Arteriotomy positioning devices described herein may be useful when performing diagnostic or therapeutic procedures requiring vascular access. The devices may be used to position an expandable support relative to an arteriotomy in a blood vessel.
Some diagnostic or therapeutic procedures require access to a patient's vasculature (e.g., imaging procedure, angioplasty, stent delivery, or otherwise). To access the patient's vasculature percutaneously, a hollow needle may be inserted through a patient's skin and overlying tissue into a blood vessel. A guide wire may be passed through the needle lumen into the blood vessel, whereupon the needle may be removed. An introducer sheath may then be advanced over the guide wire into the vessel in conjunction with or subsequent to one or more dilators. A catheter or other device may be advanced through the introducer sheath and over the guide wire into a position for performing a medical procedure.
After completion of the diagnostic or therapeutic procedure requiring access to the vasculature, the arteriotomy can be closed by various mechanical or biological solutions, such as by applying external pressure (e.g., manually and/or using sandbags), cinching, suturing, and/or delivering metal implants, plugs, or sealants. However, many of these closure procedures may be time consuming, expensive, and uncomfortable for the patient, requiring the patient to remain immobilized in the operating room, catheter lab, or holding area for long periods of time. Additionally, some of these prolonged closure procedures may increase the risk of hematoma from bleeding prior to hemostasis.
When closing the arteriotomy using a metal implant, plug, sealant, or other appropriate sealing member, the health care professional may use a vascular closure device to position and deploy the sealing member. The vascular closure device may include a balloon near the distal end of the device to aid in positioning the sealant relative to the arteriotomy. The balloon is not inflated when the device is provided. The distal end of the device is inserted into the puncture until the uninflated balloon is positioned in the vessel. The balloon is then inflated, and the user can verify inflation by many methods, one including viewing an inflation indicator on a proximal end of the device. The device can then be positioned by withdrawing the device proximally until the inflated balloon contacts the vessel wall around the arteriotomy, indicating that the sealant is in the correct position. Such an indication is often provided by tactile feedback. Once the balloon contacts the vessel wall, the health care professional may continue pulling back on the device while the balloon remains inflated to apply a proximal force to the vessel wall. In existing devices, applying a proximal force to the vessel wall does not substantially change the shape of the balloon.
Arteriotomy positioning devices described herein may be used to position a sealing member adjacent to an arteriotomy. The arteriotomy positioning device may have a handle, a catheter assembly, a core wire, and an expandable member. The core wire may be substantially fixed relative to the handle, at least while the device is in the locating and/or tension states (described below). The catheter assembly may be moveable relative to the handle and the core wire. The proximal end of the expandable support may be connected to the catheter assembly, and the distal end of the expandable support may be connected to the core wire. The distance between distal end of the expandable support and a distal end of the handle may be substantially fixed, at least while the device is in the locating and/or tension states, whereas the proximal end of the expandable support may be moveable relative to the handle. The proximal end of the expandable support may be biased proximally, but moveable distally relative to the handle in response to various forces applied to the device.
The arteriotomy positioning device may have several states, including a resting state, a locating state, and a tension state. In the resting state, the expandable support may have a width small enough to fit through the arteriotomy. In the locating state, the expandable support may have a width large enough that it does not fit through the arteriotomy, but small enough that it can move freely through small vessels, thereby reducing the chance that the expandable support will interact with bifurcations or calcifications in the blood vessel while the user is moving the expandable support into position adjacent the arteriotomy. Finally, in the tension state, the expandable support may be wider than it is when the device is in the resting and locating states in order to occlude the arteriotomy and create temporary hemostasis. Because the width of the expandable support may vary between the locating state and the tension state, the width of the expandable support may be optimized based on the function being performed by the expandable support at a given time. The expandable support may be narrow enough when locating the device relative to the arteriotomy in order to fit through small vessels, but wide enough when tension is being applied to occlude the arteriotomy and create temporary hemostasis.
Another advantage of this arteriotomy positioning device is that the device status indicator can provide several indications to the user. The device status indicator can indicate if the expandable support is in a low-profile, medium-profile, or high-profile configuration. The device status indicator can also indicate if tension is being applied to the catheter assembly, and if so, if the amount of tension being applied is appropriate. The device status indicator can also indicate when the device is in the correct position relative to the arteriotomy, since the device will show that tension is being applied once the expandable member is pulled against the vessel wall. For example, if the expandable support is a balloon, the device status indicator can indicate whether the balloon is inflated, whether the device is in the correct position relative to the arteriotomy, and/or whether tension is being applied to the catheter assembly (and if so, whether the amount of tension being applied is appropriate).
An exemplary device for positioning an expandable support may comprise a handle; a catheter assembly having a lumen, the catheter assembly extending from the handle; a core wire extending from the handle through the lumen of the catheter assembly, the core wire having a proximal end connected to the handle and a distal end extending from a distal end of the catheter assembly; and an expandable support having a proximal end connected to a distal end of the catheter assembly and a distal end connected to the distal end of the core wire; wherein the catheter assembly is slidable relative to both the handle and the core wire. The expandable member may be moveable between a low-profile configuration, a medium-profile configuration, and a high-profile configuration. The device may further comprise a device status indicator that indicates whether the expandable support is in the low-profile configuration, the medium-profile configuration, or the high-profile configuration; and whether tension is being applied to the catheter assembly. A distance between the distal end of the handle and the distal end of the catheter assembly may increase as the expandable member moves from the low-profile configuration to the medium-profile configuration, and the distance further increases as the expandable member moves from the medium-profile configuration to the high-profile configuration. A distance between the distal end of the handle and the distal end of the core wire may remain substantially constant as the expandable member moves between the low-profile configuration, the medium-profile configuration, and the high-profile configuration. The device may further comprise a spring positioned in the handle, wherein the spring applies a proximal force to the catheter assembly relative to the handle and the core wire. The handle may comprise a fluid chamber, and an inflation port that allows communication with the fluid chamber. The lumen of the catheter assembly may communicate with the fluid chamber. The catheter assembly may comprise a catheter and a plunger. The catheter assembly may comprise a resting stop that limits proximal movement of the catheter assembly relative to the handle and the core wire. The catheter assembly may comprise a tension stop that limits proximal movement of the handle and the core wire relative to the catheter assembly.
An exemplary method for positioning a device adjacent to an arteriotomy of a blood vessel may comprise inserting a distal end of a device into the blood vessel, the device comprising a core wire connected to a handle, a catheter assembly slidable relative to the handle and the core wire, and an expandable support having a length, a width, a proximal end connected to the catheter assembly, and a distal end connected to the core wire, wherein the expandable support is in a low-profile configuration; increasing the width of the expandable support and decreasing the length of the expandable support, thereby moving the expandable support from the low-profile configuration to a medium-profile configuration; withdrawing the device proximally until the expandable support contacts a wall of the blood vessel adjacent to the arteriotomy; and applying tension to the catheter assembly to further increase the width and decrease the length of the expandable support and bring the expandable support to a high-profile configuration. The relative positions of the handle and the core wire may remain substantially constant during the steps of withdrawing the device proximally, and applying tension to the catheter assembly. The step of bringing the expandable support to the medium-profile configuration may cause the catheter assembly to move distally relative to the core wire. The step of applying tension to the catheter assembly may cause the core wire to move proximally relative to the catheter assembly. The device may comprise a visual indicator having an indicator feature and a series of indicator markings, and wherein the step of bringing the expandable support to the medium-profile configuration may cause the indicator feature to move relative to the series of indicator markings. The step of applying tension to the catheter assembly may cause the indicator feature to move relative to the series of indicator markings. The expandable support may comprise a balloon, and the width may be a maximum diameter of the balloon. The step of increasing the width of the expandable support and decreasing the length of the expandable support may comprise inflating the expandable support by pushing an inflation fluid through the catheter assembly and into the expandable support. The method may further comprise performing a procedure returning the device to the low-profile configuration; and withdrawing the device from the blood vessel. The procedure may be a vascular closure procedure.
Various embodiments are depicted in the accompanying drawings for illustrative purposes, and should in no way be interpreted as limiting the scope of the embodiments. Furthermore, various features of different disclosed embodiments can be combined to form additional embodiments, which are part of this disclosure.
The detailed description set forth below, in connection with the appended drawings, is intended as a description of various configurations and is not intended to represent the only configurations in which the concepts described herein may be practiced. The detailed description includes specific details for the purpose of providing a thorough understanding of the various concepts. However, it will be apparent to those skilled in the art that these concepts may be practiced without these specific details.
Various aspects of an arteriotomy positioning device may be illustrated by describing components that are coupled, attached, connected, pneumatically associated, and/or joined together. As used herein, the terms “coupled”, “attached”, “connected”, “pneumatically associated”, “in communication with”, and/or “joined” are interchangeably used to indicate either a direct connection between two components or, where appropriate, an indirect connection to one another through intervening or intermediate components. In contrast, when a component is referred to as being “directly coupled”, “directly attached”, “directly connected” and/or “directly joined” to another component there are no intervening elements shown in said examples.
An example embodiment of an arteriotomy positioning device 100 is shown in
The arteriotomy positioning device 100 may include a handle 110, as shown in
The interior of the handle 110 may have a fluid chamber 113. The fluid chamber 113 may be formed by the inner housing 110a. The handle 110 may include an inflation port 114 that is in communication with the fluid chamber 113. The fluid chamber 113 may be in communication with the interior of the expandable support 160 via a lumen 125 of the catheter assembly 120. Therefore, a syringe or other source of inflation fluid may be coupled to the inflation port 114 to provide inflation fluid to fluid chamber 113, such that the expandable support 160 is able to expand, as described below. The inflation fluid may be saline, air, or another fluid appropriate for inflation. A valve (not shown) may also be coupled to the inflation port 114 to selectively allow fluid to enter and exit the fluid chamber 113. These features may be particularly useful if the expandable support is an inflatable balloon.
The distal end 112 of the handle 110 may also include a distal port 115 aligned along a longitudinal axis 103 of the device 100. The distal port 115 may be in communication with the interior of the handle 110. The catheter assembly 120 may extend through the distal port 115, such that a proximal end of the catheter assembly 120 may be located on the interior of the handle 110, and a distal end of the catheter assembly 120 may be located exterior to the handle 110.
The interior of the handle 110 may also have a second chamber 109, as shown in
The handle 110 may include a seal 118 (e.g., an o-ring) around an opening in a distal end of the fluid chamber 113. The seal 118 may separate the fluid chamber 113 from the rest of the interior of the handle 110. The seal 118 may have a channel 119 that allows fluid to enter and exit the fluid chamber 113. The channel 119 in the seal 118 may be aligned along a longitudinal axis 103 of the device 100. The seal 118 may be substantially fixed relative to the handle 110. The handle 110 may further have proximal and/or distal seal retaining walls (similar to those shown in
The arteriotomy positioning device 100 may further include a core wire 150. The core wire 150 may be an elongate member having a proximal end 151 and a distal end 152. The core wire 150 is shown as being solid in all embodiments; however, any of the embodiments could alternatively use a core wire with one or more lumens.
The core wire 150, and preferably the proximal end 151 of the core wire 150, may be connected to the handle 110. Movement of the handle 110 may also move the core wire 150, at least when the device 100 is in the locating and tension states as described below. In the embodiment of
The arteriotomy positioning device 100 may further include a catheter 140. The catheter 140 may be an elongate tubular member having a proximal end 141 and a distal end 142. A lumen 145 may extend from the proximal end 141 to the distal end 142. Thus, the catheter 140 may have an outer surface 143 and an inner surface 144.
The arteriotomy positioning device 100 may further include a plunger 130. The plunger 130 may have a proximal end 131 and a distal end 132. The plunger 130 may have a lumen 135, which may extend from the proximal end 131 to the distal end 132. Thus, the plunger 130 may have an outer surface 133 and an inner surface 134.
The catheter 140 may be connected to the plunger 130 to form a catheter assembly 120. The position of the catheter 140 relative to the plunger 130 may be substantially fixed, such that the catheter 140 moves together with the plunger 130, i.e., the catheter 140 is moveable upon movement of the plunger 130. The catheter 140 may be inserted into the lumen 135 of the plunger 130, such that the outer surface 143 of the catheter 140 may be in contact with, and preferably connected to, the inner surface 134 of the plunger 130.
The catheter assembly 120 may have a lumen 125. The lumen 125 may be formed by one or more of the lumen 145 of the catheter 140 and the lumen 135 of the plunger 130. As shown in
The catheter assembly 120 may have a proximal end 121 and a distal end 122. Preferably, the distal end 142 of the catheter 140 forms the distal end 122 of the catheter assembly 120. The proximal end 141 of the catheter 140, the proximal end 131 of the plunger 130, or both may form the proximal end 121 of the catheter assembly 120.
In other embodiments, the plunger 130 and the catheter 140 may be formed as a single part. In still other embodiments, the plunger 130 and the catheter 140 may be separate parts connected to one another using an adhesive, interference fit, or any other appropriate attachment mechanism known in the art. In some embodiments, features described as being included on the plunger 130 (including, but not limited, to the tension stop 126, resting stop 127, and/or various features of the device status indicator 104 (to be discussed below) may alternatively be included on the catheter 140.
The catheter assembly 120 may extend along the longitudinal axis 103 of the device 100, and may be positioned partially inside the handle 110. The proximal end 121 of the catheter assembly 120 may be positioned inside the handle 110, and preferably inside the fluid chamber 113. The lumen 125 of the catheter assembly 120 may be in communication with the fluid chamber 113 and inflation port 114 of the handle 110. The core wire 150 may extend through the lumen 125 of the catheter assembly 120. The distal end 152 of the core wire 150 may be distal to the distal end 122 of the catheter assembly 120.
The catheter assembly 120 may slidably extend through one or both of the channel 119 in the seal 118 and the distal port 115 of the handle 110. The catheter assembly 120 may sealingly engage the seal 118 of the handle 110, such that fluid leaving the fluid chamber 113 through the channel 119 in the seal 118 will flow through the lumen 125 of the catheter assembly 120. If the plunger 130 extends through the seal 118, as shown in
The device 100 may include two sets of stops: a resting stop and a tension stop. As the catheter assembly 120 moves proximally relative to the handle 110 and core wire 150, a resting stop 127 on the catheter assembly 120 may contact a corresponding resting stop 117 of the handle 110, thereby preventing further proximal movement of the catheter assembly 120. As the handle 110 and core wire 150 move proximally relative to the catheter assembly 120, a tension stop 126 on the catheter assembly 120 may contact a corresponding tension stop 116 of the handle 110, thereby preventing further proximal movement of the handle 110 and core wire 150.
In the embodiment of
The tension and resting stops 126, 127 on the catheter assembly 120 may preferably be included in the plunger 130. The stops 126, 127 may be projections extending from the outer surface 133 of the plunger 130, as shown in
The catheter assembly 120 may be positioned such that the tension stop 126 and the resting stop 127 of the catheter assembly 120 are inside the handle 110, although their positions within the handle 110 depend on the configuration of the catheter assembly 120 and the handle 110. In the embodiment shown in
In the embodiment shown in
The catheter assembly 120 may be moveable relative to the handle 110 and the core wire 150. Preferably, the catheter assembly 120 is slidable relative to the handle 110 and the core wire 150 along a longitudinal axis 103 of the device 100. The catheter assembly 120 may be able to slide through one or both of the channel 119 in the seal 118 or the distal port 115 of the handle 110.
The arteriotomy positioning device 100 may further include an expandable support 160. The expandable support 160 may be a balloon, a group of splines, a combination thereof, or any expandable structure that can move between a low-profile configuration, a medium-profile configuration, and a high-profile configuration. The expandable support 160 may have a proximal bonding region 161 at its proximal end and a distal bonding region 162 at its distal end. The axial length (also referred to as the length) of the expandable support 160 may be the distance between the proximal bonding region 161 and the distal bonding region 162, as measured along the longitudinal axis 103 of the device 100. A width of the expandable support 160 may be measured substantially perpendicularly to the longitudinal axis 103 of the device 100, at the widest part of the expandable support 160. If the expandable support 160 is a balloon, the balloon may be provided in standard shapes and sizes, and may be made from conventional materials. If the expandable support is in the shape of a sphere or ellipsoid, the width would be the maximum diameter of the expandable support 160 in a direction substantially perpendicularly to the longitudinal axis 103 of the device 100. As will be described below, the length and the width of the expandable support 160 may change as the expandable support 160 is moved between the low-profile configuration, the medium-profile configuration, and the high-profile configuration.
The expandable support 160 may be connected to the catheter 140 and the core wire 150. The proximal bonding region 161 of the expandable support may be connected to the distal end 122 of the catheter assembly 120. More specifically, the proximal bonding region 161 of the expandable support 160 may be connected to the distal end 142 of the catheter 140. Therefore, the proximal bonding region 161 of the expandable support 160 may be substantially fixed relative to the catheter assembly 120, but may be moveable relative to the core wire 150 and handle 110. The distal bonding region 162 of the expandable support 160 may be connected to the distal end 152 of the core wire 150. Therefore, the distal bonding region 162 of the expandable support 160 may be substantially fixed relative to the core wire 150 and handle 110, but moveable relative to the catheter assembly 120. If the expandable support 160 is a balloon, the lumen 145 of the catheter 140 may communicate with the interior of the balloon. Therefore, the interior of the balloon may be in communication with the inflation port 114 via the lumen 125 of the catheter assembly 120 and the fluid chamber 113 of the handle 110.
The length of the expandable support 160 may change if the catheter assembly 120 is moved relative to the core wire 150, allowing the expandable support 160 to move between the low-profile configuration, the medium-profile configuration, and the high-profile configuration. In the low-profile configuration, the expandable support 160 may have a first length 164a and a first width 163a as shown in
For simplicity, the first width 163a, first length 164a, second width 163b, second length 164b, third width 163c1, 163c2, and 163c3, and third length 164c1, 164c2 and 164c3 are each referred to as a “width” or a “length”, but each width may encompass a range of widths and each length may encompass a range of lengths. For example,
The arteriotomy positioning device 100 may also include a spring 170. The spring 170 may apply a proximal force to the catheter assembly 120 to bias the catheter assembly 120 proximally relative to the handle 110 and the core wire 150, and similarly, to bias the handle 110 and the core wire 150 distally relative to the catheter assembly 120. The spring 170 may be positioned inside the handle 110, and may be outside the fluid chamber 113 (as shown in
The device 100 may be designed to prevent the user from unintentionally pulling the expandable support 160 through the blood vessel 001 when applying tension to the catheter assembly 120. The force required to compress the spring 170 and move the housing 110 and core wire 150 proximally relative to the catheter assembly 120 when applying tension to the catheter assembly 120 may preferably be less than the force required to pull the expandable support 160 through the blood vessel 001. The force required to pull the expandable support 160 through the blood vessel 001 may increase as the width 163 of the expandable support 160 increases. For example, the force to pull the expandable support 160 through the arteriotomy when the expandable support 160 is in the high-profile configuration may be higher than the force to pull the expandable support 160 through the arteriotomy when the expandable support is in the medium-profile configuration. Therefore, increasing the tension applied to the catheter assembly 120 may also increase the force required to pull the expandable support 160 through the blood vessel 001, allowing the user to apply an increasing amount of force without pulling the expandable support 160 through the vessel.
During use, the arteriotomy positioning device 100 may be moveable between at least three states: a resting state, a locating state, and a tension state.
When the arteriotomy positioning device 100 is in the resting state (see
The device may include a releasable resting lock to maintain the expandable support 160 in the resting state. When engaged, the resting lock may prevent the catheter assembly 120 from moving distally relative to the handle 110 and the core wire 150, thereby preventing the expandable support 160 from moving from the low-profile configuration to the medium-profile configuration or high-profile configuration. When the resting lock is disengaged, the catheter assembly 120 may be able to move distally relative to the handle 110 and the core wire 150, allowing the expandable support 160 to move from the low-profile configuration to the medium-profile configuration or high-profile configuration. The user may be able to selectively engage and disengage the resting lock.
If the expandable support 160 is a balloon, the resting lock may be a valve associated with the inflation port 114. The resting lock may be engaged by closing the valve, thereby preventing inflation fluid from entering the fluid chamber 113 through the inflation port 114. The resting lock may be disengaged by opening the valve, thereby allowing inflation fluid to enter the fluid chamber 113 through the inflation port.
When the arteriotomy positioning device 100 is in the locating state (see
The device may include a releasable locating lock to prevent the device 100 from unintentionally moving from the locating state (or the tension state) back to the resting state. When engaged, the locating lock may limit proximal movement of the catheter assembly 120 relative to the handle 110 and the core wire 150 such that the expandable support 160 can move between the medium-profile configuration and high-profile configuration, but it cannot move to the low-profile configuration. When the locating lock is disengaged, the expandable support 160 may be able to move between the medium-profile configuration (or the high-profile configuration) and the low-profile configuration. The user may be able to selectively engage and disengage the locating lock.
If the expandable support 160 is a balloon, the locating lock may be a valve (not shown) associated with the inflation port 114. The same valve may act as the resting lock and the locating lock. The locating lock may be engaged by closing the valve after inflation fluid has entered the fluid chamber 113, thereby preventing fluid from exiting the fluid chamber 113 through the inflation port 114. The locating lock may be disengaged by opening the valve, thereby allowing inflation fluid to exit the fluid chamber 113 through the inflation port 114.
When the arteriotomy positioning device 100 is in the tension state (see
When the arteriotomy positioning device 100 is in the tension state, the resting stop 127 of the catheter assembly 120 may be spaced from a resting stop 117 of the handle 110. The tension stop 126 of the catheter assembly is not necessarily in contact with the tension stop 116 on the handle 110. However, increasing the tension on the catheter assembly 120 to an undesirably high level may cause the tension stop 126 to contact a tension stop 116 of the handle 110, preventing further proximal movement of the core wire 150 and handle 110 relative to the catheter assembly 120, which limits the amount of tension on the catheter assembly 120. The spring 170 may be more compressed in the tension state compared to the resting and locating states. Therefore, the spring 170 may still resist proximal movement of the handle 110 and the core wire 150 relative to the catheter assembly 120, even if the tension stops 126, 116 on the catheter assembly and handle 110 are not in contact.
The arteriotomy positioning device 100 may include a device status indicator 104 which visually indicates both the status of the device 100 (i.e., whether the device is in the resting state, locating state, or tension state) and the amount of tension, if any, being applied to the catheter assembly 120. The device status indicator 104 may allow the user to compare a feature on the catheter assembly 120 to a feature on the handle 110 to determine the longitudinal position of the catheter assembly 120 relative to the core wire 150.
The device status indicator 104 may include an indicator feature 105 on one component that moves relative to a series of markings 106 (including but not limited to lines, colored bands, raised or lowered features, etc.) on another component. The device status indicator 104 may include a series of markings 106 on the handle 110 and an indicator feature 105 on the catheter assembly 120. For example, the indicator feature 105 may be a protrusion on the plunger 130, and the markings 106 may be on the handle 110 as shown in
The device status indicator 104 may include the following markings 106: 1) a marking 106a indicating that the device 100 is in the resting state, the expandable support 160 is in a low-profile configuration, and the catheter assembly 120 is not under tension, 2) a marking 106b indicating that the device 100 is in the locating state and the expandable support 160 is in a medium-profile configuration, and the catheter assembly 120 is not under tension, and 3) one or more markings 106c1, 106c2, 106c3 indicating that the device 100 is in the tension state, the expandable support 160 is in a high-profile configuration, and the catheter assembly 120 is under tension. Marking 106c1 may indicate that the catheter assembly 120 is under tension with too little force, marking 106c2 may indicate that the catheter assembly 120 is under tension with appropriate force, and marking 106c3 may indicate that the catheter assembly 120 is under tension with too much force. If the markings 106 are included on the catheter assembly 120, marking 106a may preferably be the distal-most marking, followed in order by marking 106b, then marking 106c1, then marking 106c2, and finally, marking 106c3, which may be the proximal-most marking. If the markings are included on the handle 110, marking 106a may preferably be the proximal-most marking, followed in order by marking 106b, then marking 106c1, then marking 106c2, and finally, marking 106c3, which may be the distal-most marking. However, the reverse order may also be used, or the markings may be arranged in a different order depending on the configuration of the device 100 and the device status indicator 104. One or more of markings 106a, 106b, 106c1, 106c2, and 106c3 may be omitted, or additional markings may be included.
The following exemplary method (described in detail in the following paragraphs) may be used when locating an arteriotomy and performing a procedure. The method may include steps of inserting the expandable support through the arteriotomy and into the vessel, moving the device to the locating state, withdrawing the handle proximally until the expandable support contacts the arteriotomy, continuing to withdraw the handle proximally to apply tension to the catheter assembly and move the device to the tension state, performing a procedure, returning the device to its resting state, and withdrawing the device from the patient. It is understood that one or more of these steps may be omitted and other steps may be included in this method.
First, the user may insert the device 100 into the patient, thereby inserting the expandable support into the vessel 001 through the arteriotomy 002, as illustrated in
When the expandable support 160 is positioned inside the vessel, the user may move the arteriotomy positioning device 100 from the resting state to the locating state. The expandable support 160 may move from the low-profile configuration to the medium-profile configuration, while the catheter assembly 120 may move distally relative to the handle 110 and the core wire 150. The width 163 of the expandable support 160 may increase from the resting width 163a to the locating width 163b. The locating width 163b may be larger than the width of the arteriotomy 002 to prevent the expandable support from being pulled through the arteriotomy 002 while the device is in the locating state. The length 164 of the expandable support 160 may decrease from the resting length 164a to the locating length 164b. The distal resting stop 127 of the catheter assembly 120 may move away from the resting stop 117 of the handle 110, such that they are no longer in contact. The spring 170 may still resist distal movement of the catheter assembly 120 relative to the handle 110 and the core wire 150. The spring 170 may compress when the device 100 is moved from the resting state to the locating state. The device status indicator 104 may move from a position indicating that the device 100 is in the resting state to a position indicating that the device 100 is in the locating state. Once the device 100 reaches the locating state, a locating lock may be engaged to prevent the device 100 from unintentionally reverting to the resting state during use.
If the expandable support 160 is a balloon, the step of moving the arteriotomy positioning device 100 from the resting state to the locating state may involve inflating the balloon. The device 100 may be moved from the resting state to the locating state by pushing the inflation fluid through the inflation port 114, into the fluid chamber 113 of the handle 110, through the lumen 125 of the catheter assembly 120, and into the interior of the balloon. Once the device 100 reaches the locating state, a valve (not shown) associated with the inflation port 114 may be closed to prevent the inflation fluid from flowing out of the fluid chamber 113 through the inflation port 114.
When the arteriotomy positioning device 100 is in the locating state, the user may withdraw the handle 110 proximally to move the expandable support 160 closer to the arteriotomy 002, as shown by the arrow in
When the expandable support 160 contacts the arteriotomy 002, the user may continue withdrawing the handle 110 proximally (as shown by the arrows in
If the expandable support 160 is a balloon, the balloon may remain inflated as the arteriotomy positioning device 100 is moved between the locating state and the tension state. Although shape of the balloon may change as the device 100 is moved between the locating state and the tension state, the amount of inflation fluid in the device may remain substantially constant. Therefore, a valve associated with the inflation port may remain closed as the device is moved between the locating state and the tension state.
When the device status indicator 104 shows that an appropriate amount of tension is being applied to the catheter assembly 120, the user can perform the intended procedure (e.g., applying a sealant or other closure device, in the case of a vascular closure procedure). The proximal force applied to the handle 110 and/or core wire 150 may be maintained throughout at least a portion of the procedure, such that the device status indicator 104 continues to show that an appropriate amount of tension is being applied to the catheter assembly 120.
After completion of the procedure, the user may return the arteriotomy positioning device 100 to its resting state. The proximal force applied to the handle 110 may be decreased, thereby releasing the tension on the catheter 140, allowing the catheter assembly 120 to move proximally relative to the handle 110 and the core wire 150, and returning the device to the locating state. A locating lock may be disengaged, and the catheter assembly 120 may be moved further proximally relative to the handle 110 and the core wire 150 to return the device 100 to its resting state. If the expandable support 160 is a balloon, the locating lock may be disengaged by opening a valve associated with the inflation port 114, which allows inflation fluid to exit the fluid chamber 113 through the inflation port 114 on the handle 110, causing the balloon to deflate and the device 100 to return to its resting state.
When the arteriotomy positioning device 100 has been returned to its resting state, the expandable support 160 may have the resting width 163a smaller than the width of the arteriotomy 002. Therefore, the expandable support may fit through the arteriotomy 002 and the device 100 may be removed from the patient. A proximal force may be applied to the handle 110, and the entire arteriotomy positioning device 100 may be withdrawn from the patient.
Various other components may be provided within the arteriotomy positioning device 100. In addition, the arteriotomy positioning device 100 may also be incorporated into other devices used in procedures that require access to a patient's vasculature. For example, the arteriotomy positioning device 100 may be incorporated into a vascular closure device. The vascular closure device may further incorporate features including a sealant, a pusher member, a protective sleeve, and various other components. The sealant may be positioned near the distal end of the catheter assembly, proximal to the expandable member. The pusher member may be positioned proximal to the sealant to prevent proximal movement of the sealant and/or tamp the sealant. The sealant and pusher member may be provided inside a protective sleeve, which may be withdrawn to deploy the sealant. Incorporating the arteriotomy positioning devices discussed above into a vascular closure device may help ensure that the sealant is positioned correctly (outside the blood vessel, but near the arteriotomy) before the user deploys and/or tamps the sealant. The device may further include additional components, actuators, and/or safety mechanisms for controlling the device while exposing the sealant, tamping the sealant, withdrawing the cartridge assembly and expandable support relative to the sealant and/or the protective sleeve.
A number of alternative embodiments of arteriotomy positioning devices are envisioned, including those shown in
Another unique feature of
The device may be modified if the expandable support is not an inflatable balloon. For example, the inflation port, fluid chamber, valve, and seal in the handle may be omitted. The device may be moved from the resting state to the locating state by moving the catheter assembly distally relative to the core wire (or by moving the core wire proximally relative to the catheter assembly), which can be accomplished manually or with an actuator or control mechanism in the handle. In either case, the device should still be able to move freely between the locating state and the tension state, regardless of how the device is moved from the resting state to the locating state. The device may have one or more locking features to maintain the position of the catheter assembly. For example, a resting lock may prevent distal movement of the catheter assembly relative to the handle and the core wire when the device is in a resting state. Once the device is moved to the locating state, a locating lock may limit proximal movement of the catheter assembly relative to the handle and the core wire, while still allowing the device to move between the locating state and the tension state.
In the embodiment depicted in
The expandable support 1260 may be connected to a catheter, such as catheter 140 for example, and a core wire, such as the core wire 150 for example.
The length of the expandable support 1260 may change if a catheter assembly is moved relative to a core wire, allowing the expandable support 1260 to move between the low-profile configuration, the medium-profile configuration, and the high-profile configuration. Generally, the length may decrease and the width may increase as the expandable support 1260 moves from the low-profile configuration to the medium-profile configuration to the high-profile configuration.
In operation, once a user has inserted the device into a patient's artery, the user can unlock the lock 1320 on the plunger 1310, allowing for movement of the plunger 1310 to the position shown in
As shown in
As used herein, the relative terms “proximal” and “distal” shall be defined from the perspective of the arteriotomy positioning devices. Thus, proximal refers to the direction of the handle and distal refers to the direction of the expandable member.
For purposes of this disclosure, certain aspects, advantages, and novel features are described herein. It is to be understood that not necessarily all such advantages may be achieved in accordance with any particular embodiment. Thus, for example, those skilled in the art will recognize that the disclosure may be embodied or carried out in a manner that achieves one advantage or a group of advantages as taught herein without necessarily achieving other advantages as may be taught or suggested herein. The foregoing description is provided to enable any person skilled in the art to practice the various example implementations described herein. Various modifications to these variations will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other implementations. All structural and functional equivalents to the elements of the various illustrious examples described throughout this disclosure that are known or later come to be known to those of ordinary skill in the art are expressly incorporated herein by reference.
This application claims the benefit of U.S. Provisional Patent Application No. 62/558,462, filed Sep. 14, 2017, which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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62558462 | Sep 2017 | US |