Direction-oriented and spatially controlled bipolar coagulator for in-situ cauterization of adherent cranial tissue occluding a ventricular catheter previously implanted in-vivo
First Claim
1. A bipolar coagulator for in-vivo coagulation cauterization of tissue which is occluding at least one sidewall hole leading to the internal lumen of a catheter previously implanted into the body of a living subject for in-vivo flow release of fluids, said bipolar coagulator comprising:
- a flexible obturator of fixed dimensions and substantially cylindrical form which is configured to fit within and pass through the inner diameter of the internal lumen of the catheter previously implanted in-vivo, said flexible obturator (i) comprising a shaped proximal end section adapted for passage within the inner diameter of the internal lumen of the implanted catheter, a distal end section, and a flexible body section adapted for passage through and around such internal lumen bends as may exist within the implanted catheter, and (ii) being constituted at least in part of an electrically insulating material;
at least two electrodes spatially disposed at different, direction-oriented, pre-chosen positions on the exterior surface of said proximal end section of said flexible obturator, each of said electrodes comprising a discrete electrode tip disposed on said exterior proximal end surface of said obturator at a pre-chosen position and an electrically communicating electrode body which is joined to said electrode tip and which extends into the interior of said obturator, said at least two direction-oriented disposed electrodes providing at least one positively charged electrode pole and at least one negatively charged electrode pole which collectively identify (a) a demarcated surface area lying between said disposed electrode poles on said exterior surface of said obturator, (b) a discrete gapped space which exists adjacent to and over said demarcated surface area between said disposed electrode poles as a cauterization zone, and (c) an on-demand electrode system for generating a direction-oriented and spatially-controlled flow of electrical arc current for coagulation cauterization over said gapped space of said obturator; and
electrical current conveyance apparatus which is contained internally at least within said proximal end section of said obturator and is joined to each electrode spatially disposed on the surface of said obturator.
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Abstract
The present invention provides a bipolar coagulator which can be passed through the internal lumen of a ventricular catheter previously implanted into a cranial ventricle of a living subject and engaged in-situ. The bipolar coagulator will provide bipolar electrical arc currents for coagulation cauterization of adherent brain tissues, such as the choroid plexus, which occludes fluid flow into the intake drainage holes in the implanted ventricular catheter and often becomes adherent to the catheter in-situ. The cautery current provided by the bipolar coagulator is direction oriented and spatially controlled; thereby providing a better distribution of electrical current and heat within the surrounding cranial tissues; and thereby avoiding major complications of damage to intracranial structures such as blood vessels as well as avoiding the severe subarachnoid hemorrhages which are typical using other kinds of coagulation instruments.
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Citations
8 Claims
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1. A bipolar coagulator for in-vivo coagulation cauterization of tissue which is occluding at least one sidewall hole leading to the internal lumen of a catheter previously implanted into the body of a living subject for in-vivo flow release of fluids, said bipolar coagulator comprising:
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a flexible obturator of fixed dimensions and substantially cylindrical form which is configured to fit within and pass through the inner diameter of the internal lumen of the catheter previously implanted in-vivo, said flexible obturator (i) comprising a shaped proximal end section adapted for passage within the inner diameter of the internal lumen of the implanted catheter, a distal end section, and a flexible body section adapted for passage through and around such internal lumen bends as may exist within the implanted catheter, and (ii) being constituted at least in part of an electrically insulating material;
at least two electrodes spatially disposed at different, direction-oriented, pre-chosen positions on the exterior surface of said proximal end section of said flexible obturator, each of said electrodes comprising a discrete electrode tip disposed on said exterior proximal end surface of said obturator at a pre-chosen position and an electrically communicating electrode body which is joined to said electrode tip and which extends into the interior of said obturator, said at least two direction-oriented disposed electrodes providing at least one positively charged electrode pole and at least one negatively charged electrode pole which collectively identify (a) a demarcated surface area lying between said disposed electrode poles on said exterior surface of said obturator, (b) a discrete gapped space which exists adjacent to and over said demarcated surface area between said disposed electrode poles as a cauterization zone, and (c) an on-demand electrode system for generating a direction-oriented and spatially-controlled flow of electrical arc current for coagulation cauterization over said gapped space of said obturator; and
electrical current conveyance apparatus which is contained internally at least within said proximal end section of said obturator and is joined to each electrode spatially disposed on the surface of said obturator. - View Dependent Claims (5, 6)
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2. A complete bipolar coagulator for in-vivo coagulation cauterization of tissue which is occluding at least one sidewall hole leading to the internal lumen of a catheter previously implanted into the body of a living subject for in-vivo flow release of fluids, said bipolar coagulator comprising:
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a flexible obturator of fixed dimensions and substantially cylindrical form which is configured to fit within and pass through the inner diameter of the internal lumen of the catheter previously implanted in-vivo, said flexible obturator (i) comprising a shaped proximal end section adapted for passage within the inner diameter of the internal lumen of the implanted catheter, a distal end section, and a flexible body section adapted for passage through and around such internal lumen bends as may exist within the implanted catheter, and (ii) being constituted at least in part of an electrically insulating material;
at least two electrodes spatially disposed at different, direction-oriented, pre-chosen positions on the exterior surface of said proximal end section of said flexible obturator, each of said electrodes comprising a discrete electrode tip disposed on said exterior proximal end surface of said obturator at a pre-chosen position and an electrically communicating electrode body which is joined to said electrode tip and which extends into the interior of said obturator, said at least two direction-oriented disposed electrodes providing at least one positively charged electrode pole and at least one negatively charged electrode pole which collectively identify (a) a demarcated surface area lying between said disposed electrode poles on said exterior surface of said obturator, (b) a discrete gapped space which exists adjacent to and over said demarcated surface area between said disposed electrode poles as a cauterization zone, and (c) an on-demand electrode system for generating a direction-oriented and spatially-controlled flow of electrical arc current for coagulation cauterization over said gapped space of said obturator;
electrical current conveyance apparatus which is contained internally at least within said proximal end section of said obturator and is joined to each electrode spatially disposed on the surface of said obturator; and
a source of electrical current in electrical flow communication with said electrical current conveyance apparatus.
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3. A bipolar coagulator for in-vivo coagulation cauterization of cranial tissue which is occluding at least one sidewall hole leading to the internal lumen of a ventricular catheter previously implanted into a cranial ventricle of a living subject for in-vivo flow release of cranial fluids, said bipolar coagulator comprising:
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a flexible obturator of fixed dimensions and substantially cylindrical form which is configured to fit within and pass through the inner diameter of the internal lumen of the ventricular catheter previously implanted in-vivo, said flexible obturator (i) comprising a shaped proximal end section adapted for passage within the inner diameter of the internal lumen of the implanted ventricular catheter, a distal end section, and a flexible body section adapted for passage through and around such internal lumen bends as may exist within the implanted ventricular catheter, and (ii) being constituted at least in part of an electrically insulating material;
at least two electrodes spatially disposed at different, direction-oriented, pre-chosen positions on said exterior surface of said proximal end section of said flexible obturator, each of said electrodes comprising a discrete electrode tip disposed on said exterior proximal end surface of said obturator at an individual pre-chosen position and an electrically communicating electrode body which is joined to said electrode tip and which extends into the interior of said obturator, said at least two direction-oriented disposed electrodes providing at least one positively charged electrode pole and at least one negatively charged electrode pole which collectively identify (a) a demarcated surface area lying between said disposed electrode poles on said exterior surface of said obturator, (b) a discrete gapped space which exists adjacent to and over said demarcated surface area between said disposed electrode poles as a cauterization zone, and (c) an on-demand electrode system for generating a direction-oriented and spatially-controlled flow of electrical arc current for coagulation cauterization over said gapped space of said obturator; and
electrical current conveyance apparatus which is contained internally at least within said proximal end section of said obturator and is joined to each electrode spatially disposed on the surface of said obturator.
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4. A complete bipolar coagulator for in-vivo coagulation cauterization of cranial tissue which is occluding at least one sidewall hole leading to the internal lumen of a ventricular catheter previously implanted into a cranial ventricle of a living subject for in-vivo flow release of cranial fluids, said bipolar coagulator comprising:
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a flexible obturator of fixed dimensions and substantially cylindrical form which is configured to fit within and pass through the inner diameter of the internal lumen of the ventricular catheter previously implanted in-vivo, said flexible obturator (i) comprising a shaped proximal end section adapted for passage within the inner diameter of the internal lumen of the implanted ventricular catheter, a distal end section, and a flexible body section adapted for passage through and around such internal lumen bends as may exist within the implanted ventricular catheter, and (ii) being constituted at least in part of an electrically insulating material;
at least two electrodes spatially disposed at different, direction-oriented, pre-chosen positions on said exterior surface of said proximal end section of said flexible obturator, each of said electrodes comprising a discrete electrode tip disposed on said exterior proximal end surface of said obturator at a pre-chosen position and an electrically communicating electrode body which is joined to said electrode tip and which extends into the interior of said obturator, said at least two direction-oriented disposed electrodes providing at least one positively charged electrode pole and at least one negatively charged electrode pole which collectively identify (a) a demarcated surface area lying between said disposed electrode poles on said exterior surface of said obturator, (b) a discrete gapped space which exists adjacent to and over said demarcated surface area between said disposed electrode poles as a cauterization zone, and (c) an on-demand electrode system for generating a direction-oriented and spatially-controlled flow of electrical arc current for coagulation cauterization over said gapped space of said obturator;
electrical current conveyance apparatus which is contained internally at least within said proximal end section of said obturator and is joined to each electrode spatially disposed on the surface of said obturator; and
a source of electrical current in electrical flow communication with said electrical current conveyance apparatus.
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7. A method for in-vivo coagulation cauterization of tissue which is occluding at least one sidewall hole leading to the internal lumen of a catheter previously implanted into the body of a living subject for in-vivo flow release of fluids, said method comprising:
obtaining a bipolar coagulator device comprising a flexible obturator of fixed dimensions and substantially cylindrical form which is configured to fit within and pass through the inner diameter of the internal lumen of the catheter previously implanted in-vivo, said flexible obturator (i) comprising a shaped proximal end section adapted for passage within the inner diameter of the internal lumen of the implanted catheter, a distal end section, and a flexible body section adapted for passage through and around such internal lumen bends as may exist within the implanted catheter, and (ii) being constituted at least in part of an electrically insulating material;
at least two electrodes spatially disposed at different, direction-oriented, pre-chosen positions on the exterior surface of said proximal end section of said flexible obturator, each of said electrodes comprising a discrete electrode tip disposed on said exterior proximal end surface of said obturator at a pre-chosen position and an electrically communicating electrode body which is joined to said electrode tip and which extends into the interior of said obturator, said at least two direction-oriented disposed electrodes providing at least one positively charged electrode pole and at least one negatively charged electrode pole which collectively identify (a) a demarcated surface area lying between said disposed electrode poles on said exterior surface of said obturator, (b) a discrete gapped space which exists adjacent to and over said demarcated surface area between said disposed electrode poles as a cauterization zone, and (c) an on-demand electrode system for generating a direction-oriented and spatially-controlled flow of electrical arc current for coagulation cauterization over said gapped space of said obturator; and
electrical current conveyance apparatus which is contained internally at least within said proximal end section of said obturator and is joined to each electrode spatially disposed on the surface of said obturator;
introducing said bipolar coagulator device into the internal lumen of the previously implanted catheter;
advancing said introduced bipolar coagulator device within the lumen of the previously implanted catheter until occluding tissue in-situ is encountered;
applying electrical current to said electrical current conveyance apparatus of said bipolar coagulator device; and
coagulating the occluding tissue in-situ using a direction-oriented and spatially controlled electric arc current generated by said bipolar coagulator device.
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8. A method for in-vivo coagulation cauterization of cranial tissue which is occluding at least one sidewall hole leading to the internal lumen of a ventricular catheter previously implanted into a cranial ventricle of a living subject for in-vivo flow release of cranial fluids, said method comprising:
obtaining a bipolar coagulator device comprising a flexible obturator of fixed dimensions and substantially cylindrical form which is configured to fit within and pass through the inner diameter of the internal lumen of the catheter previously implanted in-vivo, said flexible obturator (i) comprising a shaped proximal end section adapted for passage within the inner diameter of the internal lumen of the implanted catheter, a distal end section, and a flexible body section adapted for passage through and around such internal lumen bends as may exist within the implanted catheter, and (ii) being constituted at least in part of an electrically insulating material;
at least two electrodes spatially disposed at different, direction-oriented, pre-chosen positions on the exterior surface of said proximal end section of said flexible obturator, each of said electrodes comprising a discrete electrode tip disposed on said exterior proximal end surface of said obturator at a pre-chosen position and an electrically communicating electrode body which is joined to said electrode tip and which extends into the interior of said obturator, said at least two direction-oriented disposed electrodes providing at least one positively charged electrode pole and at least one negatively charged electrode pole which collectively identify (a) a demarcated surface area lying between said disposed electrode poles on said exterior surface of said obturator, (b) a discrete gapped space which exists adjacent to and over said demarcated surface area between said disposed electrode poles as a cauterization zone, and (c) an on-demand electrode system for generating a direction-oriented and spatially-controlled flow of electrical arc current for coagulation cauterization over said gapped space of said obturator; and
electrical current conveyance apparatus which is contained internally at least within said proximal end section of said obturator and is joined to each electrode spatially disposed on the surface of said obturator;
introducing said bipolar coagulator device into the internal lumen of the previously implanted catheter;
advancing said introduced bipolar coagulator device within the internal lumen of the previously implanted ventricular catheter until occluding tissue in-situ is encountered;
applying electrical current to said electrical current conveyance apparatus of said bipolar coagulator device; and
coagulating the occluding tissue in-situ using a direction-oriented and spatially controlled electric arc current generated by said bipolar coagulator device.
Specification