be further understood that while the novel fluid connectors shown and described herein are illustrated in an intravascular temperature control catheter application, they can be used in other medical devices as well.

(7) Commencing the description of the system 10 at the proximal end, as shown the exemplary non-limiting system 10 includes a heat exchange fluid source 12 that can be a water-bath heat exchange system or a TEC-based heat exchange system such as any of the systems disclosed in one or more of the above-referenced patents. Or, the source 12 can be a source of compressed gas. In any case, the heat exchange fluid source provides warmed or cooled heat exchange fluid such as saline or compressed gas through a heat exchange fluid supply line 14, and heat exchange fluid is returned to the source 12 via a heat exchange fluid return line 16. A catheter, generally designated 18, includes a source tube 20 terminating in a female fitting 22, described further below. Also, the catheter 18 has a return tube 24 terminating in a male fitting 26, also described further below. The fittings 22, 26 can be selectively engaged with complementary fittings 28, 30 (shown schematically in FIG. 1) of the lines 14, 16 and also described further below to establish a closed circuit heat exchange fluid path between the catheter 18 and heat exchange fluid source 12. As intended herein, the fittings 22, 26, 28, 30 are quick disconnect fittings that cannot be engaged with standard Luer fittings, to avoid incorrect connections.

(8) With more specificity, a non-limiting catheter 18 may include a guide wire and primary infusion tube 32 that terminates in a fitting such as a standard female Luer 34. A standard male Luer 35 (shown schematically in FIG. 1) can be engaged with the female Luer 34 to advance a guide wire 36 through the tube 32 in accordance with central venous catheter placement principles, or medicament or other fluid can be infused through the guide wire and primary infusion tube 32 by means of the standard Luers 34, 35.

(9) Moreover, a secondary infusion tube 38 with standard female Luer fitting 40 can be selectively engaged with a standard male Luer fitting 41 (shown schematically in FIG. 1) of a medicament source 42 for infusing fluid from the source 42 through the secondary tube 38.

(10) The source 42 may be an IV bag. Or, the source 42 may be a syringe. In any case, because the coolant line fittings 22, 26, 28, 30 cannot be engaged with standard Luers, the coolant in the source 12 cannot be erroneously connected to the infusion lines 32, 38. Likewise, for the same reason the source 42 such as a syringe cannot be erroneously engaged with the coolant lines 20, 24.

(11) By “standard Luer” is meant a quick disconnect component, typically hard plastic, which in its male implementation has an inner cone surrounded by an outer internally threaded sleeve spaced from the cone, with the diameter at the tip of the cone being about 3.93 mm, a minimum internal thread diameter of the sleeve being about 7.00 mm, and a thread pitch being about 2.50 mm. In its female implementation a “standard Luer” is a female cone with external stub-like protrusions that act as threads and that are sized and shaped for engaging the internally threaded sleeve of the standard male Luer described above.

(12) The tubes 20, 24, 32, 38 may be held in a distally-tapered connector manifold 44. The connector manifold 44 establishes respective pathways for fluid communication between the tubes 20, 24, 32, 38 and respective lumens in a catheter body 46.

(13) In any case, the connector manifold 44 establishes a pathway for fluid communication between the heat exchange fluid supply tube 20 and the heat exchange fluid supply lumen of the catheter. Likewise, the connector manifold 44 establishes a pathway for fluid communication between the heat exchange fluid return tube 24 and the heat exchange fluid return lumen. Further, the connector manifold 44 establishes a pathway for fluid communication between the guide wire and primary infusion tube 32, and the guide wire lumen, which can terminate at an open distal hole 62 defined by a distally tapered and chamfered distal tip 63 of the catheter body 46. Also, the connector manifold 44 establishes a pathway for fluid communication between the secondary infusion tube 38 and the secondary infusion lumen, which can terminate at an infusion port 64 in a distal segment of the catheter body 46. Additional ports can be provided along the length of the catheter.

(14) An exemplary non-limiting catheter 18 has a distally-located heat exchange member for effecting heat exchange with the patient when the catheter is positioned in the vasculature or rectum or other orifice of a patient. The heat exchange member can be any of the heat exchange members disclosed in the above-referenced patents. By way of example, a non-limiting catheter shown in FIG. 1 can have proximal and distal thin-walled heat exchange membranes 66, 68 that are arranged along the last fifteen or so centimeters of the catheter body 46 and that are bonded to the outer surface of the catheter body 46, with the infusion port 64 being located between the heat exchange membranes 66, 68. Thus, each preferred non-limiting heat exchange membrane is about six centimeters to seven and one-half centimeters in length, with the heat exchange membranes being longitudinally spaced from each other along the catheter body 46 in the preferred embodiment shown. Essentially, the heat exchange membranes 66, 68 extend along most or all of that portion of the catheter 46 that is intubated within the patient. The heat exchange membranes can be established by a medical balloon material.

(15) The heat exchange membranes 66, 68 can be inflated with heat exchange fluid from the heat exchange fluid source 12 as supplied from the heat exchange fluid supply lumen, and heat exchange fluid from the heat exchange membranes 66, 68 is returned via the heat exchange fluid return lumen to the heat exchange fluid source 12.

(16) If desired, a temperature sensor 70 such as a thermistor or other suitable device can be attached to the catheter 18 as shown. The sensor 70 can be mounted on the catheter 18 by solvent bonding at a point that is proximal to the membranes 66, 68. Or, the sensor 70 can be disposed in a lumen of the catheter 18, or attached to a wire that is disposed in a lumen of the catheter 18, with the sensor hanging outside the catheter 18. Alternatively, a separate temperature probe can be used, such as the esophageal probe disclosed in U.S. Pat. No. 6,290,717, incorporated herein by reference. As yet another alternative, a rectal probe or tympanic temperature sensor can be used. In any case, the sensor is electrically connected to the heat exchange fluid source 12 for control of the temperature of the heat exchange fluid as described in various of the above-referenced patents.

(17) As envisioned by the present invention, the structure set forth above can be used in many medical applications to cool a patient and/or to maintain temperature in a normothermic or hypothermic patient, for purposes of improving the medical outcomes of, e.g., cardiac arrest patients, patients suffering from myocardial infarction or stroke, etc. As another example, head trauma can be treated by and after lowering and maintaining the patient's temperature below normal body temperature. Preferably, particularly in the case of myocardial infarction, the heat exchange portions are advanced into the vena cava of the patient to cool blood flowing to the heart. The catheter can be used to keep patients warm during skin graft surgery or other surgery.

(18) Now referring to FIGS. 2 and 3, details of the present connectors, male and female, can be seen. FIG. 2 shows the male and female connectors 26, 30 described above with relatively large tube barrels 80, 82 for accepting relatively large tubes 84, 86, respectively. Also shown are male and female connectors 88, 90 that in all essential respects are identical to the other connectors 26, 30 except they have smaller tube barrels for accepting smaller tubes. Accordingly, with that difference in mind discussion will focus on the first set of connectors 26, 30.

(19) The male connector includes an inner hollow cone 92 that protrudes slightly beyond an outer annular sleeve 94 as shown. While referred to for simplicity as a “cone”, as can be seen from the drawing the cone 92 technically is frusto-conical. The cone 92 is spaced from the sleeve 94 so that the female connector 30 can be advanced between the sleeve 94 and cone 92 as will be described shortly. To this end, the interior of the sleeve 94 is formed with threads 96, preferably two-start threads. The sleeve 94 joins with the tube barrel 80 as shown, and gripping flanges 98 are formed lengthwise along the tube barrel 80 and sleeve 94 to assist a person in grasping and rotating the connector 26.

(20) Turning to the female connector 30, the tube barrel 82 is hollow and frusto-conical, terminating in a ring-shaped end flange 100 that extends radially beyond the tube barrel 82 as shown. On the exterior of the flange 100, at least one and preferably radially diametrically opposed radially elongated male threads 102 are formed. In the preferred implementation a male thread 102 has a generally triangular shape; accordingly, one end 104 of the thread 102 is substantially pointed, with the male thread 102 flaring out in the axial dimension as it extends radially around the flange 100 to an opposed broad end 106 having a flat axially-oriented base 108 as shown. Like the male connector 26, the female connector 30 is formed with gripping flanges 110 that are formed lengthwise along the tube barrel 82 to assist a person in grasping and rotating the connector 30.

(21) With the above structure, the female connector 30 can be advanced between the sleeve 94 and cone 92 of the male connector 26 while rotating the connectors 26, 30 relative to each other to engage them in an interference fit.

(22) While the connectors 26, 30 may be engaged with each other, they may not be engaged with complementary standard Luer fittings owing in part to the structure above, e.g., the radially elongated male thread 102. Also preventing engagement of the connectors 26, 30 with standard Luer fittings are the preferred sizes and thread geometries set forth below.

(23) Specifically and referring to FIG. 3, the outer diameter “D1” of the cone 92 at its open end is about 5.97 mm, whereas recall that the diameter at the tip of the cone of a standard male Luer is about 3.93 mm, meaning that the cone 92 of the male connector 26 shown in FIGS. 2 and 3 is too large to allow a standard female Luer to slide over it. Furthermore, the minimum internal thread diameter “D2” of the sleeve 94 is about 9.68 mm, whereas recall that the minimum internal thread diameter of the sleeve of a standard male Luer is about 7.00 mm, meaning that the male stubs of a standard female Luer could not extend radially far enough to reach the threads 96 of the male connector 26. Still further, the thread pitch “P” of the male connector 26 is about 3.45 mm compared to the standard pitch of about 2.50 mm.

(24) The connectors described herein may be unitary molded structures made of a plastic such as nylon, polypropylene, polyethylene, or other suitable medical plastic.

(25) While the particular SYSTEM AND METHOD FOR EFFECTING NON-STANDARD FLUID LINE CONNECTIONS is herein shown and described in detail, it is to be understood that the subject matter which is encompassed by the present invention is limited only by the claims.