NL8000019A - VALVE FOR A SURGICAL IMPLANTABLE SHUNT SYSTEM AND METHOD FOR CHECKING THE CLOSING OPERATION OF THE VALVE. - Google Patents

Description

N / 29438-St / lb ^

Valve for a surgically implantable shunt system, as well as a method for checking the occlusion of the valve.

The invention relates to a valve for a surgically implantable shunt system for draining cerebrospinal fluid from a cerebroventricular catheter to a draining catheter, which valve serves to provide a certain back pressure to the cerebral ventricles. Such an implantable shunt system is used in the case of hydrocephaly and such states of impaired circulation and absorption of cerebrospinal fluid. It is important here that the counter pressure on the ventricles provided by the valve is accurately adjustable.

Mechanical devices for controlling the drainage of cerebrospinal fluid into the bloodstream are known, see, for example, the shunt device described in U.S. Patent 3,288,142. Such devices have a valve which causes a flow in one direction from the ventricles to the drain in the circulation system. Although the known valves generally work well, they are relatively expensive and difficult to manufacture. Furthermore, the known valves are relatively heavy and large, while the metal parts thereof are disturbing during X-ray examination. The known valves also sometimes threaten to clog by degradation products of the brain or by protein from the cerebrospinal fluid if they occur to an abnormally high level. This applies in particular to so-called slit valves which have been used for the present purpose, i.e. valves, which consist only of a narrow slit in an elastic tube. Such degradation products can prevent the valve from closing properly, so that the valve can no longer accurately control the back pressure at the cerebral ventricles.

Another drawback of the known shunt valves for use in the treatment of hydrocephaly is the relatively large hysteresis between the opening pressure and the closing pressure of the valve, which means that there is no sharply determined limit pressure at which the valve opens.

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The known valves of the present type have hitherto been tested by subjecting the valve to a vacuum or a gas pressure or placing it in a liquid environment. However, these methods are cumbersome and time consuming and can lead to contamination of the valve.

The object of the invention is to provide a cerebroventricular shunt valve of the type mentioned in the preamble, which combines a high reliability with a simple construction and which is compact, has a low weight, can be manufactured inexpensively and has the greatest possible permeability. for x-rays.

It is further an object of the invention to provide such a valve, which has a small hysteresis and a low sensitivity to blockage by degradation products, so that the valve can provide an accurately adjustable back pressure to the cerebral ventricles.

It is also an object of the invention to provide a method with which the sealing action thereof can be checked with simple optical means during the manufacture of the valve.

The valve according to the invention is characterized by an elongated hollow valve housing, which is divided by a flat plate placed in this housing in an inlet chamber to be connected to the ventricular catheter and an outlet chamber to be connected to the discharge catheter, which plate is provided with a round opening connecting these two chambers, the annular rim of which forms a seat for a spherical ball, which has a larger diameter than the opening and which controls the flow of liquid through the opening, the ball being spring-loaded with a ball-engaging protruding flat spring arm is pressed against the opening edge to form a closed tilt position of a circular seal between the ball and the olate such that the valve provides a precisely determined back pressure and low hysteresis as well as low sensitivity to degradation products has.

The valve is suitable for use in a hydrocephaly treatment system as illustrated, for example, in Figure 1 of U.S. Pat. No. 40 3,527,226.

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The separating plate between the two chambers of the valve body can consist of a thin plate of stainless steel, which is closely fitted in the tubular valve body. The flat spring arm, generally also made of metal 5, preferably runs parallel to the plane of the plate opening and engages the ball in a single point, so that in the open position of the valve the ball can rotate easily, whereby the accumulation of breakdown products is countered.

After the valve has been manufactured, its function and, in particular, the seal must be checked when the tilt is closed.

According to the invention this can be done in that light of a wavelength, for which the ball is impermeable, is directed at the plate opening when the ball rests against the opening edge, whereby the light, if any, passing through the opening is received by a photosensitive detector which, depending on the amount of transmitted light, indicates the sealing effect of the valve.

If no light can leak through the opening along the ball, a good seal between ball and plate occurs.

An embodiment of the valve according to the invention is shown in the drawing.

Fig. 1 is a longitudinal section of the valve; Fig. 2 is a sectional view taken on the line II-II of Fig. 1; Fig. 3 is a longitudinal section of a part of the plate with the opening arranged therein; FIG. 4 is a top plan view of the flat plate 30 with the spring mounted thereon; and FIG. 5 is a schematic depiction of an optical method for checking the valve closing action.

The valve, shown as a whole by 10 in Figures 1 and 2, has a hollow valve housing 11, which is preferably injection molded from polyether sulfone. The valve body 11 is connected at its inlet end to a cerebroventricular catheter 12 and at its outlet end to a discharge catheter 13 or to a pump system containing a second valve, for example, in the manner described in U.S. Pat. No. 3,527,4000019-4. .226. A thin flat plate 14, which is preferably made of stainless steel, is placed snugly in the valve body 11 and divides the interior of the valve body into an inlet chamber 15 and an outlet chamber 16. For example, the thin plate 14 has a length of 9.1 mm, a width of 3.4 mm and a thickness of 0.2 mm.

In the flat plate 14, an opening 17 having a diameter of 1.4 mm is provided, which opening has a highly polished opening edge and connects the inlet chamber 15 to the outlet chamber 10 16 to form a flow path for cerebral spinal fluid of the cerebral ventricles. to the discharge of this liquid into the circulation system. As can be seen more clearly in Fig. 3, the round opening 17 in the flat plate 14 has a hollow beveled top edge 18, the radius of curvature of which is equal to the radius of a spherical ball 19, so that the opening edge 18 is a seat for this ball 19 provided. The radius of curvature of the beveled edge 18 is about 0.75 mm. By the combination of the valve body 11 and the thin plate 14 placed therein, the shunt valve can be lightweight and compact and can be manufactured inexpensively.

The spherical ball 19, which serves to control the limited flow of liquid through the valve, consists of a highly polished hard material, preferably a synthetic sapphire, which ball has a diameter of 1.5 mm, which is therefore greater than the diameter of the opening 17, so that the ball can rest on the beveled opening edge 18 and seal against it. The highly polished surfaces of the ball 19 and. the edge of the opening 17 ensures good sealing when the ball 19 rests on its seat, and further reduces any tendency of the ball to lock into its seat. This makes it possible to obtain an accurately determined and constant opening pressure of the valve.

It can be seen from Figures 1 and 4 that a flat U-shaped curved spring 20 is fixed to spot 21 or 21 by spot welding or other suitable means on the flat plate 14.

The spring constant of the spring 20 can be varied by changing its width or thickness, making it possible to manufacture valves with different opening pressures. The free arm of the spring 20 pays equally to the plane of the opening 17 and extends over the ball 19, this flat spring arm engaging the ball at a single point, thereby engaging the ball against the edge 18 of the opening. 5 ning 17. This design results in a small hysteresis between the opening pressure and the closing pressure of the valve. In the open position of the valve, the ball 19 can rotate freely through its point contact with the spring 20, thereby preventing the accumulation of breakdown products and allowing an accurate control of the back pressure applied to the cerebral ventricles.

The valve 10 is assembled by inserting the assembly formed by the plate 14, the ball 19 and the spring 20 into the valve housing 11 from the right side of Fig. 1.

The profile of the chamber 16 is such that the ball 19 always remains with part thereof in the opening 17. For this purpose, a shoulder 28 is formed on the wall of the chamber 11, which limits the deflection of the spring 20 and thereby prevents the ball 19 from escaping from the opening 17.

In Fig. 5, a method for checking the sealing properties of the shunt valve is schematically shown.

A light source 25 illuminates the side of the plate 14 facing away from the spring 20, while the ball 19 is pressed into the opening 17 against its seat. The wavelength of the light from the light source 25 is chosen such that the ball 19 does not transmit this light. With a sapphire ball, for example, green light is suitable. A photosensitive detector 26 is disposed on the other side of the flat plate 14 and receives the light that would pass through the opening 17 in the plate 14 and along the ball 19, if desired. If no light reaches the detector, this means that the valve closes properly.

Although in the described exemplary embodiment the valve body 11 is injection molded from polyethersulfone and the flat plate 14 and the spring 19 are made of stainless steel, it is clear that other stable, inert and non-toxic materials can also be used . Although it is further preferred to use sapphire as the material for the ball 19, other hard, non-toxic and inert materials can also be used instead of 8000019.

The valve described has a squat shape, is lightweight, and can be inexpensively manufactured and easily assembled. More importantly, with the help of the disclosed valve, precise control of cerebrospinal fluid pressure in the cerebral valves is possible.

8000019

Claims (5)

A valve for a surgically implantable shunt system for draining cerebrospinal fluid from a cerebroventricular catheter to a draining catheter, the valve serving to provide a certain back pressure to the cerebral ventricles, characterized by an elongated hollow valve housing, which is inserted through a This flat plate placed in this housing is divided into an inlet chamber to be connected to the ventricular catheter and an outlet chamber to be connected to the discharge catheter, which plate is provided with a round opening connecting these two chambers, the annular edge of which forms a seat for a spherical ball, which has a larger diameter than the opening and controls the flow of liquid through the opening, the ball being pressed against the opening edge by a spring with a protruding flat spring arm engaging the ball to form in the closed tilt position of a circular seal between the ball and the plate, such that the valve is one n accurately provides back pressure and has low hysteresis as well as low sensitivity to deposition degradation products. Valve according to claim 1, characterized in that. note that the flat plate is stainless steel and the aperture therein has a highly polished aperture edge, and the ball consists of a highly polished spherical sapphire, while the flat arm of the metal spring engaging this ball is parallel at the plane of the plate opening. Flap according to claim 1 or 2, characterized in that the flat plate has a thickness of approximately 0.2 mm. Valve according to any one of the preceding claims, characterized in that the circular opening in the flat plate has a diameter of about 1.4 mm and the ball has a diameter of about 1.5 mm. 35 Method for checking the closing effect of the valve according to any one of the preceding claims, characterized in that light of a wavelength, for which the ball is impermeable, is directed at the plate opening 80 0 0 0 1 9 - 8 - when the ball rests against the opening edge, and the light which may pass through the opening is received by a light-sensitive detector, which, depending on the amount of transmitted light, indicates the sealing of the valve. 80 0 0 0 19