NO811532L - BIPOLAR ELECTROCOAGULATION PROBLEMS. - Google Patents

Description

The present invention relates to a bipolar probe for v electrocoagulation and more particularly a bipolar probe for endoarterial electrocoagulation using a continuous electric current.

Various devices are already known

to carry out such electrocoagulation which is a technique for the destruction of tissue and which allows in particular to treat certain tumors without the risk of spreading or bleeding. E.g. French patents published under Nos. 2,355,521 and 2,355,520 respectively describe a clamp for electrocoagulation and transistor-based electrosurgical devices that selectively produce high-frequency, high-voltage currents for incision and coagulation. However, these devices and apparatus are not satisfactorily permanent.

It is further known (see DE-OS 2,324,658) an electrocoagulation device under high-frequency alternating current, comprising in one of its embodiments two ring-shaped electrodes separated by an insulating cuff, while the farthest end of the device has the shape of a hemisphere and is made of insulating material. Furthermore, DE-OS 2,513,868 relates

a device for treating diseased tissue operating under high frequency alternating current and comprising extreme electrodes which can be arranged to clamp over or envelop the tissue to be burned off.

A blood clot-forming device is also known which works under direct current comprising a positive electrode inserted near the place where a clot is to be obtained and a negative electrode placed at a suitable point on the patient's skin. According to works by Abramson [Abramson (H.A.), Am.. J. Med. Sei., 1924, 167, pages 702-710] and those

to Phillips, Salazar and Thompson [Phillips (J. F.), Invest. Radiol., 1973,8, pages 295-304, Phillips (J.F.) et al., Radiology, 1975, 115, pages 319-321, Salazar (A.E.), Cir. Res., 1961,9, pages 1351-1356 and Thompson (W.M.) et al., Invest. Radiol., 1977, 12 page 146-153], it has really been possible to show that there is a polarization of the artery walls and the elements found in the blood (Piton (J.) et al., J.

Neuroradiol., 1978, 5, pages 139-152 and Neuroradiol., 1978, 16, pages 385-388] and establish that artificial depolarization created by a positive electrode results in a lesion of the interior and formation of a ring of lichen adhering to the arterial wall . Electrocoagulation with a positive direct current electrode has allowed completely selective interventions without exhibiting the risks that other embolization techniques entail, i.e. a risk of necrosis with the fluid blood clots, and, regardless of the material used, a risk of backflow of the liver ring into a fresh area. An arterial occlusion technique by endovascular means has also been developed (Piton (J.), J. Radiol., 1979, 60, no. 12, pages 799-808) using a relatively simple system which allows to achieve lasting results on height with electrocoagulated arteries.

However, such a system that uses a negative external electrode frequently causes complications in the area of this in the form of small burns on the skin where this electrode is applied. However, it is possible to suppress this deficiency and use a negative electrode on tissue moistened by an electrolyte.

However, this technique is only suitable for the treatment of small arteries that do not have a diameter of more than 5 mm, and not for arteries with much greater flow such as e.g. the renal artery or the hepatic arteries. For these large arteries and the same for arterio-venous fistulas with a large flow, a total thrombosis cannot be achieved until after a very long time of action for the active electrode, and it is to date only proposed to seek to remedy

this situation to increase the contact surface for the electrode or to resort to a temporary temporary arterial obstruction using a bidirectional ball probe upstream of the point where the electrocoagulation is to be carried out.

It has now been found that in a greatly reduced time and with optimal results and fewer secondary effects, an embolization can be achieved by electrocoagulation using electric direct current for small as well as large arteries and equally large arterio-venous fistulas, thanks to be a new bipolar probe coaxially inserted into an angiographic catheter.

The subject matter of the present invention is therefore a bipolar probe for electrocoagulation with direct current, connected to a generator for continuous current or a rectifier fed from an alternating current source, and this is characterized by the fact that it comprises an anode and a cathode capable of coaxially could be introduced into a classic angiographic catheter whereby the anode is arranged in the area farthest from the probe and the cathode is arranged upstream at a certain distance from the anode and the probe, as well as a sleeve of soft material in which the conductors connecting the electrodes to the power source are located.

In practice, the electrodes may be made of any known metal or alloy, in particular of platinum, silver, stainless steel, copper or tinned copper, while stainless steel is preferred. The electrodes may be of any shape and dimension provided they are compatible with the dimensions of the catheter being used; the choice depends on, among other things of the speed and dimension of the desired embolism and it is obvious to the person skilled in the art, possibly after routine testing, to give the probe electrodes according to the invention the dimensions and shapes that best suit the desired target, in many cases the type or in any case the shape. Indicatively, one can suggest an anode consisting of a spiral wire or a plate wound around the axis of the probe with a length of approximately 5-20 mm, and a cathode consisting of a sleeve with a length of 3 20 mm which surrounds the probe upstream of the anode and which allows there may be between it and the anode a space of approximately 5 - 60 mm that can be kept open or it may possibly be embedded in the same soft material that envelops the conductors that carry the electrodes at their respective free ends.

From an electrical point of view, it is essential that the materials used for the conductors ensure a single resistance in them against currents whose intensities can vary between

about. 8 and approx. 12 mA for a continuous voltage of approx. 6-10

volts, as this resistance and this voltage correspond to the conditions used for the probe according to the invention. The generator for the direct current or the rectifier for the alternating current in the grid can be made in such a way that the voltage and/or amperage can be arbitrarily varied within the values mentioned above.

The casing material can e.g. chosen from polyethylenes or any other soft plastic material that does not conduct electricity and which is approved by the French Pharmacopée such as PTFE, polyurethanes, polyamides or possibly silicones and derivatives.

In general, the dimensioning of the probe and the various components can be variable and is a function of the size and length of the artery to be embolized, the whole can slide in an angiographic catheter of any dimension such as e.g. of caliber 7F for large arteries and caliber 5F for small arteries without this being limiting.

The probe is, of course, radio-opaque. It must be sufficiently soft to ensure atraumatic catheterization of the arteries to be embolized. This softness is further improved when the portion constituting the anode is made of a coiled wire and of a length sufficient to provide a radius of curvature suitable for selective catheterization of the vessel to be embolized.

According to a particularly interesting variant, the probe according to the invention can additionally comprise, embedded in the axis of the above-mentioned casing, a fiber optic system suitable for guiding a rayon laser from a suitable source and opening essentially in the axis of the hollow volume defined by the anode by distal end of the probe.

In order to have a complete embolization equipment, it is also appropriate to add an angiographic catheter to this probe where it can slide freely, and possibly a suitable device to provide direct current.

In order to use in practice the electrocoagulation system according to the invention, one can subsequently perform the first catheterization with one or more control angiographies, if this is desired, and bring the probe according to the invention to a place as close as possible to the place of the artery where one wants to carry out the electrocoagulation. Depending on the disease to be treated, the angiography catheter can be withdrawn at the end of the operation or left in place.

The simplicity and speed of the vascular obstruction achieved with the probe according to the invention is essentially a function of, on the one hand, the amount of circulation and the caliber of the artery, on the other hand, the anode surface and the contact with the blood and the arterial wall.

In function, a partial or total electrolysis of the anode can occur, which entails a more or less total corrosion of this, and also occasionally a release of its distal fragment in the embolized artery, where this fragment is found in the liver ring and is one with the trom boss.

In all cases, the lesions formed are definitive and the interventions are totally selective, which justifies the use of the system according to the invention for localized devascularizations, especially in light of removing surgical interventions.

The endovascular probe according to the invention acts on the circulating proteins and on ions contained in the blood and transfers these by electrolysis, its main effect is to modify the fibrin's tertiary structure and renders this insoluble.

Claims (5)

1.B bipolar electrode for electrocoagulation with direct current, in function connected to a generator for. direct current or a rectifier fed from an alternating current source, characterized in that it comprises an anode and a cathode suitable for coaxial introduction into a classical angiographic catheter, the anode being arranged in the distal part of the probe and the cathode being located upstream and in a certain distance from the anode on the probe, as well as an envelope of soft material in which are embedded conductors that connect the electrodes to the power source. 2. Bipolar probe according to claim 1, characterized in that the electrodes are made of stainless steel. 3. Bipolar probe according to any one of claims 1 or 2, characterized in that the anode consists of a spiral wire or of a wound band, around the axis of the probe in a length of approximately 5-20 mm, and that the cathode consists of a sleeve with a length of about 3 - 20 mm, around the probe upstream of the anode so that a space of about 5 - 60 mm remains between the anode and the cathode. 4. Bipolar probe according to any one of claims 1-3, characterized in that the soft material of the sheath is polyethylene, PTFE, a polyurethane, a polyamide or a silicone or a derivative thereof. 5. Bipolar probe according to any one of claims 1-4, characterized in that it comprises, preferably embedded in the axis of the sheath of soft material, a fiber optic system capable of directing a rayon laser from a suitable source so that it substantially in the axis of the hollow volume defined by the anode at the distal end of the probe.