This application relates to medical devices and, more particularly, to a wire guide with a plurality of usable tips.
Wire guides are commonly used to introduce a wide variety of medical devices into a patient's vascular system or other bodily lumen. For example, wire guides may be used in angioplasty procedures, diagnostic and interventional procedures, percutaneous access procedures, or radiological and neuroradiological procedures in general. A traditional wire guide may include an elongated core element and a flexible helical coil at a distal end portion of the core element. The wire guide may also include a handle at the proximal end of the core element to steer the wire guide as it is being advanced through a patient's vascular system or other bodily lumen.
Wire guides may encounter various challenges as they are moved through a patient's vascular system or other bodily lumen. As one example, in a pedal access procedure the wire guide is inserted from the foot (pedal) so that the wire guide can traverse up into the leg below the target site. In such a procedure, assistance may be needed to direct the distal tip of the wire guide into a branch of the limb's vascular system. For example, the wire guide may experience a 90 degree or greater turn from the main vessel into the branching targeted vessel. Therefore, a physician may insert a snare into the patient from a second access location above the target site. The physician may use the snare to grab the wire guide at the tip and direct it into the branching vessel. Although the snare may help guide the tip of the wire guide, this contact between the snare and the wire guide tip may permanently damage the tip.
A wire guide may also be damaged in other procedures. For example, the patient's vascular system or other bodily lumen may contain occlusions that impede the wire guide along its path. The physician may attempt to break apart the occlusion by pushing the wire guide through the occlusion, but this contact between the distal tip of the wire guide and the occlusion may damage the distal tip.
When the distal tip of the wire guide is damaged, further use of the wire guide may be difficult for the physician or dangerous to the patient. Thus, a need exists for an improved wire guide.
In one implementation, a medical wire guide is provided that includes a mandril having a distal tip, a first coil coupled with the distal tip of the mandril, and a second coil configured to releasably engage with the mandril or the first coil. The second coil comprises a distal tip and defines an inner cavity dimensioned to contain a distal tip of the first coil when the second coil is engaged with the mandril or the first coil.
In another implementation, a medical wire guide is provided that includes a mandril having a distal tip, a first coil coupled with the distal tip of the mandril, and a second coil. The first coil has an interlocking portion and a distal end portion. The distal end portion of the first coil tapers in from a dimension of the interlocking portion of the first coil. The second coil has an interlocking portion, a distal end portion, and an inner cavity between the interlocking portion and the distal end portion. The interlocking portion of the first coil is dimensioned to releasably engage with the interlocking portion of the second coil. The distal end portion of the first coil is contained within the inner cavity of the second coil when the interlocking portion of the second coil is engaged with the interlocking portion of the first coil.
In yet another implementation, a medical wire guide is provided that includes a mandril having a body portion and a distal tip, a first coil coupled with the distal tip of the mandril, a cannula having a proximal end and a distal end, and a second coil having a proximal end and a distal end. The proximal end of the cannula is configured to releasably engage with the body portion of the mandril, and the first coil is contained within the inner cavity of the second coil when the cannula is engaged with the body portion of the mandril.
The components in the figures are not necessarily to scale. Moreover, in the figures, like referenced numerals designate corresponding parts throughout the different views.
This detailed description describes a medical wire guide that possesses a plurality of usable tips. For example, a first one of the wire guide tips may be used and then removed, revealing a fresh tip that resides beneath the first tip on the same end of the wire guide. A wire guide with multiple usable tips may be especially beneficial for medical procedures that require different tip properties at different stages of the procedure or for medical procedures that commonly result in damage to the leading tip of the wire guide. For example, a wire guide with multiple tips would allow a physician to remove a damaged wire guide tip and then continue to use the same wire guide with the newly revealed second tip to complete the procedure. Having multiple usable tips in a wire guide could save the time and materials that would otherwise be wasted by removing the damaged wire guide and inserting a new wire guide to complete the procedure after the first wire guide was damaged. These savings are especially helpful given the rise of health care costs.
The wire guide assemblies described herein are formed from a plurality of components, including mandrils, coils, safety wires, and cannulas, which will each be described below in connection with
The mandril 10 may be formed of a suitable metallic material such as medical grade stainless steel, a stainless steel alloy, a super-elastic material including a nickel-titanium alloy (e.g., Nitinol), a liner-elastic material, or combinations of these materials. Alternatively, other suitable mandril materials may be used. The mandril 10 may include a radiopaque material, such as platinum or gold. Inclusion of a radiopaque material may increase the visibility of the wire guide within the body of a patient. In some implementations, a radiopaque material may be included in other portions of the wire guide, such as in the various coils, safety wires, and cannulas.
It will be appreciated that the mandril 10 may take one of many different shapes. In some implementations, the mandril 10 has a circular cross-sectional shape. In other implementations, the mandril 10 has a rectangular cross-sectional shape. In yet other implementations, the cross-section of the mandril 10 assumes different shapes along the length of the mandril 10. The mandril 10 may have a cross-sectional area that remains substantially constant along its length. Alternatively, the mandril 10 may have a cross-sectional area that varies along its length. In one implementation, the mandril 10 has a cross-sectional area that diminishes gradually or stepwise at increasing distances from the proximal end of the wire guide such that the mandril 10 tapers to a smaller diameter toward its distal end. For example, as shown in
The shoulder portion 14 of the mandril 10 may be ground into the beginning of the taper to provide a supporting surface for abutting a coil. The shoulder portion 14 may also provide a soldering surface for connecting a coil with the mandril 10. In one implementation, the shoulder portion 14 may be larger than the diameter of the coil abutting the shoulder portion 14 so that the coil cannot pass over the shoulder portion 14. The distal tip 18 of the mandril 10 may include a barrel at the end of the taper. The barrel of the distal tip 18 may provide support and an increased surface area for binding with a coil.
The coil 20 includes a proximal end portion 22, an interlocking portion 24, and a distal end portion 26. The interlocking portion 24 may have a different winding pitch than the proximal end portion 22 and the distal end portion 26. For example, as shown in
In one implementation, the proximal end portion 22 may represent 40% or more of the total length of the coil 20, the interlocking portion 24 may represent 10% of the total length of the coil 20, and the distal end portion 26 may represent 40% or less of the total length of the coil 20. Alternatively, other proportions of the length of the coil may be devoted to the respective portions.
The entire length of the proximal end portion 22 and the interlocking portion 24 of the coil 20 may have about an equal diameter (e.g., within either a 5%, 10%, or 20% variation in diameter). Alternatively, some portions of the proximal end portion 22 or the interlocking portion 24 may taper to a narrower diameter or extend to a wider diameter. The distal end portion 26 of the coil 20 tapers in from a dimension (e.g., diameter) of the interlocking portion 24 such that a distal-most segment 28 of the distal end portion 26 is smaller in diameter than the diameter of the interlocking portion 24 and may be smaller in diameter than other sections of the distal end portion 26.
The coil 30 may include an interlocking portion 32 and a distal end portion 34. The interlocking portion 32 may have a different winding pitch than the distal end portion 34. For example, as shown in
In one implementation, the coil 20 is soldered to the mandril 10, while the coil 30 is free from a direct connection with the mandril 10. For example, the coil 30 may be coupled with the mandril 10 by an indirect connection through a threaded engagement with the coil 20. The threaded engagement may be disconnected by twisting the coil 30 relative to the coil 20 in the opposite direction than used to connect the coil 30 with the coil 20.
As shown in
Each of the distal tips of the coils may be formed to promote atraumatic vessel navigation, such as by forming a rounded distal surface. The distal-most portion of the distal tip 28 of the coil 20 may be welded or soldered to form an atraumatic distal tip usable after the outer coil 30 is removed from the wire guide. As shown in
During a medical procedure, a physician may use the distal end of the coil 30 as the leading distal tip of the wire guide for a first stage of the procedure. At some point in the procedure, the physician may want to remove the coil 30 and expose the underlying coil 20 to act as the leading distal tip of the wire guide for another stage of the procedure. As one example, the physician may want to remove the coil 30 because it has been damaged. As another example, the physician may want to remove the coil 30 because the coil 20 has certain properties, such as an increased flexibility, that are better suited for the next stage of the procedure.
A physician may remove the coil 30 from the wire guide by pushing the distal end of the wire guide out of a second access location of the patient that is different than the first access location that was used to begin feeding the wire guide into the patient. The distal end of the wire guide may be exposed while other portions of the wire guide are still within a vascular passage or other bodily lumen of the patient. The coil 30 may be removed by locating an area distal to the intertwined coils and twisting the coil 30 relative to the coil 20 to disengage the threaded connection between the two coils. The interlocking portions may be visually marked in some way to enhance the ability of the physician to locate the area of connection between the coils. The threaded connection provides a simple removal process that may not require tools. Additionally, the threaded connection is unlikely to unscrew with torsion while in the patient. After the coil 30 has been removed to expose the distal tip of the coil 20, then the new distal tip of the wire guide may be retracted back into the patient through the second access location to continue the medical procedure with the distal tip of the coil 20 now serving as the distal-most portion of the wire guide.
Having two different usable distal tips available on one end of the wire guide allows customization of the two tips for different stages of the procedure. As a first example, the first coil 20 may be formed from a different material than the coil 30. The different properties of the materials may allow the coil 30 to be formed from a relatively stiff material for clearing occlusions, while the coil 20 may be formed from a relatively flexible material for traversing delicate passageways after the occlusions have been cleared. As a second example, the distal end portion of the coil 30 may be wound with a different pitch than the distal end portion of the coil 20. The different winding pitches may allow one coil to be stiffer or more flexible than the other. As a third example, the coil 30 may be wound from a wire with a different diameter than a wire used for the coil 20. The different wire diameters may allow one coil to be stiffer or more flexible than the other. As a fourth example, the diameter of the coil 20 may be smaller than the diameter of the coil 30. This difference in size may allow the wire guide to gain access to smaller passageways when led by the coil 20 after the larger coil 30 is removed from the wire guide. As a fifth example, one of the coils may have a curved shape. For example, the outer coil 30 may be separately curved so that the curved portion extends beyond the length of the inner coil 20. This difference in coil shape allows for a wire guide with both a curved distal tip option and a straight distal tip option. Alternatively, both coils 20 and 30 may be attached together while straight and then curved together at the same time. This implementation provides a wire guide with multiple curved usable tips. One or more of the coils may be curved by stretching the coil in a manner that provides space between adjacent coil rings to define the curve radius.
Additionally, the coils may be different from each other in multiple ways. For example, the distal tip of the coil 30 may be made of stainless steel with a very tight pitch and/or larger wire to create great stiffness for pushing through blockages, and the distal tip of the coil 20 that is contained beneath the coil 30 may be made of a softer material with a wider pitch and/or a smaller wire diameter for use further into the body as vessels become smaller or more fragile. Thus, the combinations of materials, coil pitches, coil diameters, and wire sizes result in a multi-purpose wire guide that may be customized to the unique set of requirements of an individual procedure.
Although the differences in properties between the coils 20 and 30 may provide a benefit in some procedures and implementations, in other procedures and implementations there may be a benefit to having multiple available distal tips with the same or similar properties. For example, the coil 20 may have many of the same properties as the coil 30, and thus serves as a redundant distal tip in case the coil 30 is damaged during use. In this situation, the coil 20 is available for use as the distal tip to continue the procedure after the damaged coil 30 has been removed. Having multiple redundant distal tips on the wire guide may provide a solution to replacing damaged wire guide tips by saving procedural time, hospital materials, and healthcare and procedural costs. It saves time and reduces the possibility of contamination by providing a ready, fresh wire guide tip without requiring the physician to fully remove the whole damaged wire guide and insert an entirely new wire guide to complete the procedure. For example, contamination may become an increasing concern when the wire in use has a length longer than 80 cm, which may require many personnel to assist in handling. By not requiring the complete removal of the wire guide in some implementations to get a new usable distal tip for the wire guide, the risk of contamination, lost time, and lost costs is reduced.
The coils 140 and 150 may be helical shaped wound coils formed by winding a wire to form a plurality of rings (e.g., wire turns). The coils may be wound by a coiling machine that presses the wire against a wedge to curve the wire into a coil shape. The coiling machine can control the pitch and diameter of the coil according to the operator's preferences. The wire used to form the coils 140 and 150 may be made from a suitable metallic material such as platinum, palladium, medical grade stainless steel, a stainless steel alloy, a super-elastic material including a nickel-titanium alloy (e.g., Nitinol), a liner-elastic material, or combinations of these materials. Alternatively, other suitable coil winding materials may be used for the coils 140 and 150.
One or both of the coils 140 and 150 may include a safety wire (e.g., similar to the safety wire 40 shown in
The mandril 160 of
In some implementations, the medical wire guides described herein include two usable tips. Alternative implementations of the wire guide may include more than two usable tips. As one example, one or more additional coils may be interconnected with the outer coil 30 of
The coils of the wire guides described herein may be releasably engaged with each other in several different ways. As one example,
The locking mechanism of the implementation of
The connection between the ring 236 and the void formed from the smaller diameter of the ring 234 provides resistance against movement of the outer coil 232 relative to the inner coil 230. However, a physician may intentionally pull the outer coil 232 relative to the inner coil 230 with sufficient force to dislodge the ring 236 from the void formed by the smaller diameter of the ring 234 to remove the outer coil 232 and expose the inner coil 230 for use as the distal tip of the wire guide.
The medical wire guides described herein may be dimensioned to fit within a vascular passage or other body lumen. The wire guide may generally have a length in the range of 30-600 cm. In some implementations, the length of the wire guide may be in the range of 90-300 cm. The wire guide may generally have an outer diameter in the range of 0.204-1.321 mm (0.008-0.052 inches). In some implementations, the outer diameter may be in the range of 0.254-2.286 mm (0.01-0.09 inches). For example, one type of wire guide may have an outer diameter of about 0.889 mm (0.035 inches). In other implementations, wire guides of other dimensions (e.g., longer, shorter, wider, or narrower) may also be used.
While various embodiments, features, and benefits of the present devices have been described, it will be apparent to those of ordinary skill in the art that many more embodiments, features, and benefits are possible within the scope of the disclosure. For example, other alternate devices may include any combinations of structure and functions described above or shown in the figures.
The present patent document is a divisional application that claims the benefit of priority under 35 U.S.C. § 120 of U.S. patent application Ser. No. 13/569,758, filed Aug. 8, 2012 which is hereby incorporated by reference in its entirety.
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Number | Date | Country | |
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20180185619 A1 | Jul 2018 | US |
Number | Date | Country | |
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Parent | 13569758 | Aug 2012 | US |
Child | 15910253 | US |