Abstract: A microelectrode comprises an oblong electrically conducting electrode body covered by distal and proximal sections of a layer of insulating material except for an annular contact section disposed between them, a blunt distal bulge at the distal end of a radial extension substantially greater than that of the proximal section of non-conducting material. For implantation into soft tissue the microelectrode is provided with a support of a material dissolvable in body fluid. Also disclosed is a set of microelectrodes sharing such support, a method of manufacture of the microelectrode and the set, and uses of the microelectrode and the set.

Abstract: An implantable microfilament guiding structure that has spatially arranged channels intended for the accommodation and movement of microfilaments such as electrically conductive microelectrodes. The microfilament guiding structure has materials which disintegrates and/or dissolves when subjected to mammalian tissue fluids. The channels of the microfilament guiding structure are spatially arranged such that the distances between at least some of said channels gradually increase in the distal direction. The microfilament guiding structure forms part of a proto electrode also referred to as prior microfilament assembly. Also disclosed are methods for manufacturing the microfilament guiding structure and proto microelectrode assemblies and a method for implantation of microfilaments in soft tissue.

Abstract: A method of providing a channel filled with aqueous gel in soft tissue comprises injecting a biocompatible aqueous gel into the tissue. Also disclosed is a corresponding device, the combination of the device and a guide for its insertion into tissue, and a system comprising the combination and a reservoir filled with aqueous gel comprising means for exerting pressure on the gel.

Abstract: A method for optimization of the stimulation pattern of a set of implanted electrodes in excitable tissue of a patient is disclosed, wherein it comprises the steps of: (a) choosing a first group of a certain number of from said set of implanted electrodes, (b) stimulating the excitable tissue electrically by said first group of electrodes, (c) registering information provided by the patient, (d) assigning each electrode of said first group of electrodes a value related to said information, wherein these steps are repeated for one or more further groups of said certain number of electrodes chosen from said set of implanted electrodes, wherein each electrode may be included in one or several groups, wherein the total assigned value for each electrode is calculated, and wherein electrodes having a total assigned value exceeding a predetermined value or a predetermined number of the electrodes having the highest total assigned value are chosen to be included in said stimulation pattern, as well as a method for tr

Abstract: In a method for implantation of a physically stabilized aggregate of living cells or tissue fragment is injected into a channel provided in soft tissue filled with an aqueous gel. Also discloses are methods of stabilizing such aggregates and fragments and of forming such channel in soft tissue as well as means for carrying out the methods.

Abstract: A microelectrode array comprises three or more flexible oblong, electrically co-operating microelectrodes in wire and/or ribbon form disposed substantially in parallel. The microelectrodes are electrically insulated except for at a distal section thereof. The array further comprises electrically non-conducting microfibres connecting central portions of the microelectrodes in oblique directions in respect of the array axis. In a preferred array variety the microelectrodes are joined by a glue that is dissolvable or degradable in aqueous body fluid. Also disclosed is a combination of two or more arrays of the invention.

Abstract: A microelectrode that is useful for implantation into, or placement adjacent, soft tissue, such as neural tissue, and includes a conductive element having a distal non-insulated portion and a proximal insulated portion. Part of the conductive element is disposed in a casing of electrically insulating non-degradable material, the casing encapsulating the non-insulated portion of the conductive element, and including at least one opening and a first structural component in which the electrically insulated portion of the conductive element can slide in an axial direction.

Abstract: In a method for implantation of a physically stabilized aggregate of living cells or tissue fragment is injected into a channel provided in soft tissue filled with an aqueous gel. Also discloses are methods of stabilizing such aggregates and fragments and of forming such channel in soft tissue as well as means for carrying out the methods.

Abstract: A device selected from microelectrode, temperature sensor, optical sensor, optical fibre, temperature control element, and microdialysis probe for insertion into soft tissue comprises a body with a distal terminal section and a layer of an agent such as gelatin capable of forming a gel with aqueous body fluid on the terminal section. The terminal section and the gel-forming layer have a temperature of more than 30° C. below body temperature during a period of time prior and up to insertion. Also disclosed is method of insertion, an insertion assembly and a use of the device.

Abstract: A device for insertion into soft tissue including a micro electrode, a micro light source; a stiffening element having a material dissolvable or degradable in aqueous body fluid or a material swellable in such fluid to form a transparent gel; a coat of a flexible non-conducting polymer material on the stiffening element; a base disposed at the rear end of the device. The flexible coat has a distal opening allowing light emitted from the light source to leave the device upon said collapse or dissolution or swelling. Also disclosed is a therapeutic or diagnostic device formed in the tissue from the insertable device, uses thereof, and a method of disposing the insertable device in soft tissue.

Abstract: A proto-microelectrode, a proto-microelectrode bundle and array, a method of manufacture of the proto-microelectrode, and a method of using the proto-microelectrode, the proto-microelectrode being capable of forming a microelectrode upon implantation into soft tissue, and includes an oblong electrode body; an optional first coat of electrically non-conducting material on the electrode body; a second coat of water insoluble flexible polymer material enclosing, at a distance, the electrode body and the first coat, the second coat including one or more through openings; a first layer of ice disposed between the electrode body and the second coat.

Abstract: A microelectrode probe for implantation into soft tissue comprises an envelope of flexible polymer material divided by a wall into a distal and a proximal compartment filled with matrices of biocompatible material dissolvable or degradable in aqueous body fluid and comprising a centrally disposed electrically conducting core penetrating the wall and attached to it. The core is insulated at its proximal portion from which it extends to a holder for attachment to a tissue different from said soft tissue. The envelope and the core extending distally from the holder are embedded in an additional matrix of similar kind. Also disclosed is method for its manufacture, an array comprising two or more microelectrode probes and a microelectrode probe for incorporation into the array as well as method for the manufacture of the array.

Abstract: A method is provided for optimization of a stimulation specificity and an energy consumption of implanted electrodes in excitable tissue of a patient. The method may involve electrically stimulating excitable tissue between one or more combinations of electrode pairs in a cluster of electrodes, or electrically stimulating excitable tissue between one or more combinations of electrode pairs in two or more clusters of electrodes. The two electrodes of the electrode pairs may not belong to a same cluster. Each of the electrodes may be located on a physically separated entity, such that the tissue surrounds and separates each electrode from all other electrodes, thereby allowing tissue between the electrodes to be stimulated. An electrode pair or pairs which give rise to a lowest energy consumption while still giving a therapeutic effect may be chosen.

Abstract: A method for optimization of the stimulation pattern of a set of implanted electrodes in excitable tissue of a patient is disclosed, wherein it comprises the steps of: (a) choosing a first group of a certain number of from said set of implanted electrodes, (b) stimulating the excitable tissue electrically by said first group of electrodes, (c) registering information provided by the patient, (d) assigning each electrode of said first group of electrodes a value related to said information, wherein these steps are repeated for one or more further groups of said certain number of electrodes chosen from said set of implanted electrodes, wherein each electrode may be included in one or several groups, wherein the total assigned value for each electrode is calculated, and wherein electrodes having a total assigned value exceeding a predetermined value or a predetermined number of the electrodes having the highest total assigned value are chosen to be included in said stimulation pattern, as well as a method for tr

Abstract: A proto microelectrode from which a micro electrode is formed in situ upon insertion into soft tissue comprises a flexible oblong electrode body of electrically conducting material having a front end and a rear end. The electrode body having a metal or a metal alloy or an electrically conducting form of carbon or an electrically conducting polymer or a combination thereof. A first coat of a water soluble and/or swellable and/or degradable material is disposed on the electrode body and extends along is at least over a distal portion thereof. A second coat of electrically insulating, water insoluble flexible polymer material is disposed on the first coat. The second coat comprises one or more through openings at or near its front end. Also disclosed is a corresponding micro electrode and a method of manufacture.

Abstract: A proto-device for implantation into soft tissue comprises an oblong device body, biodegradable microfibres adhesively attached to the body, a rigid matrix of biocompatible material enclosing the body and the microfibres. The biocompatible material is dissolvable and/or degradable in aqueous body fluid at a rate substantially superior to the rate of microfibre degradation. The proto-device is one of proto-microelectrode, proto-optical fibre, proto-polymer tube for drug delivery, proto-electrical lead, proto-encapsulated electronics. Also disclosed are uses of the proto-device and methods for its implantation and manufacture.

Abstract: A method of identifying upon insertion into soft tissue a microelectrode of a set of three or more microelectrodes each comprising an electrically conductive body comprises providing the microelectrode with a unique metallic pattern of three or more sections separated from each other and disposed in an axial direction on the body and/or on one or more insulating layers on the body; inserting the microelectrode into the tissue simultaneously or consecutively with the other microelectrodes of the set; detecting the pattern by computer tomography (CT) or X-ray. Also disclosed are microelectrodes provided with unique patterns and sets of such microelectrodes and their use.

Abstract: A device selected from microelectrode, temperature sensor, optical sensor, optical fibre, temperature control element, and microdialysis probe for insertion into soft tissue comprises a body with a distal terminal section and a layer of an agent such as gelatin capable of forming a gel with aqueous body fluid on the terminal section. The terminal section and the gel-forming layer have a temperature of more than 30° C. below body temperature during a period of time prior and up to insertion. Also disclosed is method of insertion, an insertion assembly and a use of the device.

Abstract: A microelectrode array comprises three or more flexible oblong, electrically co-operating microelectrodes in wire and/or ribbon form disposed substantially in parallel. The microelectrodes are electrically insulated except for at a distal section thereof. The array further comprises electrically non-conducting microfibres connecting central portions of the microelectrodes in oblique directions in respect of the array axis. In a preferred array variety the microelectrodes are joined by a glue that is dissolvable or degradable in aqueous body fluid. Also disclosed is a combination of two or more arrays of the invention.

Abstract: A proto microelectrode from which a micro electrode is formed in situ upon insertion into soft tissue comprises a flexible oblong electrode body of electrically conducting material having a front end and a rear end. The electrode body having a metal or a metal alloy or an electrically conducting form of carbon or an electrically conducting polymer or a combination thereof. A first coat of a water soluble and/or swellable and/or degradable material is disposed on the electrode body and extends along is at least over a distal portion thereof. A second coat of electrically insulating, water insoluble flexible polymer material is disposed on the first coat. The second coat comprises one or more through openings at or near its front end. Also disclosed is a corresponding micro electrode and a method of manufacture.