DEVICE AND METHOD FOR SEALING A PUNCTURE IN A BLOOD VESSEL
FIELD OF THE INVENTION
The present invention is generally in the field of homeostatic devices and in particular it is directed to a sealing device and a method utilizing same for sealing punctures in any blood vessel of a patient during or after a medical procedure.
BACKGROUND OF THE INVENTION
During several surgical procedures carried out, for example in treatment of vascular diseases, it is common practice to invade a blood vessel and introduce a treating or diagnostic device, e.g. balloons or various types of stents to operate on walls of the arteries, plaque removing devices, observation and flow diagnostic instruments, etc.
During such procedures, a blood vessel is punctured so as to allow introduction of the instrument through the artery and then maneuver it to the required site of operation. This is carried out in practice by introducing a guide tube often referred to as an "Introducer sheath", through which the instrument can then be easily maneuvered to the site of interest.
A problem occurs once the procedure is complete and the guide tube has then to be removed, when the percutaneous puncture bleeds. Bleeding may result in hematoma or in severe cases to malfunction of critical organs and even death. Such bleeding is stopped, by a most common method, by simply applying pressure on to the puncture site by a medically trained person for a sufficiently long period of time until homeostasis takes place to spontaneously seal the puncture and stop the bleeding.
In cases of puncturing the femoral arteries, the required time may be as long as about 45 minutes or more and in some cases re-bleeding occurs if the patient is not in rest.
A variety of methods and devices have been suggested for replacing the traditional method disclosed above, some of which involve introducing chemical compounds which act as homeostasis catalysts or as adhering agents, whilst others aim at introducing various forms of plugging members into the puncture. The following is a list of prior art patents disclosing devices and methods for sealing punctured blood vessels: U.S. 4,705,040 4,890,612, 4,929,246, 5,108,420, 5,342,393, 5,350,399, 5,391,183, 5,613,974, 5,810,884, 5,861,003, 5,957,952, 5,984,950, 6,007,563 and WO 98/31287.
It is an object of the present invention to provide a series of novel devices for sealing a puncture or incision formed in a blood vessel or in other body organs.
SUMMARY OF THE INVENTION It is an object of the present invention to provide a sealing device and a method utilizing same, for sealing a puncture or incision formed in a body organ, typically in a blood vessel. A device in accordance with the present invention has the unique advantage of being introduced into the puncture over a guide tube (sheath) and is self adaptable for use in a wide range of sizes of guide tubes. The device is fitted with anchoring means to ensure suitable anchorage within the puncture and is self adapted for a variety of wall thicknesses of the blood vessel at the puncture site.
An advantage of a device according to the present invention is that once it is introduced into the puncture or incision it can be rapidly deployed into its operative sealing position.
According to the present invention there is provided a sealing device for sealing a puncture in a blood vessel, said device being slidingly receivable over a guide tube and comprising a sealing portion, a wall-engaging portion extending between an external bearing member for bearing over an external surface of the
blood vessel, and an internal bearing member for bearing against an inner surface of the blood vessel, where at least said internal bearing member is manipulable between a constricted position in which it is essentially coextensive with the wall-engaging portion and an expanded position in which it engages the inner surface of the blood vessel.
The device according to the present invention may assume many variations as will be disclosed hereinafter, all of which comprises a common principle component element namely, a manipulable internal bearing member and which are deployed into their operative, expanded position over the guide tube. The internal bearing member is expanded into its anchoring position within the vessel by means of a manipulating member which is in the form of a manipulating sleeve slidable over the guide tube or by deformation of a collapsing member, e.g. by pulling.
According to some embodiments of the invention, the internal bearing member spontaneously displaces into its anchoring state upon removal of the guide tube wherein the sealing portion spontaneously seals.
However, according to another aspect of the present invention there is provided a sealing device for sealing a puncture in a blood vessel, said device being slidingly receivable over a guide tube and comprising a sealing portion, a wall- engaging portion extending between an external bearing member for bearing over an external surface of the blood vessel, and an internal bearing member for bearing against an inner surface of the blood vessel, where said internal bearing member is a rib extending along a helical path. A device according to this aspect differs from devices according to the previous aspect in that the internal bearing member is fixed rather than being manipulable. By a further aspect of the invention, there is provided a method for sealing a puncture in a blood vessel, the method comprising the following steps:
(a) obtaining a sealing assembly comprising a sealing device slidable over a guide tube and being axially displaceable over the guide tube by a manipulating member; said sealing device having a sealing body portion and a wall-engaging portion extending between an external bearing
member for bearing over an external surface of the blood vessel, and an internal bearing member for bearing against an inner surface of the blood vessel; (b) mounting the sealing assembly over the guide tube; (c) introducing the sealing assembly into the puncture site;
(d) displacing the sealing device over the guide tube by the manipulating member so as to introduce the wall-engaging portion through the puncture of the blood vessel;
(e) deploying the sealing device into a position in which the internal bearing member bears against an inner surface of the blood vessel; and
(f) removing the guide tube and allowing a sealing member of the device to assume a sealing position.
BRIEF DESCRIPTION OF THE DRAWINGS
For better understanding the invention and to see how it may be carried out in practice, reference is now being made to the accompanying drawings illustrating several embodiments in accordance with the present invention, in which:
Figs. 1A-1E are top isometric, bottom isometric, bottom, side and sectional views of a device in accordance with a first embodiment of the present invention, in an expanded position, removed from the guiding tube; Figs. 2A and 2B illustrate a perspective and a bottom view of the device seen in Figs. 1, in a retracted position mounted on a guide tube;
Figs. 3A and 3B illustrate a sealing device in accordance with a second aspect of the invention in a deploying state and in operative, sealing state, respectively; Fig. 4A is an isometric view of a sealing device in accordance with another embodiment of the present invention, mounted over a guide tube, in its constricted position;
Fig. 4B illustrates the device of Fig. 4 A in a partially expanded position;
Fig. 4C illustrates the device of Figs. 4A and 4B in a sealing state engaged with a blood vessel in a sealing state;
Fig. 5A is a perspective view of a sealing device in accordance with still another embodiment of the present invention, the device illustrated in its constricted position;
Figs. 5B-5G are different views of a wall engaging portion and an internal bearing member of the device seen in Fig. 5A, in constricted and expanded positions;
Fig. 6A is an isometric view of device according to the present invention fitted with a wall engaging portion and an internal bearing member in accordance with a further embodiment, in a constricted position, mounted over a guide tube; and
Fig. 6B illustrates the device of Fig. 6 A in its expanded, operative position.
DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS Attention is first directed to Figs. 1 and 2 of the drawings illustrating a first embodiment of a sealing device in accordance with the present invention generally designated 20. The device has a generally tubular shape and has a fore end 22 and a distal end 24. An intermediate, wall-engaging portion 26 is essentially cylindrical and has an inner diameter slidable over a guide tube (introducer sheath) 30 seen in Figs. 2A and 2B of the type which is used in different medical procedures.
Fixedly attached to the wall-engaging portion 26 there is a housing 32 accommodating a resilient membrane 34 pre-slotted to allow accommodation of the guide tube 30 as in Figs. 2A and 2B. Membrane 34 is normally closed, i.e. when not receiving a guide tube through the opening, it assumes a sealed state. A support ring 36 (Figs. 1A and IE) is provided adjacent the fore end 22 of the device, formed with an aperture coaxial with the central cavity of the device extending through the wall-engaging portion 26.
In the present example wall-engaging portion 26 is formed of a metallic material such as, for example, Nitinol or so-called medical type stainless steel,
whereas the housing 32 is composed of various elastomeric and plastic materials. However, a person versed in the art will appreciate that other combinations are possible. For example, the device may be partially or entirely made of bio-degradable (bio-absorbable) materials. An annular shoulder 38 of housing 32 constitutes an external bearing surface which in use bears against an external surface 41 of the blood vessel as schematically illustrated in Fig. ID.
Integrally formed with the wall-engaging portion 26 there is a pair of internal bearing arms 42 in the form of springy arcuate arms, each having one free end. The arrangement is such that the two arms are axially staggered whereby when they are retracted so as to coincide with the outer diameter of wall-engaging portion 26 they do not interfere with one another. The arrangement is further such that in their retracted position (Figs. 2A and 2B) they each extend over a circular portion larger than 180°C whereby when the guide tube 30 extends through the device 20 each arm embraces a portion of the tube 30 and is prevented from spontaneously displacing into the expanded position of Figs. 1A-1E, unless the tube is withdrawn.
An upper surface 46 of each of the internal bearing members 42 is adapted for bearing against an inner wall 48 of the blood vessel as illustrated in Fig. ID. Deployment of the device 20 into sealing engagement within a puncture formed in a blood vessel is carried out by introducing the guide tube 30 through the puncture (it is presumed that many medical procedures require the use of the guide tube and thus, the guide tube is already in position). In this case, the sealing device 20 is slidably displaced along the guide tube 30 towards the blood vessel and with the aid of a manipulating member in the form of tube 50 (Fig. 2A), which has a diameter larger than the diameter of the aperture formed in support ring 36, and upon sliding the manipulating member 50 in direction of arrow 52 it entails displacement of the device 20 into the aperture at the blood vessel. Then, upon withdrawal of the guide tube 30 the internal bearing members 42 deform into their
wall-engaging position and the sealing diaphragm 34 spontaneously seals as the tube is withdrawn.
Further attention is now directed to Figs. 3A and 3B illustrating a device in accordance with a second aspect of the present invention. The device generally designated 60 has a generally tubular shape and comprises a fore end 62 with an opening 64 fitted for slidably receiving a guide tube 66. Fitted adjacent the fore end 62 there is a sealing member 68, similar to the arrangement disclosed in connection with the previous embodiment of Figs. 1 and 2.
The housing 70 of the device is formed with a neck portion 72 constituting an external bearing member for anchoring against an outer wall 74 of the blood vessel. An essentially cylindric portion 76 constitutes a wall-engaging portion which in the operative position of Fig. 3B occupies the puncture of the blood vessel. A bottom end of the device is formed with a rib 80 extending along a helical path, with an upper coil 82 of which constitutes an internal bearing member which in use bear against an internal wall 75 of the blood vessel, as seen in Fig. 3B.
The device 60 is deployed into its operative position over the guide tube 66 (Fig. 3A) and upon encountering the outer surface 74 of the blood vessel it is further inserted in a screw-type motion until the external bearing member 72 bears against the outer surface 74 of the blood vessel, entailing rib 82 to bear against inner wall 75, anchoring the device in place. At this situation the guide tube 66 may be removed, allowing the diaphragm 68 to spontaneously deform into its sealed position as in Fig. 3B.
Figs. 4A-4C illustrate a sealing device 90 in accordance with still another embodiment of the present invention. The device is generally formed of a mesh of pre-stressed material, e.g. woven metal mesh or woven plastic material and has a fore end 92 and a bottom end 94, pre-stressed to rotate in opposed directions illustrated by arrows 96 and 98 in Fig. 4B, thereby urging the device to rotate about a longitudinal axis thereof and displace into a collapsed state wherein the diameter of the device increases at its respective ends but shrinks to seal the internal bore thereof at a central portion. This arrangement is at times referred to as an "Iris
valve". Whilst the device may be made of a tight mesh material, it may be coated with a suitable material or embedded there within. The device may also be made of woven material with or without elastomeric coating.
The device 90 is initially mounted over a guide tube 96 as shown in Fig. 4A. In this position the device retains an essentially cylindric position. However, upon withdrawal of the guide tube 96 the device 90 tends to spontaneously deform into the position of Fig. 4C, owing to its pre-stressed structure. In this position there is formed an external bearing surface 98 and an internal bearing surface 100 (corresponding with ends 92 and 94 of the device), as illustrated in Fig. 4C, with an intermediate central portion 102 wound about itself and serving as a sealing member and as a wall-engaging portion. In this position the external bearing member 98 bears against outer wall surface 106 of the blood vessel with internal bearing member 100 bearing against inner wall surface 108 of the blood vessel, thus anchoring the device in place within the puncture 110. It will be appreciated that in addition to the above disclosed arrangement, there may be provided a resilient sealing member, e.g. of the type disclosed in the previous embodiments.
Attention is now directed to Figs. 5A-5G illustrating a further device in accordance with the present invention generally designated 120, seen in a general perspective view in Fig. 5A. The device comprises a housing 122 which is principally similar to the housing 32 in the first embodiment illustrated in Figs. 1 and 2. Housing 122 comprises a support ring 124, a pre-slotted diaphragm-like sealing member 126 and an annular shoulder 128 constituting an external bearing surface. Fitted to housing 122 there is a wall-engaging portion 130 which is separately illustrated in Figs. 5B-5G. As explained in connection with the first embodiment, the internal diameter of the wall-engaging portion 130 is designed for sliding over a guide tube (not shown).
Formed at a bottom end of wall-engaging portion 130 there are two internal bearing members 134 each formed of a pre-stressed wire having at least three parallel looped portions 136, 138 and 140 (most clearly illustrated in the side view
of Fig. 5C). Each of the bearing members 134 has two leg portions 142 fixed to or integral with the wall-engaging portion 130. The arrangement is such that at the constricted position (Figs. 5A-5C) the looped portions 136, 138 and 140 extend essentially parallel to a longitudinal axis of the device and thus the device is readily slidable over the guide tube (not shown). However, upon withdrawal of the guide tube, the internal bearing members 134 spontaneously snap into their expanded position as in Figs. 5D-5F, with the longer looped portions 138 laterally projecting outwardly. In the expanded position the long looped portions 138 bear against the inner surface of the blood vessel (not shown). As can be seen in particular in Fig. 5E, at the expanded position the looped portions 138 are upwardly inclined so as to improve anchoring within the vessel.
Deploying the device 120 into its operative position is done as in the description referring to the first embodiment whereupon displacement of the device over the guide tube (not shown) into the puncture of the blood vessel and then withdrawal of the guide tube entails spontaneous expansion of the internal bearing member and sealing of the seal member 126.
Figs. 6A and 6B illustrate still a further embodiment of the present invention generally designated 150 which in Fig. 6A is illustrated in its retracted position and in Fig. 6B in its expanded, operative position. The sealing portion generally designated 152 is similar to that disclosed in connection with the previous embodiments and the rear is directed to the relevant passages hereinabove. An annular shoulder 154 of the sealing portion 152 constitutes the external bearing surface.
Fitted to the housing of sealing member 152 there is a wall engaging portion 158 which is tubular portion adapted for fit sliding over an introducing sheath 160 (seen only in Fig. 6A). The tubular member 158 is formed with a plurality of axial slots 164 wherein between two consecutive slots 164 there is a deformable internal wall fixing members 170, each formed with an integral radial fold-line 174.
A pair of deploying cords 178 extend through the tubular member 158 and are attached at 180 to a lowermost portion 182 of the tubular member 158.
The arrangement is such that at an initial state the internal engaging members 170 are coaxial with other portions of the tubular member 158 and upon pulling cords 178 in the axle direction illustrated by arrows 186, the internal engaging member collapses outwardly as illustrated in Fig. 6B, thereby constituting the internal anchor for bearing against an internal surface of the blood vessel.
Whilst some embodiments have been described and illustrated with reference to some drawings, the artisan will appreciate that many variations are possible which do not depart from the general scope of the invention, mutatis, mutandis. For example, different materials may be used for obtaining different mechanical properties of different components of the device, e.g. pre-stressing, durability, etc. Furthermore, at least portions of the devices may be coated or made of anti-coagulant material as known per se.