Embodiments of the present disclosure generally relate to medical devices and associated methods of use. In particular, embodiments of the present disclosure relate to guidewires for use in medical procedures.
During certain medical procedures, a guidewire may be used to access a target area of a patient's body. Accessing the target area with the guidewire may include navigating the guidewire through tortuous passages and/or openings of the patient's body. Once in position, the guidewire may facilitate movement of another medical device to the target area. For instance, the guidewire may be inserted through the patient's body to the target area, and may act as a rail or support to facilitate delivery of a catheter, stent, cannula, endoscope, cutting device, retrieval basket, or the like, to the target area.
In one type of procedure, a guidewire can be used to access a bile duct in the patient's body. Next, a medical device may be advanced over the inserted guidewire and toward the bile duct, using the inserted guidewire as a rail. The characteristics of the guidewire may have an effect on how efficiently these, and other procedures, can be performed. For example, if the guidewire is too thick, it may be difficult to gain entry into the bile duct. If the guidewire is too thin, it may not be rigid enough to support the medical device, and may be easily bent so as to withdraw from the bile duct.
Therefore, guidewires having performance-enhancing characteristics are desired.
According to an embodiment of the present disclosure, a guidewire for performing medical procedures may include a central core. The central core may include a first region having a first width and a distal surface. The central core may also include a second region distal to the first region. The second region may have a second width different than the first width. The second region may also have a proximal surface. At least a portion of the distal surface of the first region may be angled relative to a portion of the proximal surface of the second region. The guidewire may also include a first covering surrounding the first region. The first covering and the first region may form a first covered region having a third width. The guidewire may also include a second covering surrounding the second region. The second covering and the second region may form a second covered region having a fourth width. The third width and the fourth width may be substantially equal.
According to another embodiment of the present disclosure, a guidewire for performing medical procedures may include a central core. The central core may include a first region having a first width and a distal surface. The central core may also include a second region distal to the first region. The second region may have a second width different than the first width. The second region may also have a proximal surface. At least a portion of the distal surface of the first region may be angled relative to a portion of the proximal surface of the second region. The central core may also include a third region distal to the second region. The third region may have a third width different than the second width. The central core may also include a fourth region distal to the third region. The fourth region may have a fourth width different than the third width. The guidewire may also include a first covering surrounding the first region. The first covering and the first region may form a first covered region having a fifth width. The guidewire may also include a second covering surrounding the second region and at least a portion of the third region. The second covering and the second region may form a second covered region having a sixth width. The fifth width and the sixth width may be substantially equal. The guidewire may also include a third covering surrounding the fourth region and at least a portion of the third region.
According to another embodiment of the present disclosure, a method of using a guidewire to introduce a medical device to a target area in a patient's body may include inserting the guidewire to the target area through the patient's body. The method may also include inserting a distal tip of the guidewire into an opening at the target area of the patient's body. The method may also include inserting a tapered region of the guidewire, proximal to the distal tip, into the opening. The method may also include identifying when a proximal end of the tapered region has reached the opening. The method may also include advancing a medical device over the guidewire to the target area while the distal tip and the tapered region remain in the opening, once the proximal end of the tapered region has reached the opening.
Additional characteristics, features, and advantages of the described embodiments will be set forth in part in the description that follows, and in part will be apparent from the description, or may be learned by practicing the disclosure. The disclosed subject matter can be realized and attained by way of the elements and combinations particularly pointed out in the appended claims.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only, and are not restrictive of the described embodiments, as claimed.
The accompanying drawings, which are incorporated in, and constitute a part of this specification, illustrate exemplary embodiments of the present disclosure and, together with the description, serve to explain the principles of the disclosure.
Reference will now be made in detail to embodiments of the present disclosure, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.
A guidewire 106 may be introduced into a central lumen of a cannula or sphincterotome 105. The guidewire 106 and sphincterotome 105 may be inserted into a proximal portion (not shown) of the shaft 102, and may be advanced through the central lumen of the shaft 102, toward the side opening 108. The sphincterotome 105 and the guidewire 106 may emerge from the opening 108, and may extend through or otherwise engage the elevator 109. As the sphincterotome 105 and the guidewire 106 extend from the opening 108, the elevator 109 may be moved to facilitate positioning of the sphincterotome 105 and the guidewire 106. For example, the elevator 109 may be tilted to redirect the sphincterotome 105 and the guidewire 106 to align with an opening, such as the patient's papilla 103. As the sphincterotome 105 and the guidewire 106 extend further out from the opening 108, portions of the guidewire 106 may be extended from the sphincterotome 105 so that those portions of the guidewire 106 may enter the papilla 103, and may proceed into the patient's bile duct 107. The sphincterotome 105 may be removed after the guidewire 106 has been inserted, by being withdrawn proximally from the guidewire 106. The guidewire 106 may act as a rail or support for introducing one or more other medical devices, such as a catheter, cannula, stent, retrieval basket, snare, or the like, to a target area of the patient's body. Further details of the guidewire 106 will be described in conjunction with subsequent figures.
In one embodiment, the end portion 112 of the elongated member 110 may include a wire core 113. The core 113 may have a first region 114, a second region 118, a third region 120, and a fourth region 124. In one embodiment, each of the regions may have a diameter different than diameters of the other regions. The core 113 may be made of, for example, any suitable biocompatible material, which may include, but is not limited to, metals, metal alloys, polymers, reinforced polymer composites, or the like. In some embodiments, the core 113 may be formed from one or more shape memory alloys, such as nitinol.
The first region 114 may extend to a proximal end (not shown) of the guidewire 106. A first covering 122 (
The first covering 122 may be made of parylene, polyimide, polytetrafluoroethylene (PTFE), a PTFE blend, fluorinated ethylene propylene (FEP), a FEP blend, epoxy FEP, perfluorinated ethylene-propylene copolymer (EFEP), an EFEP blend, or any other suitable coating. These types of coatings may be low-friction or lubricious, reducing impediments to the sliding of medical devices over the guidewire 106, while also helping to preserve the straightness of the guidewire 106. In one embodiment, the first covering 122 may be a PTFE spray coating. Exemplary materials for first covering 122, and exemplary thicknesses for first covering 122, are illustrated in
It is contemplated that in one embodiment, the first covering 122 may include a plurality of layers (not shown). Each of the layers may extend circumferentially around the core 113 in the first region 114. The layers may have substantially equal thicknesses. However, it is also contemplated that one or more of the layers may have a thickness different than a thickness of another of the one or more layers.
The second region 118 extends distally from the first region 114. The second region 118 may have a different diameter than the first region 114. For example, the second region 118 may have a smaller diameter than the first region 114. It is also contemplated that one or more portions of the second region 118 may have a smaller diameter than the first region 114, and one or more portions of the second region 118 may have a larger diameter than the first region 114.
Exemplary diameters for portions of the core 113, such as the first region 114 and the second region 118, are shown in TABLE 1 (
The diameter of the first region 114 may be substantially constant from one end of the first region 114 to the other. The diameter of the second region 118 may also be substantially constant from one end of the second region 118 to the other. When the second region 118 has a smaller diameter than the first region 114, the smaller diameter of the second region 118 may give that region more flexibility than the first region 114, which may facilitate navigation of the distal portion 112 through body openings and tortuous anatomy. Further, the smaller diameter of the second region 118 may provide space for a second covering 132 to encompass the second region 118, without having the second covering 132 extend radially beyond an outer diameter defined by the first covering 122. As such, the second covering 132 may have a different thickness than the first covering 122. The second covering 132 will be described in more detail below.
The first region 114 and the second region 118 may meet at a transition region 116. As shown in
It is contemplated that the transition region 116 may be located between approximately 15 cm and approximately 90 cm from a distal end of the fourth region 124. In another embodiment, the transition region 116 may be located between approximately 50 cm and approximately 70 cm from the distal end of the fourth region 124. In another embodiment, the transition region 116 may be located approximately 60 cm from the distal end of the fourth region 124. In yet another embodiment, the transition region 116 may be located between approximately 35 cm and approximately 70 cm from the distal end of the fourth region 124. For example, the transition region 116 may be located at approximately 25 cm from the distal end of the fourth region 124.
It is also contemplated that the transition region 116 may include a plurality of small transition regions, forming a plurality of steps (not shown). Each of those steps may include surfaces similar to the surfaces 116a and 116b, having characteristics similar to those of the surfaces 116a and 116b described above.
A third region 120 may extend distally from a distal end of the second region 118, to a proximal end of the fourth region 124. A diameter of the core 113 in the third region 120 may differ from a diameter of the core 113 in the second region 118, and/or may vary in a distal direction. For example, the diameter of the core 113 in the third region 120 may decrease in the distal direction, such that the third region 120 may form a taper between the distal end of the second region 118 and the proximal end of the fourth region 124. The taper may include a smooth, sloped surface, and/or a sloped surface formed by a plurality of steps. It is also contemplated that the diameter of the core 113 in the third region 120 may decrease in the distal direction over a first portion, and increase or remain constant in the distal direction over a second portion.
It is contemplated that the distal end of the third region 120 may be approximately 10 cm from a distal end of the fourth region 124. The core 113 in the transition region 116 is steeper than the third region 120, in that the transition region 116 undergoes its change in diameter over a shorter distance than the distance in which the third region 120 undergoes its change in diameter.
The fourth region 124 extends distally from the distal end of the third region 120. The diameter of the core 113 in the fourth region 124 may be substantially constant from one side of the fourth region 124 to the other, and/or may be less than the diameter of the core 113 in the third region 120. It is also contemplated that the diameter of the core 113 in the fourth region 124 may vary. For example, the diameter may increase over a portion of the fourth region 124, and/or may decrease over a portion of the fourth region 124.
The dimensions of the fourth region 124 may facilitate entry of the fourth region 124 into a body opening, such as the papilla 103. The dimensions of the core 113 in the fourth region 124 may also be configured such that when a distal end of the fourth region 124 encounters an obstruction or constriction in a body lumen, such as in the bile duct 107, the proximal end of the fourth region 124 may bend, initiating formation of a loop. To form the loop, the distal portion 112 may bend back on itself to form a āUā shape.
An area 127 lies where the proximal end of the fourth region 124 meets the distal end of the third region 120, and marks the location where looping may initiate. Proximal to the area 127, the diameter of the core 113 may begin to increase in a proximal direction, giving the third region 120 its taper. As the diameter of the core 113 increases, its strength and/or stiffness may also increase.
An area 129 lies where the proximal end of the third region 120 meets the distal end of the second region 118. During use, once the distal portion 112 has been inserted into an opening far enough, such that the area 129 is at the opening (and the fourth region 124 and third region 120 are through the opening), the inserted length of the distal portion 112 (e.g., the length of the fourth region 124 and third region 120) may have sufficient strength and/or stiffness to allow introduction of a medical device over the guidewire 106, and to the opening, without pulling the inserted length out of the opening due to bending of the inserted length.
The sheath or second covering 132 may encompass the second region 118 and at least a portion of the third region 120. The second covering 132 may have a thickness such that an outer diameter of the second covering 132 is substantially equal to an outer diameter defined by the first covering 122. For example, the thickness of the second covering 132 may be in the range of 0.002 to 0.003 inches. Further, any seam formed between the proximal end of the second covering 132 and the first covering 122 and/or the surface 116a, may have a width of 0.005 inches or less. Furthermore, the second covering 132 may have a black and yellow spiral color, or any other suitable outward appearance, to enhance its visibility. The second covering 132 may be formed from a suitable flexible, lubricious, and/or biocompatible material. Examples of materials may include one or more of PTFE, FEP, EFEP, Tecothane, a polyether block amide like PEBAX, such as 72D PEBAX, a polyamide material like Grilamid TR55, combinations of polymers, and/or any other suitable materials. In some embodiments, the second covering 132 may be coated with a hydrophilic coating, to enhance lubricity. In some embodiments, second covering 132 may be lubricious enough that a hydrophilic coating may be omitted.
It is contemplated that in one embodiment, the second covering 132 may include a plurality of layers (not shown). Each of the layers may extend circumferentially around the core 113 in the second region 118. The layers may have substantially equal thicknesses. However, it is also contemplated that one or more of the layers may have a thickness different than a thickness of another of the one or more layers. It is also contemplated that one or more of the layers may extend continuously across both the first region 114 and the second region 118. One or more layers of the second covering 132 may increase the bond strength between one or more other layers of the second covering 132 and the core wire 113.
In one contemplated embodiment, the second covering 132 may be made of 72D PEBAX, without tungsten loading, the 72D PEBAX being coextruded with an adhesive resin like BYNEL. In another contemplated embodiment, the second covering 132 may be made of Grilamid TR55 coextruded with BYNEL. In yet another contemplated embodiment, the second covering 132 may be made of a monolayer of reflowed EFEP. Exemplary materials for second covering 132, and exemplary construction processes for second covering 132, are illustrated in
A visual indicator 138 may be applied to the guidewire 106 to provide an indication of the location of the area 129. The visual indicator 138 may be in the form of a strip, band, or a coil, or any other suitable form. Additionally or alternatively, the visual indicator 138 may include printed ink. It is also contemplated that the visual indicator 138 may be radiopaque for viewing under fluoroscopy. For example, the visual indicator 138 may include one or more of tungsten, platinum, gold, tantalum, palladium, salts thereof, alloys thereof, or the like It is also contemplated that the visual indicator 138 may be visible to the naked eye.
The visual indicator 138 may be positioned on the second covering 132, at least partially round the second covering 132, at least partially embedded within the second covering 132, or positioned around the area 129, underneath the second covering 132. The visual indicator 138 may be centered over the area 129. For example, a center of the visual indicator 138 may be located a distance of approximately 10 cm from the distal end of the fourth region 124. Alternatively, an edge of the visual indicator 138 may be positioned over the area 129. It is also contemplated that the visual indicator 138 may be at least partially raised from a surface of the second covering 132, or may be flush with the surface of the second covering 132.
The fourth region 124, and at least a portion of the third region 120, may be encompassed by a substantially constant diameter third covering 130. The third covering 130 (
The third covering 130 may extend distally beyond the core 113 to help protect tissue from being punctured or otherwise damaged by the fourth region 124, during insertion of the distal portion 112 into and/or through the patient's body. The third covering 130 may be formed from one or more of, a polyurethane like TECOTHANE 1095 A, PEBAX 2533, PEBAX 2055, PEBAX 3533, an aliphatic polyether polyurethane like TECOFLEX, joined TECOTHANE/PEBAX, or jointed TECOTHANE/TECOFLEX. The material of the third covering 130 may also include a Tungsten filler to increase the radiopacity of the third covering 130, making the distal tip of the guidewire 106 visible via fluoroscopy. Exemplary amounts of filler are shown in TABLE 2 (
It is contemplated that in one embodiment, the third covering 130 may include a plurality of layers (not shown). Each of the layers may extend circumferentially around the core 113 in the third region 120 and/or the fourth region 124. The layers may have substantially equal thicknesses. However, it is also contemplated that one or more of the layers may have a thickness different than a thickness of another of the one or more layers. It is also contemplated that one or more of the layers may extend continuously across two or more of the first region 114, second region 118, third region 120, and fourth region 124. In one contemplated embodiment, the third covering 130 may including a radially inner layer of BYNEL; an intermediate layer of TECOTHANE, TECOFLEX, and/or PEBAX loaded with Tungsten filler; and a radially outer layer of PEBAX, without Tungsten filler, for its dielectric properties. The BYNEL layer may be between approximately 0.001 to 0.002 inches thick. The outer layer of PEBAX may be approximately 0.001 inches thick.
When the second covering 132 is made of one type of material and the third covering 130 is made of another type of material, a ring or sleeve 131 (
In one embodiment, the ring 131 may be made of a polyether block amide material like VESTAMID Care PEBA ME-B. The ring 131 may be between approximately 0.1 cm and 1.0 cm wide. The second covering 132 may be made of EFEP, and the third covering 130 may be made of PEBAX. In the absence of the ring 131, the EFEP forming the second covering 132 may flow under the PEBAX forming the third covering 130, lifting the third covering 130 off of the core 113 and creating an undesirable lip or other discontinuity at or near the joint 133. With the ring 131 at the joint 133 during the reflowing step, the EFEP forming the second covering 132 may bond with the PEBA forming the ring 131, and the PEBAX forming the third covering 130 may bond with the PEBA forming the ring 131, thus bonding the second covering 132 with the third covering 130. It is contemplated that the ring 131 may be omitted when the second covering 132 is formed of PTFE or FEP, since PTFE and FEP may create a better bond with PEBAX than EFEP when reflowed.
A visual indicator 139 may be applied to the guidewire 106 to provide an indication of the location of the area 127. The visual indicator 139 may be similar to the visual indicator 138. The visual indicator 139 may differ in that the radiopacity of the visual indicator 139 may be different from that of the third covering 130 and/or the visual indicator 138, so that the visual indicator 139 may be distinguishable from the third covering 130 and/or the visual indicator 138. The visual indicator 139 may be positioned around the third covering 130, embedded within the third covering 130, or positioned around the area 127 underneath the third covering 130. The visual indicator 139 may be centered over the area 127. Alternatively, an edge of the visual indicator 139 may be positioned at the area 127.
Aspects of the guidewire 106 may enhance the performance of guidewire 106 when used in a procedure. The length of guidewire 106 may allow a proximal portion of the guidewire 106 to extend through the shaft 102, while also allowing a distal portion of the guidewire 106 to extend distally out of the shaft 102 and into a target area, even when guidewire 106 travels through a subject's anatomy. Reducing the diameter of the core 113 in one or more of the regions 118, 120, and 124 may create thin bendable regions that have less stress and strain in their bends than in the region 114, making navigation through tortuous passages easier. The thick diameter of the region 114 may help improve pushability of the guidewire 106, enhance the tactile feel of the device in the hand of the user, and/or help transmit rotational forces from the proximal portion of the guidewire 106 to the distal portion of the guide wire 106.
Covering the core 113 with one or more of the coverings 122, 130, and 132 may help with insertion of the guidewire 106 due to their lubricity. Their lubricity may also help a user rotate the distal portion of the guidewire 106 in a controllable way. To rotate the distal portion of the guidewire 106, the user may rotate a proximal portion of the guidewire 106. If the distal portion of the guidewire 106 sticks to one or more surfaces in a subject's body, it may not rotate as the proximal portion of the guidewire 106 is rotated. When a sufficient twisting force has been imparted to the proximal portion of the guidewire 106, and/or an intermediate portion of the guidewire 106, the twisting force may overcome the sticking force (e.g., friction) between the distal portion of the guidewire 106 and the body surface, causing the distal portion of the guidewire 106 to rotate abruptly or whip. Because of the whipping, the user may not be able to position the distal portion of the guidewire 106 with enough accuracy to perform certain procedures.
From the user's perspective, it may be more desirable for there to be a one-to-one relationship between rotation of the proximal portion of the guidewire 106 and rotation of the distal portion of the guidewire 106. The lubricity of coverings 122, 130, and 132 may enhance the user's control by reducing sticking/friction between the guidewire 106 and body surfaces, leading to less whipping and a closer relationship between proximal portion rotation and distal portion rotation for the guidewire 106. The reduced diameter portions of core 113 may also reduce whipping by ensuring that there is less stress and strain built up in bent portions of the guidewire 106 when in use, since stress and strain can hinder rotation.
Coverings 122, 130, and/or 132 may also provide dielectric resistance for accessory products, like the sphincterotome 105, reducing the likelihood of capacitive coupling developing between the sphincterotome 105 and the core 113, and of a direct short developing between the sphincterotome 105 and the core 113. Materials for the coverings 122, 130, and 132 may also enhance guidewire performance in other ways. For example, an EFEP covering may be highly lubricious, while being thinner than other coverings. When the EFEP covering is on a bent region of the guidewire 106, the thinness of the covering may reduce stress and strain at the bend, and the lubricity of the covering may reduce sticking, leading to enhanced rotational control for the user. An FEP covering may bond well with core 113. A 72D PEBAX covering may be hard, receptive to co-extrusion with BYNEL for bonding to core 113, and receptive to receiving a hydrophilic coating for added lubricity. A Grilamid TR55 coating may have higher impact strength and/or durability than the other coatings, and may extrude well with BYNEL for bonding to core 113, making the coating desirable when the guidewire 106 is aggressively bent by, for example, the elevator 109.
A method of accessing a body opening, such as a patient's papilla 103, and treating a target area, such as the patient's bile duct 106, may include inserting the shaft 102 into a passageway in a patient's body, such as the patient's duodenum 101. The distal end 104 of the shaft 102 may be positioned near the papilla 103, with the opening 108 and elevator 109 turned towards the papilla 103.
The guidewire 106 may be inserted through the central lumen of the shaft 102 before the shaft 102 is inserted into the patient, during insertion of the shaft 102, or after insertion of the shaft 102. The guidewire 106 may be pushed out of the opening 108, and the elevator 109 may be actuated to guide the guidewire 106 toward the papilla 103.
The distal portion 112 of the guidewire 106 may approach the papilla 103. The guidewire distal tip 142, which may include a rounded distal end of the third covering 130, may reach the papilla 103, and its relatively low compliance (compared to other portions of the guidewire 106) may help facilitate its entry into the papilla 103. The distal portion 112 may be pushed through the papilla 103 until the visual indicator 138 reaches the papilla 103, indicating that the area 129 has reached the papilla 103. The user may be able to view the visual indicator 138 reaching the papilla 103 via fluoroscopy. Once this happens, the user may be assured that the length of the distal portion 112 inserted through the papilla 103 has a sufficient strength and/or stiffness, such that medical devices may travel over the guidewire 106, using the guidewire 106 as a rail, without causing the inserted length to be bent severely enough to be pulled out of the papilla 103.
The guidewire 106 may be inserted even further through the papilla 103, into, for example, the bile duct 107. Using fluoroscopy, the user may track movement of the guidewire distal tip 142, providing the user with an indication of the depth to which the guidewire 106 has been inserted. If, in the bile duct 107, the guidewire distal tip 142 contacts an obstruction or constriction, such as a stone (not shown) in the bile duct 107, the guidewire distal tip 142 may engage the stone. The fourth region 124 may, at the area 127, begin bending to form a loop. Using fluoroscopy, the user may identify that bending has occurred, and based thereon, may identify an approximate location of the stone in the bile duct 107. If no bending occurs, it may indicate that the bile duct 107 is clear of obstructions or constrictions.
If an obstruction, such as a stone, is found, a medical device, such as a retrieval basket, may be inserted over and along the guidewire 106, using the guidewire 106 as a rail, to deliver the retrieval basket to the stone. The retrieval basket may be actuated to capture the stone, after which the retrieval basket may be withdrawn from the guidewire 106.
Embodiments of the present disclosure may be applicable to various and different medical or non-medical procedures. In addition, certain aspects of the aforementioned embodiments may be selectively used in collaboration, or removed, during practice, without departing from the scope of the disclosure.
Other embodiments of the present disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the embodiments disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.
This application claims the benefit of U.S. Provisional Application No. 61/842,692, filed Jul. 3, 2013, the disclosure of which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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61842692 | Jul 2013 | US |