DE19846630C2 - Aortic umbrella catheter - Google Patents

Description

The present invention relates to a percutaneously insertable renal aortic umbrella catheter.

For cardiac surgery with an extracorporeal circus lation (EKZ) enables the EKZ the vital perfusion sion of the body during the operation Cardiac arrest.

Since the beginning of cardiac surgery, neurological disorders have been associated after operations with the heart-lung machine severe peri- and postoperative complications. Next Through syndromes come to peripheral and central neurological failures, such as temporary paralysis, visual disturbances to paraplegia as well as pronounced Apoplex (stroke) with coma due to irreversible brain damage. The main cause is serious neurological Disorders today are mainly micro and macro embolisms due to detached wall parts of the aorta or calcified  Heart valves blamed. Especially for those Surgery to cannulate a calcified aorta and their manipulation, e.g. B. disconnect, disconnect, punch from wall parts to bypass supply are essential Pathomechanisms in the foreground. As in the relevant Literature described, especially show older patients increased, sometimes considerable arteriosclerotic changes in the area of the aortic wall. The share of over 70 Year-old patients are steadily increasing in cardiac surgery and is now more than 30% in many cases. The hee ability of neurological complications after cardiac surgery is given in the literature between 2 and 11%. It would be therefore desirable such neurological complication to prevent them.

From DE-A-40 30 998 is one of at least one under Preload compressible radially and by advancing Percutaneously implantable vascular filter in a catheter, especially known cava filter. Such cava filters who implanted through a catheter remain in the cava and are said to be a partial mechanical blockade of the hollow reach the vein and thereby contain the blood stream Effectively prevent embolism to the lungs. The vessel filter according to DE-A-40 30 998 consists of biodegradable mate rial, the Im remote from the vessel wall in the implanted state plantate parts are more quickly degradable than those close to the vessel wall Implant parts.

DE-A-195 15 933 describes an aortic device Occlusion while maintaining perfusion during the extracor poral circulation of cardiac surgery to avoid known risky cross aortic disconnection. The device has an insertable into a catheter Occlusion cannula, the lumens of which are distal to the end dilatable balloon is connected. The Occlusionska nüle is connected to an insufflation catheter. The Ascending aorta is cannulated through an aortic catheter  and the distal end of the occlusion cannula is in the balloon's deflated condition, whereupon the Balloon positioned accordingly by the insufflation di is latated. After cardiac surgery is completed The balloon becomes attached to the heart that is at a standstill desuffled, and the beginning weakened heart The extracorporeal circulation via Ballonocclusion perfusion cannula temporarily until errei sufficient cardiac output.

EP-A-0 165 713 relates to a collapsible filter basket which is arranged in a A patient's blood vessel can be inserted.

EP-A-0 815 803 discloses a catheter with a temporary vein cava filter previously known.

US-A-5,662,671 describes an arterial catheter system for removal of Deposits from the aorta and other arteries. This system points typically an elongated catheter element, one at the distal end portion of the Catheter provided filter device and an arterectomy device, which is a mechanism for catching and holding moving Deposits and a removal mechanism to remove the Has deposits. The filter device is typically in the form of a network formed around the circumference of the distal end portion of the catheter extends. A first end section of the network is at the outer Catheter surface attached while the second end portion on one expandable mechanism mounted between one contracted and an expanded state is expandable.

The invention has for its object an improved to provide aortic catheters, which in particular should be designed so that the neurological compli cations blamed micro and macro embolism can be safely avoided.

This task is accomplished with the Features of the claims solved.

The invention is based on the basic idea of one Device for protecting the blood flow path and nachge switched organs such. B. brain, before detached tissue particles in cardiac surgery with extracorpora ler circulation (EKZ). Detached tissue par Articles in the sense of the invention are in particular atheromatous Plaques, heart valve lime. The invention Device serves as a filter that extends across the cross section the aorta extends and the detached tissue particles catches, the captured particles then together can be removed from the aorta with the filter.

The device according to the invention can be inserted percutaneously rer catheter, which has a peripheral artery (Arteria femo ralis, brachial artery) with the help of a sluice up to the aorta ascentes proximal to the brachiocephalic trunk advanced and there by an expandable sealing element can be positioned. This is preferably a seal ment a ring balloon, which by means of a through the catheter men supplyable fluids such. B. sodium chloride solution or  a gas that can be expanded and attached to the inner wall the aorta is tight. The sealing element can also be mecha niche, e.g. B. by suitable spring means or by using suitable memory materials. The Sealing element is preferably made of an elastic or ex pandable material formed, preferably made of plastic. A filter or membrane is provided on the sealing element, which extends over the cross section of the vessel and as Collection filter for detached tissue parts works. Before preferably the filter is bag-like or conical connected to the catheter. At the end of the operation, the seal becomes tight relaxed or contracted such that the bags formed by the filter essentially closes and trapped particles, after which the catheter together with these particles can be removed.

A procedure similar to that of commercially available catheters The inner guide wire can be used for the applica facilitate the catheter.

The present invention is based on a preferred embodiment described by way of example. In the Drawings show:

FIG. 1 shows a catheter according to the invention in the aorta of a patient;

Fig. 2 was the catheter according to the invention in the expanded to; and

Fig. 3 shows the catheter according to the invention in a relaxed state with particles trapped and trapped by the filter.

The theter in FIGS. 1 to 3 according to the invention shown Ka 2 is a flexible plastic catheter with a Lu men 4 and provided at the distal end, chen in wesentli annular sealing element 6. The outer diameter of the flexible plastic catheter is approximately between 0.5 mm and 5 mm. The annular sealing element 6 is an elastic or expandable ring balloon which is connected to the lumen 4 via an opening 8 . By means of a proximal opening 10 , the dilatable ring balloon 6 is filled by filling (insufflation) with a fluid, preferably a liquid such as e.g. B. sodium chloride solution, in the expanded state shown in FIGS . 1 and 2 can be brought. For this purpose, the catheter 2 is advanced via a percutaneous puncture 12 or after the surgical exposure of a peripheral artery 14 with the aid of a lock in the desufflated state through the aorta descendes 15 and the aortic arch up to the aorta ascendes 16 and immediately proximal to the exit of the brachiocephalic trunk fixed by unfolding the ring balloon 6 . This usually takes place before the aortic clamp 17 and in particular before the aortic cannula 19 is inserted. The insufflation of the ring balloon 6 it follows by means of a fluid source 20 which communicates with the ring balloon 6 via the lumen 4 . In order to avoid a potential air embolism in the event of accidental rupture of the balloon 6 , expansion by liquid is safer. A guide wire (not shown) located in the lumen 4 can stabilize the catheter 2 and facilitate advancement. The exact positioning of the catheter 2 or the ring ball 6 can be checked, for example, by direct sonography (ultrasound). Electromagnetic location with appropriate probe marking or direct application using ferromagnetic and magnetic materials is also possible.

The elastic sealing element or the ring balloon 6 is preferably made of a highly elastic plastic, such as. B. latex is formed, which at the same time has sufficient plasticity to compensate for arteriosclerotic irregularities in the aortic inner wall. The size of the ring balloon 6 depends on the diameter of the ascending aorta 16 and can be determined both preoperatively by echocardiography and intraoperatively by direct measurement. For example, at least four different sizes of the ring balloon with an outer diameter of 20 mm, 30 mm, 40 mm and 50 mm should be available. The width or diameter b of the ring should be as small as possible in order to keep the resistance to the blood flow low. Before preferably the width b of the ring is between 2 mm and 5 mm. The ring shape of the balloon 6 can be realized by easily see on the inside and the outside of the ring under different expansion properties of the plastic. A harder, e.g. B. thicker material on the inside compared to the outside leads to a pre-partial application of the ring balloon 6 to the inner aortic wall, the cross section of the ring may be somewhat oval, which on the one hand increases the sealing surface on the inner wall of the vessel and on the other hand narrows the Vessel diameter is minimized by the ring balloon. This leads to an additional reduction in the resistance to the blood flow and a reduction in the so-called dead space (space between the ring and the inner wall of the aorta) in which limescale particles could also be deposited that would not be trapped.

In order to continuously measure the occlusion pressure required to stabilize and seal the ring balloon 6 , a manometer 22 may preferably be connected to the lumen 4 . If the pressure drops, the balloon can be refilled at any time.

A filter or membrane 26 is provided circularly on an outer edge 24 of the ring balloon 6 . An inner section 28 of the filter 26 is connected to the shaft of the plastic catheter 2 at an axial distance from the ring balloon 6 . Preferably, the axial distance between the ring balloon 6 and the attachment of the filter 26 on the plastic catheter is 15 mm to 50 mm, more preferably 20 mm to 30 mm. After expansion of the ring balloon 6 , the filter or membrane 26 unfolds into a bag-like or conical or zelt-shaped collecting device that can catch potential lime particles before they enter the bloodstream and z. B. penetrate into the head-arm vessels 21 . The membrane 26 is preferably made of a plastic material, such as. B. poly ester with a net-shaped arrangement, the pore size of about 50 microns to 300 microns, preferably 100 microns to 200 microns is sufficient. The pressure drop across this filter is minimal. With a cardiac output of z. B. 5 l / min, the pressure drop across a line filter of 20 µm to 40 µm pore size is only 665 to 1330 Pa (5 to 10 mmHg).

At the end of the operation, the ring balloon is desuffliert, so that the bag formed by the filter 26 is closed and the trapped by the filter 26 (lime) particles 30 are trapped therein around the Kathe ter 2 , and remain included when removing the catheter. The frequency of neurological complications after heart surgery can thus be significantly reduced.

In addition to the embodiment of the tele element 6 described above in the form of an expandable ring balloon, the sealing element can also be stretchable in other ways known per se. For example, it is possible to provide spring elements that are pressed together by a sleeve when the catheter is inserted and removed, and spread a sealing ring when the sleeve is removed. Likewise, it is also possible to see an annular spring on the annular sealing element, which, for. B. is contractible with a wire. Furthermore, it is also possible to use so-called memory materials, which can have different shapes or dimensions at different temperatures and which, for. B. expand in the heated state and seal against the inner wall of the aorta, but contract in the cooled state and can be moved in the aorta.

Claims (14)

1. Aortal umbrella catheter ( 2 ) with a proximal and a distal end, an expandable ring balloon ( 6 ) arranged at the distal end for placement against an inner wall of the vessel and a filter ( 26 ) which can be extended over the cross section of the vessel, an outer section ( 24 ) the filter ( 26 ) is attached to the ring balloon ( 6 ) and an inner section ( 28 ) of the filter ( 26 ) is axially spaced on the catheter shaft, so that the filter ( 26 ) is stretched like a bag when the ring balloon ( 6 ) is expanded, and wherein the ring balloon ( 6 ) has different expansion properties on its inside and on its outside. 2. Catheter according to claim 1 with a between the distal and the proximal end of the catheter ( 2 ) extending lumen ( 4 ) which is in communication with the interior of the sealing element ( 6 ). 3. Catheter ( 2 ) according to claim 1 or 2, wherein a guide wire is also provided for easier application of the catheter ( 2 ). 4. Catheter ( 2 ) according to one of claims 1 to 3, wherein the ring balloon ( 6 ) by means of a fluid provided via the lumen ( 4 ) and a fluid source ( 20 ) is insufflatable and desufflatable. 5. Catheter ( 2 ) according to one of claims 1 to 4, wherein the lumen ( 4 ) opens directly into the interior of the ring balloon ( 6 ). 6. Catheter ( 2 ) according to one of claims 1 to 5, wherein the ring balloon ( 6 ) consists at least partially of plastic. 7. The catheter ( 2 ) according to claim 6, wherein the plastic is latex. 8. Catheter ( 2 ) according to one of claims 1 to 7, wherein the width (b) of the ring of the ring balloon ( 6 ) is between 2 and 5 mm. 9. Catheter ( 2 ) according to one of claims 1 to 8, wherein further ferromagnetic elements or magnets for positioning the catheter ( 2 ) are provided from the outside. 10. Catheter ( 2 ) according to one of claims 1 to 9, wherein the lumen ( 4 ) with a pressure gauge ( 22 ) is in communication. 11. Catheter ( 2 ) according to one of claims 1 to 10, wherein the filter ( 26 ) is attached to the ring balloon ( 6 ) and catheter ( 2 ) in such a way that the filter ( 26 ) forms a closed bag in the non-expanded state. 12. Catheter ( 2 ) according to one of claims 1 to 11, wherein the filter ( 26 ) is a membrane. 13. The catheter ( 2 ) according to claim 12, wherein the pore size of the membrane is between 50 and 300 microns. 14. Catheter ( 2 ) according to one of claims 1 to 13, wherein on the inside of the ring balloon ( 6 ) a less elastic material and / or a less elastic configuration of the ring balloon ( 6 ) is provided compared to its outside.