The currently available winged needle sets and prior art, particularly those using relatively large diameter needles typically larger than about 17 gauge, have “wings” that are believed to be at least 34 mm. wide on arteriovenous fistula sets. This is true when the tubing of said sets is large, typically with an outer diameter of at least about 5.0 mm., and when small tubing on scalp vein sets has only an outer diameter of 2 mm. or less.
It is now mandated by law that many needle sets must carry a needle protector to protect handlers of the set from accidental needle stick, after the needle has been used and withdrawn from the patient. An example of such a device is the MasterGuard® Slotted Needle Guard sold by Medisystems Corporation of Seattle, Wash., in which the needle guard passes along the wings of the needle to be protected, with the wings projecting outwardly through the slots.
Various slotless tubular needle guards are known as well, one such guard being proposed for use with a winged needle, namely the WingEater needle guard of JMS Co., Ltd., as illustrated in PCT published application WO 02/30491 A1 (in Japanese). A problem with this design resides in the difficulty in getting the wings to fold properly as a wide mouthed tube is advanced to enclose the winged needle by the tubular needle guard. Furthermore, the WingEater needle guard has a small pocket at the bottom of the front end thereof for capturing the point of the needle. In the practice of hemodialysis, the needle is often “flipped” by 180° rotation after insertion into the vein, in an attempt to maximize blood flow through the needle. In the flipped position, it is difficult or impossible for the needle tip, when removed from the patient, to be captured by the forward pocket of the WingEater device.
In accordance with this invention, a realization has arisen that there is no real need, especially in the case of larger winged needle sets where the needles are essentially no smaller than about 17 gauge, for the wings to be as wide as 34 mm. or more. Such hubs are large enough to be more readily graspable on their own than hubs of smaller needles. It may be that aesthetics has been a chief driving force for the design, but, in fact, it has been determined in accordance with this invention that a substantially narrower wing is useable, even with the larger diameter needles utilized in hemodialysis, blood collection, and the like. With a narrower wing, it becomes possible to develop a tubular, open-ended needle guard which can receive a winged needle without any need to fold the wings. Such a needle guard may have the advantage of easy needle insertion, plus a sealing capability against spillage of blood from the tubular needle set which carries the guard while the needle is guarded. By this invention, a set can be completely sealed after use. Also, the set can be safely and effectively sealed whether the winged needle is in the normal or the “flipped” position.
In accordance with this invention, a winged needle comprises a hollow medical needle which typically is essentially no smaller than 17 gauge. The needle is carried by a hub, the hub also carrying wings which project laterally outwardly from the hub in opposed directions. The wings have outer tips that are spaced from each other by essentially 20 to 30 mm., rather than the prior art outer wing tip spacing of at least about 34 mm. for larger needles of 17 gauge and more. Preferably, the outer tips may be spaced by no more than essentially 27 mm.
As is conventional, the needle and hub are connected to flexible tubing, to comprise an arteriovenous fistula set or other set, particularly a set that is intended for access to blood.
A tubular, slot-free, hollow needle guard, having self-supporting walls to define an inner chamber, may be carried on the tubing, with the needle guard defining a forward, end opening having a generally stable, two dimensional cross-sectional area. The hollow guard is proportioned to receive and surround the winged needle without substantial bending of the wings, which renders such a needle guard easier to install around the winged needle of this invention, when compared with other known, slotless needle guards. To accomplish this, the open end of the needle guard and the inner chamber, typically define an aperture having a horizontal dimension of essentially 20 mm. or greater, and a vertical dimension of essentially 3 mm. or more, sufficient to accomplish easy entry of the winged needle without substantial bending of the wings. This self-supporting, chamber-defining shape for a needle guard is different from, and advantageous over, the flexible envelope-type needle guards of Hogan U.S. Pat. Nos. 4,935,011 and 4,820,282, being substantially rigid in some embodiments, with the end opening having a substantially fixed dimension, but being typically subject to the slight resilience found in most hollow plastic items.
Furthermore, by this invention a similar guard for a winged tube set is provided having a hollow needle, a needle hub, and flexible set tubing attached to the hub. The guard comprises a needle guard tube which is free of wing-receiving slots, and defining a forward, open end. When in use, the guard tube contains a winged needle of a set, which winged needle has outwardly extending, substantially unbent wings positioned within the guard. The guard comprises a fixed-dimension, open mouth having a width of at least about 20 mm, a height of at least about 5 mm., and preferably a mouth having a width of essentially at least 25 mm., and generally no more than essentially 35 mm. Such a guard is generally utilized with a winged needle which can be received within the guard without substantial bending of the wings out of their initial, generally planar shape.
Further in accordance with this invention, a guard for a winged needle tube set of the above type having a hollow needle, a needle hub, and flexible set tubing attached to the hub may comprise a needle guard tube which is free of wing-receiving slots and which defines a forward, open end. An anchor strip may be attached to the forward end. The anchor strip may be attached to the rest of the guard by a first flex line, permitting transverse rotational movement of the anchor strip relative to the guard tube. This transverse, rotational movement may be either vertical, horizontal, or in some diagonal direction, and the first flex line may be carried on the anchor strip adjacent to the rest of the needle guard tube. A second flex line may also be defined in the anchor strip, spaced from and preferably parallel to the first flex line, permitting free, added rotational movement of an outer portion of the anchor strip.
Preferably, the first flex line is connected to a top wall of a generally rigid needle guard tube, and is substantially horizontal, to permit substantially vertical transverse rotational movement of essentially the entire anchor strip. The needle guard tube may be of rectangular cross section.
In some embodiments, the forward, open end of the needle guard tube may be partially defined by a bottom wall of the needle guard, which bottom wall extends horizontally beyond the top wall of the needle guard. The first and second flex lines may be spaced apart at about the distance of the height of the open end, to permit the anchor strip to pivot to close the open end, in which closed position the anchor strip occupies an L-shaped configuration, with an outer portion of the anchor strip lying against the bottom wall. It will also be seen in the drawings that outermost portions of the anchor strip may be spaced from the bottom wall.
In some embodiments, the anchor strip described above may define an outwardly extending projection between the first and second flex lines. This projection may be used to assist in the manual closing of the open end of the guard tube, to press the anchor strip into its L-shaped configuration, and to thus close and preferably seal the open end of the guard tube.
In some embodiments, the guard of this invention may carry a flow-blocking, tapered projection which is proportioned to sealingly engage a female luer. Such a female luer is typically carried by the winged needle tube set which carries the guard of this invention.
It also may be desirable for various embodiments of the guard of this invention to carry internal tube centering ribs.
In some embodiments, the needle guard of this invention defines a rear aperture through which the flexible tubing extends, with the hub being connected with the flexible tubing, where a first portion of the tubing is positioned outside and around a portion of the hub, and this first portion defines an increased outer diameter, when compared with the remaining portions of the flexible tubing. This may be accomplished by providing a first portion of the flexible tubing which is naturally of slightly larger outer diameter, or the flexible tubing used may be all naturally of the same outer diameter, but the first portion is stretched by being placed on a projecting rigid or semi-rigid tube of the hub, which stretches that first portion of the flexible tubing into an outer diameter which is greater than the natural outer diameter of the rest of the flexible tubing.
In accordance with this invention, the rear aperture is sized to permit easy sliding of the remaining portions of the flexible tubing through it, so that the guard of this invention may easily slide along the flexible tubing, being captured and held on the flexible tubing by the fact that the flexible tubing passes through the rear aperture of the guard. However, edges of the rear aperture bind against the first portion of the tubing, since it is of larger outer diameter, to form a seal with the first tubing portion, when the first portion extends through the rear aperture of the guard. The increase in outer diameter of the first tubing portion only has to be a few thousands of an inch for the guard to slide easily along most of the tubing, but to bind against and form a seal with the first portion of the tubing carried on the hub, so that blood which leaks from the needle into the interior of the guard does not leak out of the rear aperture when the needle is enclosed in the guard.
The needle of a needle tube set may be safely removed from a first position in which the needle penetrates a patient, to a second position where the needle is safely enclosed in a needle guard tube, by a method which comprises:
The open, front end of the guard may be partially defined by a bottom wall of the needle guard tube which extends horizontally beyond the top wall of the needle guard tube. An outer portion of the anchor strip lies against the bottom wall when in L-shape and is wedged into closing relation with the open end.
Thus, a guard is provided which can seal its front end after the winged needle is enclosed, while preferably avoiding the difficulties which can arise with a guard which bends and folds the flexible needle wings as the needle is drawn into the guard. Because of the lateral forces created by such wing folding, the needle tip can thrash side to side or up and down during its removal from a blood vessel, doing significant damage to the blood vessel and resulting in a possible hematoma.
Furthermore, the use of needles with a shortened wing width enables the needle to be “flipped” (rotated by 180°) more safely than with longer wings, as the physician or nurse seeks better blood flow from the fistula or vein which has been penetrated. Up until now, special, more costly “rotatable hub” sets were needed to flip needles easily and safely. However, a short, fixed wing as described herein flips with the essential ease of a rotatable wing, but does not exhibit the problems with such rotatable hubs, namely difficulty in control of the needle point bevel and point position of the needle both before, during, and after cannulation.
As a further advantage, a typical, known taping scheme for safely securing a winged needle to the skin of a patient has been the so called “chevron design”. A tape loop is placed under the tube of the winged needle set, and then the lengths of tape from the loop are crossed over each wing. This is a fairly difficult manual process, which requires manipulation of the needle hub and wings in a way that can cause movement of the sharp needle tip in the blood vessel, thus risking hematomas. A shorter, fixed wing set requires much less manipulation to install taping in the conventional Chevron pattern.
Furthermore, the winged needle can advance into the guard of this invention with resistance forces that are substantially less than guards where the wing must be folded. For example, while the WingEater guard generally requires an entry force of about 550 grams to fold the wings and cause entry of the needle into the guard, the guard of this invention, engaging a winged needle as described herein, may enter its guard at a force of about 210 grams or less, since the wing is not being folded or otherwise significantly bent.
a is a rear perspective view of a guard similar to the guard of
a are elevational views of the needle set and guard of
Referring to the drawings, and particularly
While at least one prior art butterfly needle set having a much thinner needle (27 gauge) has a tip-to-tip wing diameter of 28 mm., it appears that the prior art teaches that larger needles require wide wings for use, thus failing to appreciate the advantages of narrow wings as described herein.
Specifically, the spacing between wing outer tips 18 in a first embodiment of this invention may be about 26-27 mm.
Needle set 10 also comprises flexible set tubing 20, which is connected to hub 14 in a conventional manner (
It should further be noted that winged needle set 10 is shown in
Needle guard 30 is shown, particularly in
Thus, needle 12 may be completely drawn into needle guard 30 and held therein as shown particularly in
Needle guard 30 also carries an anchor strip 36 which comprises a sheet of plastic material as shown, integrally attached to the top wall of needle guard tube 32 by a first flex line 38, which specifically may be a plastic living hinge of generally conventional construction. This permits vertical, transverse rotational movement of anchor strip 36 relative to guard tube 32. A second, living hinge flex line 40 is also defined in the anchor strip 32, spaced from first flex line 38, which also permits vertical rotational movement of an outer portion 42 of anchor strip 36. As shown, anchor strip 36 may define an upward curve at its outer end 44 to facilitate manual retention, in accordance with the teachings of Utterberg U.S. Pat. No. 5,951,529.
At forward, open end 34, bottom wall 46 of forward, open end 34 is shown to extend horizontally beyond the top wall 38 of needle guard 30, the forward end of which ends at first flex line 38. First and second flex lines 38, 40 are spaced apart at a distance of about the vertical spacing of open forward end 34, to permit anchor strip 36 to pivot about its flex lines 38, 40, to close end 34 in a manner particularly illustrated in
Guard 30 also carries a flow-blocking, tapered projection 54, which is proportioned with the outer shape of a male luer, to sealingly engage a female luer 22 of the winged needle set 10 that carries guard 30. The cutaway view of
As shown in
Needle guard 30 may be used by being initially carried on a rear portion of tube 20, with tube 20 extending through rear aperture 60 of guard 30, (
a shows how the process of
Following this, one may manipulate projection 50 with the fingers to bend anchor strip into the L-shape as illustrated in
As shown in
The detailed design and function of needle guard 30b in
Needle guard 30 may be used with any desired winged needle including conventional needles of enlarged wing transverse dimension, but preferably, a somewhat smaller, less bulky needle guard 30 may be provided for use with needle sets having wings of reduced transverse dimension as previously described herein.
Referring to
At the rear aperture 60a, a tube retention flange 72 that abuts hub 76 in
The above has been offered for illustrative purposes only, and is not intended to limit the scope of the invention, which is as defined in the claims below.
Number | Name | Date | Kind |
---|---|---|---|
4820282 | Hogan | Apr 1989 | A |
4935011 | Hogan | Jun 1990 | A |
5030212 | Rose | Jul 1991 | A |
5433703 | Utterberg et al. | Jul 1995 | A |
5562637 | Utterberg | Oct 1996 | A |
5951529 | Utterberg | Sep 1999 | A |
5983947 | Utterberg | Nov 1999 | A |
6616635 | Bell et al. | Sep 2003 | B1 |
20040102739 | Nakajima | May 2004 | A1 |
Number | Date | Country |
---|---|---|
WO 0174416 | Mar 2001 | WO |
WO 0230491 | Apr 2002 | WO |
Number | Date | Country | |
---|---|---|---|
20070250014 A1 | Oct 2007 | US |