WO2015073877A1 - Methods, systems, and apparatuses for delivery of electrolysis products - Google Patents

Methods, systems, and apparatuses for delivery of electrolysis products Download PDF

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Publication number
WO2015073877A1
WO2015073877A1 PCT/US2014/065783 US2014065783W WO2015073877A1 WO 2015073877 A1 WO2015073877 A1 WO 2015073877A1 US 2014065783 W US2014065783 W US 2014065783W WO 2015073877 A1 WO2015073877 A1 WO 2015073877A1
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WO
WIPO (PCT)
Prior art keywords
electrode
pad
site
electrolysis
aqueous matrix
Prior art date
Application number
PCT/US2014/065783
Other languages
French (fr)
Inventor
Paul Mikus
Liel RUBINSKY
Boris Rubinsky
Original Assignee
Paul Mikus
Rubinsky Liel
Boris Rubinsky
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Paul Mikus, Rubinsky Liel, Boris Rubinsky filed Critical Paul Mikus
Priority to EP21212317.8A priority Critical patent/EP3981465A1/en
Priority to EP14862428.1A priority patent/EP3068925B1/en
Priority to US15/036,386 priority patent/US10154873B2/en
Publication of WO2015073877A1 publication Critical patent/WO2015073877A1/en
Priority to US16/219,815 priority patent/US11260165B2/en
Priority to US17/553,401 priority patent/US20220105256A1/en

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    • CCHEMISTRY; METALLURGY
    • C25ELECTROLYTIC OR ELECTROPHORETIC PROCESSES; APPARATUS THEREFOR
    • C25BELECTROLYTIC OR ELECTROPHORETIC PROCESSES FOR THE PRODUCTION OF COMPOUNDS OR NON-METALS; APPARATUS THEREFOR
    • C25B1/00Electrolytic production of inorganic compounds or non-metals
    • C25B1/01Products
    • C25B1/24Halogens or compounds thereof
    • C25B1/26Chlorine; Compounds thereof
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Definitions

  • Electrolysis generally refers to a process of inducing an electrochemical reaction that involves passing a direct current through an ionic solution via electrodes. Electrolysis may facilitate the removal and/or addition of electrons from atoms and/or ions, which may lead to the formation of new products. For example, by passing a DC current through a saline solution (NaG and ⁇ :? 0), hypochiorous acid (HCIO) may be formed.
  • a saline solution NaG and ⁇ :? 0
  • hypochiorous acid HCIO
  • Hypochiorous acid has disinfecting properties and is often used as a cleaning agent. In. some applications, Iiypoc remplious acid is used to ablate unwanted tissue and/or disinfect wounds in tissue. Hypochiorous acid is typically introduced to the wound by pouring a solution of hypochiorous acid over the wound or soaking a wound dressing in hypochiorous acid and applying the dressing to the wound.
  • hypochiorous acid When exposed to air. hypochiorous acid decomposes over time. As the acid breaks down, the disinfecting and ablation properties are decreased. To maintain effectiveness, fresh hypochiorous acid is poured over the wound and/or the soaked gauze is replaced at multiple intervals. The labor intensive nature of continuing! ⁇ ' treating wounds to ensure effectiveness of disinfection as well as the lack of precision in delivering the hypochiorous acid may make this mode of use of hypochiorous acid impractical in emergency and clinical environments.
  • Wkj ⁇ Aii example apparatus for delivery of electrolysis products to a site may include an electrode, an aqueous matrix in contact with the electrode, wherein the aqueous .matrix, may include a saline solution, wherein the electrode may include a materia! and the aqueous matrix may have a H, the material and the pH may be selected to produce the electrolysis products when a current is passed through the aqueous matrix using the electrode, and wherein the electrode and the aqueous matrix, may be packaged for placement proximate the site.
  • An example system for delivery of electrolysis products to a site may include a device which may he positioned proximate the site, wherein the device may include an electrode and an aqueous matrix, a power supply, a controller which may be positioned at the site or remotely from the site, the controller may be in communication with the electrical circuit, and wherein the controller may be programmed to provide art electronic signal to the circuit for the electrode to produce the electrolysis products, wherein the electronic signal may be indicative of a dose of the electrolysis products and the timing of the production of the dose.
  • An example method for delivering electrolysis products to a site may include using a controller remote from the site, generating an electrical signal indicative of a timing and dose of the electrolysis products, providing the electrical signal to a device proximate the site, wherein the device is configured to generate the electrolysis products responsive to the electrical signal
  • FIG. 2 is a schematic illustration of an apparatus for deli very of electrolysis products to a site according to an embodiment of the disclosure.
  • FIG. 3 is a schematic illustration of an arrangement of electrodes according to aa embodiment of the disclosure.
  • FIG. 4 is a schematic illustration of another arrangement of electrodes according to an embodiment of the disclosure.
  • FIG. 5 is a schematic illustration of a system for producing electrolysis products for the treatment of surface of tissue according to an embodiment of the disclosure
  • FIG, 6 is a schematic illustration of an internal electrolysis apparatus according to an embodiment of the disclosure .
  • FIG . 7 is a schematic illustration of an internal electrolysis apparatus according to an embodiment of the disclosure.
  • FIG. S is a schematic illustration of an internal electrolysis apparatus according to an embodiment of the disclosure.
  • FIG. 9 is a schematic illustration of an internal electrolysis apparatus according to an embodiment of the disclosure.
  • FIG . 10 is a schematic illustration of a pad in accordance with an embodiment of the disclosure.
  • electrolysis products such as hypoch!orous acid
  • the products may be produced and delivered in a controlled manner to maintain effectiveness.
  • a system and/or apparatus ma include a solution capable of producing, upon electrolysis, sterilizing products. The solution may be brought into contact with the tissue to be treated. Electrodes capable of producing electrolysis ma be brought into contact with the solution, and as electric current may be generated in the solution that produces the desired levels of electrolysis products. The magnitude and duration of the current generated may be controlled to modulate the amount of products produced.
  • Fig 1 is a schematic illustration of the electrical circuit 1000 which may be used to deliver electrolysis products according to an embodiment of the disclosure.
  • the electrical circuit may include a power supply .1005, two or more electrodes 1010, .1 15 coupled to the power suppl 1005, and a control system 1020 that may regulate the current and/or voltage through the circuit 1000 or portions thereof.
  • the electrical circuit 1000 may be closed at least in part through an aqueous matrix .1 25.
  • the design of the circuit ma be such that the current is forced to pass at least in part through the aqueous matrix. 1025,
  • the aqueous matrix 1025 may include a maumade materia], a biological material, or a combination thereof.
  • the aqueous matrix 1025 may be at a treatment site in direct contact or part of the treatment site.
  • the aqueous matrix 1025 may be the site at which products of electrolysis are generated.
  • the controller 1020 may turn on and of the power to the circuit 1000, may adjust the level of power delivered, and may operate the circuit 1000 in conjunction with other devices.
  • the controller 1020 may receive feedback from measurements made in the aqueous matrix 1025 by a sensor 1030.
  • the controller 1020 may also optionally receive signals from an external controller 1035.
  • FIG. 2 is a schematic illustration of an apparatus for delivery of electrolysis products to a site according to an embodiment of the disclosure.
  • the apparatus 200 may include at least one electrode and an aqueous matrix in contract with the electrode.
  • the electrode and the aqueous matrix may be selected such that electrolysis products are produced in the aqueous matrix when a current is passed through the aqueous matrix using the electrode.
  • the aqueous matrix may include a raanmade material such as a hydrogel and/or a biological material such as tissue.
  • the electrode and aqueous matrix may be packaged for placement proximate the site to which delivery of electrolysis products is desired.
  • an electrode 210 and aqueous matrix 225 are shown packaged in a pad 200.
  • At least one electrode may be included in the apparatus.
  • the electrode 210 is shown in Figure 2, and may be a cathode in some embodimesrts. la some examples, however, the electrode 210 may be placed at a location remote from die apparatus, such as proximate another location of a patient's body in some examples.
  • a second electrode may be included in the apparatus, such as the electrode 220 shown in Figure 2. in some examples, the electrode 220 may be an anode,
  • Electrode materials arc generally selected to include a material that is selected to produce the electrolysis products when a current is passed through the aqueous matrix using th electrode.
  • the materials chosen for the electrodes, including the electrodes 210, 220, may be chosen to produce certain the electrolysis products.
  • an anode e.g. electrode 220
  • a cathode e.g. electrode 210
  • the use of mixed metal oxide anode electrodes may produce different species of electrolytic products that may be tailored for different clinical needs.
  • the electrodes may also include different materials with properties of interest. For example, platinum may be used if inert electrodes are desired or silver elecirodes or silver/silver chloride electrodes if silver ions are desired in the solution, which may furthe enhance the sterilization effect.
  • the electrodes 210 and 220 are separated by art insulating layer 215,
  • the insulating layer 15 may be implemented using any suitable insulating material.
  • the insulating layer 215 between the electrodes 210, 220 may be omitted.
  • a portion of the aqueous matrix 225 is between the electrodes 210, 220.
  • a portion of the aqueous matrix 225 is between the electrode 210 and the impermeable barrier 205,
  • One or more of the electrodes in the apparatus may be externally-accessible for receipt of an electronic signal from a controller, which may be placed remotel from the apparatus, such as the apparatus 200.
  • the controller may be integrated with apparatus 200.
  • Apparatuses described herein may include an aqueous matrix in contract with at least one electrode.
  • the aqueous matrix 225 is shown in Figure 2 in contact with both the electrodes 21 , 220, Aqueous matrices described herein, including the aqueous matrix 225, may include components for forming electrolysis products.
  • the aqueous matrix 225 may be implemented using a gel and/or hydrogel.
  • the aqueous matrix may include a saline solution.
  • the aqueous matrix may have a pH selected to produce electrolysis products, such as hypochlorous acid, la some examples, the pH of the aqueous matrix 225 may range between 2 and 5.
  • the aqueous matrix 225 may be placed hi contact with a site for delivery of electrolysis products, such as by laying a pad including the aqueous matrix 225 on the site,
  • the aqueous matrix 225 may include a low pH saline solution (e.g. about 3 t 4 pH) that is configured for the production of hypochlorous acid.
  • the materials included in the solution included in the aqueous matrix 225 may be chosen to produce the desired electrolysis products, such as hypochlorous acid).
  • the aqueous matrix 225 ma have a higher electrical conductivity than the site for delivery of electrolysis products. The higher electrical conductivity of the aqueous matrix 225 may result in electrolysis products produced primarily in the aqueous matrix 225, not the tissue at the site.
  • the ionic composition of the aqueous matrix 225 may he designed to have the desired conductivity but to include different ions from those normally in tissue, for example a greater concentration of Na or Ca.
  • the aqueous matrix 225 may be infused with a drug for combination therapy at the treatment site. That is, both the drug and electrolysis products are delivered to the treatment site.
  • aqueous matrices described herein such as the aqueous matrix 225, may be implemented using a liquid solution.
  • the liquid solution may be prepared separately and applied directly to the treatment site before placement of the impermeable barrier 205.
  • the treatment pad 200 may be placed at the treatment site and the aqueous matrix 225 may be introduced to the treatment si te by injecting it through a port (not shown. in the impermeable barrier 205.
  • the treatment pad 200 includes a dehydrated gel. Before use, the gel may be hydrated with a solution, such as saline, to form: the aqueous matrix 225.
  • the aqueous matrix 225 is already present in the treatment pad 200. In some embodiments the aqueous matrix is combined with body tissue and/or body fluids. 1 3 i
  • the a least one electrode in the apparatus may be coupled to a power supply .
  • the electrodes 21 , 220 in Figure 1 may be coupled to a power supply (not shown ⁇ . Examples of power supplies may include, but are not limited to, one or more batteries, a computer ⁇ e.g., coupled via USB cable), a cellular phone, a regulated power suppl that draws energy from the electrical network, a solar cell, and combination thereof.
  • the power supply may be incorporated in the apparatus, e.g. the treatment ad 200, The power supply generally provides power to one or more electrodes to power the electrolysis process.
  • the electrode and aqueous matrix may he packaged for placement proximate a site of deli very for the electrolysis products.
  • the electrode and aqueous matrix may be packaged into the pad 200 shown in Figure 2,
  • some or all of the components of the pad 200 are disposable, hi some embodiments, some or all of the components of the pad 200 are steri ieree. hi some embodiments, some or ail of die components of the pad 200 ma be multi-use,
  • the pad 200 is sized to cover a large area of a site, in some embodiments, the pad 200 may have smaller dimensions to limit deliver ⁇ ' of electrolysis products to a smaller area.
  • the pad 200 may be implemented in a variety of shapes. For example, the pad 200 may be square, rectangular, circular, ovular, half- moon.. Other shapes may also be possible. The shape and/or size of the pad 200 may be selected based on the size and/or shape of the site for delivery.
  • the pad 200 may include an impermeable barrier 205 which may include a periphery (not shown) that may extend beyond the dimensions of the electrodes 210, 220 and/or aqueous matrix 225.
  • the periphery of the impermeable barrier 205 may include an adhesive that ma be used to secure the pad 200 to the site, i some embodiments, the pad 200 is secured by bandages. In some embodiments, the pad 200 is not secured to the treatment site.
  • an aqueous matrix may be applied to a site and electrodes applied to the aqueous matrix. For example, it may be desired to treat, a confined space between two tissues or inside of one tissue ⁇ e.g., a needle hole).
  • the aqueous matrix may be introduced into the confined space, and the electrodes may be inserted into or proximate the confined space.
  • the electrodes may be coupled to a controller arid/or Sow voltage source outside the confined space.
  • ablation by electrolysis may be performed in the interior of a blood vessel or a cavity inside the body.
  • electrodes ma touch a tissue of interest and an ionic flow that propagates by diffusion may be directed towards the tissue of interest.
  • the flow of ion in an undesirable direction may be impeded by impermeable surfaces, in some embodiments, the direction: of flow of ions may be controlled through the use of iontophoresis, electro osmosis and/or electrophoresis.
  • Example site include wounds.
  • wounds that may be treated include but are not limited to bed sores, diabetic ulcers, burns, tears, gashes, surgical incisions, cuts, scrapes, irradiation and scars formation.
  • the pad 200 may accordingly be configured to adhere to the wound.
  • the apparatuses described herein, such as pad 200, . may be used for cosmetic procedures. For example, unwanted cosmetic features may be ablated or the electrolysis products may induce tightening of the skin.
  • Example sites include infected tissue, acne, and/or the pad may be configured for placement on an implantable de vice (e.g. pacemaker, joint implant, or other medical device). When activated, the pad can then be used to treat an infection proximate the implanted device.
  • an implantable de vice e.g. pacemaker, joint implant, or other medical device.
  • Other example sites for delivery of electrolysis products include a malignant tumor, an abdomen surface, a nerve, a benign tumor, a blood vessel surface, an intestinal surface, an esophagus surface, a urethra surface, a bladder surface, or combinations thereof
  • Example apparatuses described herein may be packaged tor placement proximate a site for delivery of electrolysis products, in this manner, the device may be placed locally to the site for delivery such that the electrolysis products generated by the apparatus ma diffuse into and/or be driven toward the site.
  • the electrodes 210,220 shown in Figure 2 may be coupled to a power supply, such as a battery. While the pad 200 is applied to the site, the electrodes 210,220 may be energized by power supply, and electrolysis products are formed in the aqueous matrix 225.
  • a controller (not shown in Figure 2) may control the coupling of the electrodes 210, 220 to the power supply.
  • the controller may modulate the connection between the electrodes ' 210, 220 to the power supply to turn on and off current in the aqueous matri 225, thereby controlling generation of electro lysis products .
  • the electrolytic reaction induces a flow of material through the aqueous matrix 225.
  • the flow may extend further into the treatment site.
  • the iontophorctie, eiectro-osmoiic and/or eieetrophoretic flow may enhance transport of the electrolysis products into the treatment site. This may allow deeper tissue to be treated by the treatment a 200.
  • a negative pressure source (not shown) may be used in conjunction with the treatment pad 200 and may be applied to the tissue treated by the treatment pad 200.
  • the negative pressure source may be a tube coupled to a vacuum, a hypobanc compartment, or a maiiual suction bulb. Other negative pressure sources may be used.
  • the negative pressure source may urther enhance production of the electrolysis products at the treatment site and/or remove depleted products and/or ablated materials.
  • the negative pressure source is manually operated by a user. In some embodiments, the negative pressure source is operated by the controller.
  • FIG. 3 is a schematic illustration of an alternative arrangement of electrodes 300 according to an embodiment of the disclosure.
  • electrodes 305, 310 may be formed in the same horizontal plane and may he separated by an aqueous matrix 315, In some embodiments, the aqueous matrix 315 may he replaced by a nonconducting film on. which the electrodes 305, 315 are sputtered. The film may be embedded in or placed on or in an aqueous matrix .
  • FIG. 4 is a schematic illustration of an alternative arrangement of electrodes 400 according to an embodiment of the disclosure.
  • an anode 10 is disk-shaped and mounted to a disk-shape cathode 405.
  • the cathode 405 has a diameter greater than the diameter of the anode 410, however, in some embodiments, the anode 410 may have a diameter greater than the cathode 405.
  • the cathode 405 and anode 410 may have an insulation layer coupled between them (not shown) in some embodiments.
  • the electrodes 400 are embedded in or placed on an aqueous matrix.
  • 43] Figures 1 -4 show various electrode configurations for performing electrolysis.
  • needle electrodes may, for example, penetrate a tissue to which electrolysis products may be delivered.
  • Surface electrodes may be placed on or near a surface of a tissue to which electrolysis products may be delivered.
  • surface pad electrodes may be used where electrodes are packaged in a pad which is placed proximate (e.g. on) tissue to be treated.
  • FIG. 5 is a schematic illustration of a system 100 for producing electrolysis products (e.g. electrolytic product), which may be used to deliver electrolysis products to a site, for example for the treatment of a tissue surface according to an embodiment of the disclosure.
  • a pad 105 which may be implemented using the pad 200 of Figure 2, may be proximate a site that is to be treated (e.g. tissue 10). The pad may be coupied to a power supply 1 15.
  • An electrical circuit may be implemented through the pad and/or tissue using the circuit in Figure 1 in some examples.
  • the production and delivery of electrolysis products to the tissue 1 b the pad 105 ma be controlled by a controller 1 10.
  • the controller 1 10 may, for example, be programmed to provide an electronic signal to the pad 105 and/or power supply 1 1.5.
  • the electronic signal may be indicative of a dose of electrolysis products.
  • the electronic signal may control the timing and magnitude of a current generated in the pad 105 to produce electrolysis products. This may allow a user to customize treatment of the tissue 10.
  • the controller 1 .1 may transmit an electronic signal to the pad 105 and/or the power supply 1 15 to cause the pad 105 to produce a particular flow (e.g. constant flow) of electrolysis products to the tissue 1 .
  • a controller may be used to electronically control the generation and application of electrolysis products to a site, where the site is proximal an example pad as described herein.
  • the controller 1 .10 and/ or the power supply 1.15 may be integrated into the treatment pad 1 5.
  • the controller 1 .10 may include a programmable chip coupled to the treatment pad 105 and/or power supply 1 15.
  • the controller 1 10 may be implemented using a computing device (not shown) and be remotely coupled to the treatment pad 105, The computing device may be implemented using, for example a desktop, laptop, server, handheld device, a personal computer, a tablet computer, and/or a smart phone.
  • the computing device may be integrated with and/or shared with another piece of medical equipment, such as an injection pump, a negative pressure system, or combinations thereof.
  • the controller may be programmed to provide an electronic signal indicative of electrolysis product dose and also control the other piece of medical equipment.
  • the controller 1 1.0 may be coupled by a wire or communicate with the treatment pad 105 and/or the power supply 115 wireSessiy.
  • the controller may be programmed to provide an electronic signal indicative of a dose of the electrolysis products to an electrode described herein.
  • the controller may include such a program, or include one or more processing devices (e.g. processors) coupled to a memory encoded with executable instructions for electrolysis product delivery.
  • the controller may cause the current through the electrodes to be pulsed. Other modulation patterns may also be used.
  • the controller may also control the voltage of the power supply in some embodiments.
  • Treatment dosage may also be adjusted by the magnitude of the current applied and duration of energy applied to the aqueous matrix of apparatuses described herein.
  • length and/or magnitude of the electronic signal may further indicate a desired depth of the electrolysis product delivery. Generally, a longer application of a current ma cause electrolysis produets to be produced for a longer time, allowing them to diffuse deeper into the site,
  • the system 1 0 may further include a sensor (not shown) tor measurement of pH near at least one electrode in the apparatus for delivery of electrolysis produets, such as the pad 105.
  • the sensor may sense pH near the electrode and provide the pH value to the controller, such as the controller 1 10.
  • the controller 1 1.0 may further be programmed to adjust an electronic signal provided to the pad 105 and/or power supply 1 15 based on the pl:l near the electrode. If the pH varies outside of a predetermined range, additional components may be added to the aqueous matrix to adjust the pH to return it to a range desired for producing the electrolysis products.
  • FIG. 6 is a schematic illustration of art internal electrolysis apparatus according to an embodiment of the disclosure.
  • a balloon catheter 500 may include an electrode 505 deposited or attached to aft outer balloon surface 510,
  • the catheter 500 may include a rauhi lumen shaft 5.15 thai may allow for inlltatioa'deflaiioti of the balloon 51 , and one or more electrodes 505 to be coupled via conductors to a power source and/or controller, ⁇ ⁇ some embodiments, the multi-lumen shaft 15 may include one or more fluid transfer iumens 520.
  • the balloon catheter 500 may be inserted or in contact with an aqueous matrix 530 around the electrode 505.
  • the aqueous matrix 530 may include a manmade material, a biological material, or a combination thereof.
  • one or more electrodes may be a remote needle or pad 525ori inserted o in contact with a tissue or with the aqueous .matrix 530.
  • the aqueous matrix ma include a mammae material, a biological material or a combination thereof
  • the fluid transfer himen 520 may deliver and/or remove fluid substances proximate the electrodes 505.
  • a fluid transfer lumen 520 may deliver a saline solution to the electrodes 505 which may increase the production of hypoehSorous acid proximate the target site, in some embodiments, the fluid transfer lumen 520 may remove depleted solution, degraded electrolysis products, and/or ablated tissue from the target site. The addition and/or removal of fluids from the target site may allow for -adjustments to the properties of the solution such as H, ionic composition, -and/or dosage.
  • the removed fluids may be collected and analyzed. For example, the pH of the removed solution may be determined. The pH of the removed solution may determine the composition of new solution delivered to the target site, in another example, the solution may be analyzed for the presence of living microorganisms to determine the effectiveness of a sterilization procedure. Other analysis of the removed solution may also be performed.
  • the balloon 510 may prevent the flow of ions from the aqueous matrix 530 in an. undesirable direction. This may allow for diffusion of electrolysis products from the aqueous matrix 530 into a vessel wall or other target tissue, causing ablation on the targeted region, hi some embodiments, multiple balloons 510 may be included in the catheter 500.
  • the balloons 510 may isolate a target tissue for treatment, which may allow for controlled diffusion of electrolysis products from the aqueous matrix 530 into the target tissue, in some embodiments, the balloon. 510 may be ring-shaped. That is, the balloon. 510 may include a channel near the middle portion which may allow at least partial flow of fluid through the ' balloon 510. This may allow the electrodes 505 to contact the target site for electrolysis, but allow for blood flow and/or other fluid How during treatment
  • the electrode 505 may be deposited on rite multi-lumen shaft 515 in addition to on the balloon 51 . In some embodiments, the electrode 505 may be deposited on the raulti-hrmen shaft 515 instead of on the balloon 510. The electrode 505 may be deposited on the mulH-lumen shaft 515 upstream and or downstream from the balloon 510. In. some embodiments, whe two balloons 510 are included in the catheter 500, the electrode 505 may be deposited on the multi-Jumen shaft 515 between the two balloons 510. Other electrode 505 locations may be used.
  • the apparatus may include a spring electrode 605 design with an impermeable surface 610 attached to the back of the electrodes 605.
  • the spring electrode 605 with the impermeable surface 610 ma be embedded in an aqueous matrix 620.
  • the aqueous matrix 620 may include a manmade materiai a biological materiai or a combination thereof.
  • the impermeable surface 10 may allow for controlled diffusion of electrolysis products from the -aqueous matrix 620 into the target tissue.
  • the spring electrodes 605 may be a variet of different shapes and polarities.
  • the center shaft 61.5 may incorporate one polarity while the outer spring electrodes 605 are the same polarity and opposite polarity of the center shaft 615.
  • the apparatus 600 may allow for the application of electrolysis without occluding a vessel duct, and/or passage.
  • the apparatus 700 may include a stent 705 embedded in an aqueous matrix 715.
  • the aqueous matrix 715 may include a raanmade material, a biological material, or a combination thereof.
  • the stent 705 may have one or more configurations.
  • the stent 705 may act as an electrode.
  • a wire mesh stent may be used to deliver a low voltage direct current to the tissue.
  • inner wall of the stent 705 may be coated on one side with the aqueous matrix.
  • the stent 705 may be a nitinoi stent thai may have the inner surface of the stent 705 coated in a similar fashion.
  • the stent 705 m y be configured as cither a monopolar electrodes with a shaft 710 as a return, or with a remote second electrode as illustrated in Figure 6 in a bipolar configuration with both polarities built into the stent 705 but separated by a nonconducting surface, in some embodiments, the impermeable surface may act as a nonconductor to separate the two conducting surfaces on die stent 705.
  • FIG. 9 is a schematic illustration of another internal electrolysis apparatus 800 according to an embodiment of the disciosore.
  • the apparatus 800 may include a solid insert 805 a portion of which is at least one electrode 810.
  • the electrode 810 is an anode.
  • the electrode 810. which may be an anode, may be surrounded by an aqueous matrix 820.
  • the aqueous matrix 820 may include a manmade material, a biological material, or a combination thereof.
  • the insert 805 is a needle
  • a second electrode 15 may be positioned on the surface of the insert 805 and or in. an aqueous matrix surrounding the insert, l ' a some embodiments, the one or more electrodes may be mounted on the outer surface of the insert.
  • the outer surface of the insert 805 may be electrically insulated except for the surface area of the electrodes 810, 815.
  • the apparatus 800 may be directly introduced to the treatment site under imaging (CT. MR, Ultrasound) guidance.
  • An electrical circuit including at least two electrodes and the aqueous matrix 820 may be coupled to a power source (not shown).
  • the power source may be outside the body or inside the body.
  • the power source may be a battery.
  • the power source may be a constant DC current power supply.
  • the treatmeat may be controlled by a microprocessor (not shown) to determine and deliver dose specific treatment parameters to the targeted treatment site,
  • a treatment planning system ma he used to calculate optimal treatment zone placement over the targeted treatment area to guide placement of the insert electrode.
  • the internal electrolysis apparatuses illustrated in Figures 6-9 may include imaging components. This may allow real time monitoring of electrolysis treatment.]
  • the internal electrolysis apparatuses described above may be used in multiple applications. Examples of applications include targeted lung denervation for chronic obstructive pulmonary disease, renal denervation, and carotid bod receptors for congesti ve heart failure.
  • Another application ma in volve the use of a balloon catheter with electrodes a the treatment of percutaneous tens luminal coronary angioplasty (PTCA).
  • PTCA percutaneous tens luminal coronary angioplasty
  • an apparatus for example the apparatus 500, may be used for a traditional angioplasty procedure.
  • the electrodes incorporated on the balloon surface may then be activated pre or post balloon dilation to treat the vessel walls through the production of hypoehlorous acid, which may reduce the rate of restenosis.
  • the intraluminal electrolysis allows for treatment of the smooth muscle below the surface which may inhibit the formation of a neointima,
  • art apparatus such as the apparatus in Figure 8 may be applied to combine the use of a stent with the treatment of intraluminal electrolysis.
  • the stent may be placed by conventional means.
  • Intraluminal electrolysis may be applied via the stent which may prohibit restenosis.
  • the intraluminal electrolysis ma allow for treatment of the smooth muscle below the surface which may inhibit formation of a neointima.
  • intraluminal electrolysis may be used to treat
  • An apparatus such as apparatus 500, may be used to combine a catheter based procedure with the treatment of transluminal electrolysis.
  • the catheter may be positioned in a normal fashion to dilate the restricted vessel.
  • intraluminal electrolysis may be applied, to produce hypoehlorous acid to treat the remaining clotted area as well as the surfaces belo the vessel wall which may pre vent recurrence.
  • the low thermal aspects of the intraluminal electrolysis may make it particularly attractive for this type of application, because of the reduced or non-existent swelling of the tissue as a result of the thermal damage.
  • an apparatus such as apparatus 1057.
  • 700 ma be used to combine a stent with the treatment of the intraluminal electrolysis.
  • the stent may be place in a normal fashion.
  • Intraluminal electrolysis may be applied via the stent in order to treat any remaining clotted area as well, as below the surface which may prevent recurrence.
  • intraluminal electrolysis may be used to treat Peripheral Artery Disease (PAD).
  • An apparatus such as apparatus 500 may be used to combine a balloon catheter with intraluminal electrolysis, in this approach, the balloon may be placed by conventional means.
  • Intraluminal electrolysis may be applied via the electrodes mounted on the balloon which may treat any remaining plaque as we l as the surfaces below the vessel wall which may prevent recurrence.
  • an apparatus such as the apparatus 700 may be used to combine a stent with the treatment of intraluminal electrolysis.
  • the stent may he placed in norma! fashion.
  • Intraluminal electrolysis ma be applied via the stent to treat any remaining plaque as well as the surfaces below the vessel wail which may prevent recurrence.
  • Addition clinical applications of intraluminal electrolysis may include ablation of malignant and benign cell growth on die inner surface of the esophagus (Barrett Syndrome), colon - tumors, rectal tumors, tumors in the mouth, opening of veins for treatment of varicose veins.
  • Intraluminal electrolysis can be utilized inside the heart for ablation procedures that require full transmural lesions.
  • a first non-limiting e m le two electrodes of an electrolysis treatment system are configured similar to the electrodes in Figure 3,
  • the anode is a L5-inch (39.4mm) diameter circle of Titanium, grade 2. It is .0005 inches (0.010mm) thick.
  • the Ti was submersed In iridium chioride and then place in an oven at 450 C for 2 hours.
  • the iridium chloride reacts with the oxygen at high temperatures and a layer of iridium oxide develops on the titanium and this serves as the anode in our system.
  • An iridium oxide electrode was used here because it serves as a catalyst to the production of HC!O.
  • RQO Ruthenium Oxide
  • the larger circle with circumferential boles is made of Pyraiux (Dupont). It has an outer diameter of 2 inches (53mm) and a copper layer of 35mieron.s coated on one side with a high dielectric plastic of 45 micron. The copper surface serves as a cathode. Other materials can be used for cathodes such as Carbon, graphite, graphene, Ag/AgCl, The anode and cathode are attached across the plastic layer, which is used to electrically separate the anode from the cathode.
  • Eight holes of a diameter of 0.085 inches ⁇ 2.1mm) are equally spaced at a diameter of 0.2 inches (6.8mm)
  • the holes serve aa important function, as a conduit for the transport of ions between the cathode and anode, which may be generally referred to as a salt bridge.
  • a path for ion transport may be required for the system to function.
  • Two strips extend from the anode and cathode for the purpose of connecting the electrodes to the power supply and the power delivery control system.
  • the electrodes are then embedded in a gel in the Petri dish.
  • the gel is 0.7 gr. iJitraPitre Agarose (Invitrogen Cat No. 155510-027) dissolved in 100ml of distilled water.
  • iJitraPitre Agarose Invitrogen Cat No. 155510-027
  • 590ml of 1 olar Citric Acid and 1 Oral of Sodium Citrat was introduced.
  • 9 gr of NaCl were mixed into the solution.
  • the solution was cast in a 2" diameter, Petri dish that served as a moid, in such a. way that the electrode assembly was in the middle of the east.
  • the thickness of the gel is 6 mm.
  • Wires were coupled to the anode and. cathode of the electrode unit.
  • the wires leaving the electrode unit are connected to an Agilent E363 lA constant current power supply.
  • a top gel layer of a Methyl Violet (Fluka) dye infused agar gel was set on top of the electrolysis gel in which the electrode unit was embedded to serve as a measurement: marker for the production of hypochlorous acid.
  • the thickness of the measurement marker gel is 7mm and the diameter is 2 inch.
  • Methyl Violet is denatured by hypochlorous acid and turns clear.
  • the gel becomes clear where the HCIO has interacted with the Methyl Violet.
  • the bottom gel is a pH sensitive dye infused agar.
  • the thickness of the gel is 7mm and the diameter is 2 inch (53mm). Whenever a basic or acid solution interacts with the dye a color change occurs. Hydroxides produced at the cathode, turn this gel into a blue color.
  • hypochlorous acid induced denaturation of the methyl violet dye at the interface between the electrolytic gel and the Methyl Violet stained gel
  • the cathode could be made of other materials such as c arbon.
  • the electrolytic- pad was allowed to remain in place for another 30 minutes. After 40 minutes of application, of which only 10 minutes were active, the penetration of HCIO and the discoloration is much larger that after the 10 minutes of activation.
  • the gel pad may trap all the electrolysis products in the gel pad assenibiy. Afier 1 minutes activation ail the products are still in the gel
  • the pH of 4 of the gel may assure that the products are primarily hypochlorous acid.
  • the gel continues to supply the precise quantity of hypochlorous acid embedded in the gel. Thirty minutes after the electric activation of the pad has stopped, the hypochlorous acid continues to penetrate the methyl sample. However the amount delivered may be precise.
  • experiments employed a large 6" ( 153 mm) Petri dish. A hole with a diameter of 3.5" (88 mm) was cut through the back of the Petri dish, to allow access to the precision electrolysis pad and to negative controls. The precision electrolysis pad was placed inside the hole, in this design the cathode side was covered with an impermeable coating. The two electrodes of the pad were connected to an Agilent E3631 A constant current power supply.
  • a positive control was also prepared.
  • the Petri dish had a 5 mm high agar gel as described earlier.
  • a thin layer of E. Coli ATCC 55244 was spread on the top of the gel, on the surface opposite to the surface in contact with the bottom surface of the Petri dish.
  • the control was left outside on the bench at room temperature for 50 minutes, similar to the protocols in which active sterilization was attempted. It was then piaced overnight, for 1 hours, in an incubator at 37 C.
  • Electrolysi was generated by passing a voltage of 4 Volts (approximate current was 50-60nulliA.raps) through the electrodes for 20 minutes. Then the electrolysis pad was left i situ for 30 more minutes. Following the experiments all plates were collected and placed in an incubator overnight, for .18 hours at 37C, A region in which there was no E. Coli growth formed in relation to the hole at the bottom of the Petri dish, where the electrolysis pad was present. It was evident that the sterilization of the bacteria occurred within the outline of the anode on the pad. The pad was placed on the back side of surface contaminated with E. Coli. The distance between the pad and the contaminated surface was 5 mm. This suggests the electrolysis pad ma have the ability to sterilize deep irt the body.
  • a second negative control stud was performed with a. commercial product that employs a silver ion dressing, Allevyn,
  • the Allevyn pad was placed on the surface of the gel facing the hole, as with the other experiments.
  • the pad was applied according to the rrjanufaeiiirer instructions.
  • the Allevyn pad was kept in place for 50 minutes, after which the plates were collected and placed in an incubator for 18 hours at 37 C.
  • the part of the gel facing the hole was completely covered wi th E. Coli growth.
  • Figure 10 illustrates a precision electrolysis pad 900 in accordance with an embodiment of the invention.
  • the precision electrolysis pad may include all the elements in. the same device.
  • the precision electrolysis pad 900 may be provided in a container that i sealed and keeps the precision electrolysis pad 900 sterile until opened for use.
  • the container may be a vacuum sealed bag or other suitable container.
  • FIG. 10 is a view of the pad 900 from the side that may come into contact with a wound.
  • the two-electrode unit 90S similar to electrode 400 in Figure , is shown with the anode surface visible, the anode surface may be similar to anode 10 in Figure 4. All the components are on plane 910, embedded between two gel cylinders 915, 920.
  • the gel cylinders 915, 920 may be made of agar gel or a hydrogel or any type of material that includes a saline solution and a pH buffer.
  • the pH buffer may maintain a pH of between 2 and 6, preferably between 3 and 5, preferably 4,
  • the gel may be l.Sgrams UltraPure Agarose (Jnvitrogen Cat No.
  • each gel cylinder 915, 920 may be 2 inches (53mm) and the ihicknessmay be 0.23 inches (6mm).
  • the electronic components of the device may be assembled on a solid surface 925.
  • the solid surface 925 may be connected to the electrodes 905 through electrical connections 930.
  • a programmable microprocessor 935 may turn on and off the electric current may be mounted to the solid surface 925.
  • the programmable microprocessor 935 may be a Bluetooth device that may be controlled from the exterior or a programmable chip or a simple on/off switch, in some embodiments, precision electrolysis electrodes 905 may be a separate unit or an integrated unit as shown in Figure 9,
  • the power supplied to the electrodes may come from a stationary power source or from a portable power source that may also be another pad connected to the electrodes 905 by an electric wire.
  • the power supply may be a battery.
  • a battery (not shown) may be mounted to the opposite side of the solid surface 925.
  • the battery may be a 3 Volt Lithium battery (Cr2032).
  • the precision electrolysis concept may be implemented with other designs as well.
  • the electrolytic process may be performed at the treatment site and precision raay be accomplished through placement of the electrodes at the desired location, control over the pH environment, and active control of the passage of current to generate the desired electrolysis products at the site.
  • a Petri dish was filled with a physiological solution based agar gel with anamycin.
  • an antibiotic resistant E. Coli strain ATCC Product No. 55244
  • the sterilization was performed using a physiological saline gel pad with a pH of 4 designed composition simitar to that in the previous experiments.
  • the electrodes were two 0.7 mm diameter cylindrical electrodes made of carbon inserted vertical into the pad and not along the pad as previously described.
  • the gel pad sterilization was activated with input from a constant voltage power supply connected to the two electrodes
  • First die gel pad was applied on a contaminated surface of the Petri dish for one minute without activating the electrodes. The pad was then removed and transferred the dish to an incubator for 36 hours in conditions most amenable for bacteria growth, at 37 C. The dish was then removed, in the second experiment the gel pad was applied as in the first experiment, but the gel was activated at specific predetermined areas with two carbon electrodes, for a one minute activation of 20 V. The gel pad was then removed and the samples placed in the incubator for 36 hours.
  • the gel pad was infused with pH sensitive dye.
  • the activated area was shown through a change of color in the pad, a a function of the change in pH.
  • a yellowish original color of the pad indicated a pH of 4.
  • the color of the activaied part of the pad changed, according to the change in pH, This aspect of the gel pad may allow the users to know immediately if the electrolysis activation is successful or not and the site of activation.
  • the cells may be sonoporated, eiectroporated, or chemically permeabiized.
  • the same electrodes used tor electrolysis may also be used for elcetroporation in some embodiments.
  • the electrodes for elcetroporation and electrolysis are separate.
  • the permeabiiization of the cells may increase the diffusion of electrolysis products into the ceils.
  • the combination of therapies may increase the effectiveness of the electrolysis.

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Abstract

EExample apparatuses and systems are disclosed for providing controlled delivery of electrolysis products to a site which may be used for treatment of infection and ablation of undesirable cells and tissue. A system disclosed may include a power supply, two electrodes, an aqueous matrix that may close the electric circuit between the electrodes at the treated site, and a controller. The controller may control the electrical circuit to induce a direct current through the electrodes and an aqueous matrix to produce electrolysis products. The duration and magnitude of the charge applied may determine the dose of the products applied to the treatment site. The composition of the electrodes and the aqueous matrix may be chosen to produce desired products. An apparatus is disclosed that may be in the form of a pad for applying to a wound. An apparatus is disclosed that may be used for treating internal tissue.

Description

ί
METHODS, SYSTEMS, AND APPARATUSES FOR
DELIVERY OF ELECTROLYSIS PRODUCTS
CROSS -REFERENCE TO RELATED APPLICATIONS
fOOlj This application claims priority to provisional applications U.S. Serial No.
61/904,142 filed on November 14, 20.13, U.S. Serial No. 61/921 ,084 filed on December
27, 2013, and U.S. Serial No. 61/938,623 filed on February 1 1, 2014.
f 002] The entire disclosures of the afore-mentioned -applications are considered to be pan of die disclosure of the instant application and are hereby incorporated by reference in their entirety for any purpose.
BACKGROUND
1003] Electrolysis generally refers to a process of inducing an electrochemical reaction that involves passing a direct current through an ionic solution via electrodes. Electrolysis may facilitate the removal and/or addition of electrons from atoms and/or ions, which may lead to the formation of new products. For example, by passing a DC current through a saline solution (NaG and Η:?0), hypochiorous acid (HCIO) may be formed.
|004] Hypochiorous acid has disinfecting properties and is often used as a cleaning agent. In. some applications, Iiypociilorous acid is used to ablate unwanted tissue and/or disinfect wounds in tissue. Hypochiorous acid is typically introduced to the wound by pouring a solution of hypochiorous acid over the wound or soaking a wound dressing in hypochiorous acid and applying the dressing to the wound.
|005j When exposed to air. hypochiorous acid decomposes over time. As the acid breaks down, the disinfecting and ablation properties are decreased. To maintain effectiveness, fresh hypochiorous acid is poured over the wound and/or the soaked gauze is replaced at multiple intervals. The labor intensive nature of continuing!}' treating wounds to ensure effectiveness of disinfection as well as the lack of precision in delivering the hypochiorous acid may make this mode of use of hypochiorous acid impractical in emergency and clinical environments. SUMMARY
Wkj{ Aii example apparatus for delivery of electrolysis products to a site according to as embodiment of the disclosure ma include an electrode, an aqueous matrix in contact with the electrode, wherein the aqueous .matrix, may include a saline solution, wherein the electrode may include a materia! and the aqueous matrix may have a H, the material and the pH may be selected to produce the electrolysis products when a current is passed through the aqueous matrix using the electrode, and wherein the electrode and the aqueous matrix, may be packaged for placement proximate the site.
[007] An example system for delivery of electrolysis products to a site may include a device which may he positioned proximate the site, wherein the device may include an electrode and an aqueous matrix, a power supply, a controller which may be positioned at the site or remotely from the site, the controller may be in communication with the electrical circuit, and wherein the controller may be programmed to provide art electronic signal to the circuit for the electrode to produce the electrolysis products, wherein the electronic signal may be indicative of a dose of the electrolysis products and the timing of the production of the dose.
"008'j An example method for delivering electrolysis products to a site may include using a controller remote from the site, generating an electrical signal indicative of a timing and dose of the electrolysis products, providing the electrical signal to a device proximate the site, wherein the device is configured to generate the electrolysis products responsive to the electrical signal
BRIEF DESCRIPTION OF THE DRAWINGS
009] The foregoing and other features of the present disclosure will become more fully apparent from the following description and appended claims, taken in conjunction with the accompanying drawings. Understanding that these drawings depict onl several examples in accordance with the disclosure and are, therefore, not to be considered limiting of its scope, the disclosure will be described with additional specificity and detail through use of the accompanying drawings, in which
{O!OJ Fig i is schematic illustration of the electrical circuit according to an embodiment of the disclosure. FIG, 2 is a schematic illustration of an apparatus for deli very of electrolysis products to a site according to an embodiment of the disclosure.
|012f FIG. 3 is a schematic illustration of an arrangement of electrodes according to aa embodiment of the disclosure.
fO ] FIG. 4 is a schematic illustration of another arrangement of electrodes according to an embodiment of the disclosure.
f014] FIG. 5 is a schematic illustration of a system for producing electrolysis products for the treatment of surface of tissue according to an embodiment of the disclosure,
[015] FIG, 6 is a schematic illustration of an internal electrolysis apparatus according to an embodiment of the disclosure .
[01.6] FIG . 7 is a schematic illustration of an internal electrolysis apparatus according to an embodiment of the disclosure.
f0l7] FIG. S is a schematic illustration of an internal electrolysis apparatus according to an embodiment of the disclosure,
[018] FIG. 9 is a schematic illustration of an internal electrolysis apparatus according to an embodiment of the disclosure.
]0'19'f FIG . 10 is a schematic illustration of a pad in accordance with an embodiment of the disclosure.
DETAILED DESCRIPTION
{020] Certain detail are set forth below to provide a sufficient understanding o embodiments of the disclosure. However, it will be clear to one skilled in the art mat embodiments of the disclosure may be practiced without these particular details. Moreover, the particular embodiments of the present disclosure described herein are provided by way of example and should not be used to limit the scope of the invention to these particular embodiments. In other instances, well-known materials, components, processes, controller components, software, circuitry, timing diagrams, and/or anatomy have not been described or shown in detail in order to avoid unnecessarily obscuring the embodiments.
]'021'f In some embodiments, electrolysis products, such as hypoch!orous acid, may be used for disinfecting and/or ablation. The products may be produced and delivered in a controlled manner to maintain effectiveness. In some embodhnents, a system and/or apparatus ma include a solution capable of producing, upon electrolysis, sterilizing products. The solution may be brought into contact with the tissue to be treated. Electrodes capable of producing electrolysis ma be brought into contact with the solution, and as electric current may be generated in the solution that produces the desired levels of electrolysis products. The magnitude and duration of the current generated may be controlled to modulate the amount of products produced.
{022 j Fig 1 is a schematic illustration of the electrical circuit 1000 which may be used to deliver electrolysis products according to an embodiment of the disclosure. The electrical circuit may include a power supply .1005, two or more electrodes 1010, .1 15 coupled to the power suppl 1005, and a control system 1020 that may regulate the current and/or voltage through the circuit 1000 or portions thereof. The electrical circuit 1000 may be closed at least in part through an aqueous matrix .1 25. The design of the circuit ma be such that the current is forced to pass at least in part through the aqueous matrix. 1025, The aqueous matrix 1025 may include a maumade materia], a biological material, or a combination thereof. The aqueous matrix 1025 may be at a treatment site in direct contact or part of the treatment site. The aqueous matrix 1025 may be the site at which products of electrolysis are generated. The controller 1020 may turn on and of the power to the circuit 1000, may adjust the level of power delivered, and may operate the circuit 1000 in conjunction with other devices. Optionally, the controller 1020 may receive feedback from measurements made in the aqueous matrix 1025 by a sensor 1030. The controller 1020 may also optionally receive signals from an external controller 1035.
|023J Figure 2 is a schematic illustration of an apparatus for delivery of electrolysis products to a site according to an embodiment of the disclosure. The apparatus 200 may include at least one electrode and an aqueous matrix in contract with the electrode. Generally, the electrode and the aqueous matrix may be selected such that electrolysis products are produced in the aqueous matrix when a current is passed through the aqueous matrix using the electrode. The aqueous matrix may include a raanmade material such as a hydrogel and/or a biological material such as tissue. The electrode and aqueous matrix may be packaged for placement proximate the site to which delivery of electrolysis products is desired. In Figure 2, an electrode 210 and aqueous matrix 225 are shown packaged in a pad 200. {024j At least one electrode may be included in the apparatus. The electrode 210 is shown in Figure 2, and may be a cathode in some embodimesrts. la some examples, however, the electrode 210 may be placed at a location remote from die apparatus, such as proximate another location of a patient's body in some examples. A second electrode ma be included in the apparatus, such as the electrode 220 shown in Figure 2. in some examples, the electrode 220 may be an anode,
{025 j Electrode materials arc generally selected to include a material that is selected to produce the electrolysis products when a current is passed through the aqueous matrix using th electrode. The materials chosen for the electrodes, including the electrodes 210, 220, may be chosen to produce certain the electrolysis products. For example, an anode (e.g. electrode 220) may include iridium oxide and/or rubidium oxide deposited on titanium, which may improve the production of hypoehlorous acid, and a cathode (e.g. electrode 210) ma include copper. The use of mixed metal oxide anode electrodes may produce different species of electrolytic products that may be tailored for different clinical needs. The electrodes may also include different materials with properties of interest. For example, platinum may be used if inert electrodes are desired or silver elecirodes or silver/silver chloride electrodes if silver ions are desired in the solution, which may furthe enhance the sterilization effect.
|β26| to the example shown in Figure 2, the electrodes 210 and 220 are separated by art insulating layer 215, The insulating layer 15 may be implemented using any suitable insulating material. In some embodiments, the insulating layer 215 between the electrodes 210, 220 may be omitted. I some embodiments, a portion of the aqueous matrix 225 is between the electrodes 210, 220. In some embodiments, a portion of the aqueous matrix 225 is between the electrode 210 and the impermeable barrier 205,
[027] One or more of the electrodes in the apparatus, such as the electrodes 10 and/or 220 may be externally-accessible for receipt of an electronic signal from a controller, which may be placed remotel from the apparatus, such as the apparatus 200. In some embodiments, the controller may be integrated with apparatus 200.
[028] Apparatuses described herein, may include an aqueous matrix in contract with at least one electrode. The aqueous matrix 225 is shown in Figure 2 in contact with both the electrodes 21 , 220, Aqueous matrices described herein, including the aqueous matrix 225, may include components for forming electrolysis products. In some embodiments, the aqueous matrix 225 may be implemented using a gel and/or hydrogel. The aqueous matrix may include a saline solution. The aqueous matrix may have a pH selected to produce electrolysis products, such as hypochlorous acid, la some examples, the pH of the aqueous matrix 225 may range between 2 and 5. The aqueous matrix 225 may be placed hi contact with a site for delivery of electrolysis products, such as by laying a pad including the aqueous matrix 225 on the site,
{029] in some embodiments, the aqueous matrix 225 may include a low pH saline solution (e.g. about 3 t 4 pH) that is configured for the production of hypochlorous acid. The materials included in the solution included in the aqueous matrix 225 may be chosen to produce the desired electrolysis products, such as hypochlorous acid). In some embodiments, the aqueous matrix 225 ma have a higher electrical conductivity than the site for delivery of electrolysis products. The higher electrical conductivity of the aqueous matrix 225 may result in electrolysis products produced primarily in the aqueous matrix 225, not the tissue at the site. The ionic composition of the aqueous matrix 225 may he designed to have the desired conductivity but to include different ions from those normally in tissue, for example a greater concentration of Na or Ca. In some embodiments, the aqueous matrix 225 may be infused with a drug for combination therapy at the treatment site. That is, both the drug and electrolysis products are delivered to the treatment site.
{030] In some embodiments, aqueous matrices described herein, such as the aqueous matrix 225, may be implemented using a liquid solution. The liquid solution may be prepared separately and applied directly to the treatment site before placement of the impermeable barrier 205. In some embodiments, the treatment pad 200 may be placed at the treatment site and the aqueous matrix 225 may be introduced to the treatment si te by injecting it through a port (not shown. in the impermeable barrier 205. In some embodiments, the treatment pad 200 includes a dehydrated gel. Before use, the gel may be hydrated with a solution, such as saline, to form: the aqueous matrix 225. In some embodiments, the aqueous matrix 225 is already present in the treatment pad 200. In some embodiments the aqueous matrix is combined with body tissue and/or body fluids. 1 3 i In some embodiments, the a least one electrode in the apparatus ma be coupled to a power supply . For example, the electrodes 21 , 220 in Figure 1 may be coupled to a power supply (not shown}. Examples of power supplies may include, but are not limited to, one or more batteries, a computer {e.g., coupled via USB cable), a cellular phone, a regulated power suppl that draws energy from the electrical network, a solar cell, and combination thereof. The power supply may be incorporated in the apparatus, e.g. the treatment ad 200, The power supply generally provides power to one or more electrodes to power the electrolysis process.
[032J The electrode and aqueous matrix may he packaged for placement proximate a site of deli very for the electrolysis products. For example, the electrode and aqueous matrix may be packaged into the pad 200 shown in Figure 2, In some embodiments, some or all of the components of the pad 200 are disposable, hi some embodiments, some or all of the components of the pad 200 are steri zahle. hi some embodiments, some or ail of die components of the pad 200 ma be multi-use,
|033] in some embodiments, the pad 200 is sized to cover a large area of a site, in some embodiments, the pad 200 may have smaller dimensions to limit deliver}' of electrolysis products to a smaller area. The pad 200 may be implemented in a variety of shapes. For example, the pad 200 may be square, rectangular, circular, ovular, half- moon.. Other shapes may also be possible. The shape and/or size of the pad 200 may be selected based on the size and/or shape of the site for delivery.
{03 j The pad 200 may include an impermeable barrier 205 which may include a periphery (not shown) that may extend beyond the dimensions of the electrodes 210, 220 and/or aqueous matrix 225. The periphery of the impermeable barrier 205 may include an adhesive that ma be used to secure the pad 200 to the site, i some embodiments, the pad 200 is secured by bandages. In some embodiments, the pad 200 is not secured to the treatment site.
{035] While shown packaged as a pad 200 in Figure 2, a pad may not be used in some examples. In some embodiments, an aqueous matrix may be applied to a site and electrodes applied to the aqueous matrix. For example, it may be desired to treat, a confined space between two tissues or inside of one tissue {e.g., a needle hole). The aqueous matrix may be introduced into the confined space, and the electrodes may be inserted into or proximate the confined space. The electrodes may be coupled to a controller arid/or Sow voltage source outside the confined space.
[036] in some examples, ablation by electrolysis may be performed in the interior of a blood vessel or a cavity inside the body. In some embodiments, electrodes ma touch a tissue of interest and an ionic flow that propagates by diffusion may be directed towards the tissue of interest. In some embodiments, the flow of ion in an undesirable direction may be impeded by impermeable surfaces, in some embodiments, the direction: of flow of ions may be controlled through the use of iontophoresis, electro osmosis and/or electrophoresis.
Θ37] Example site include wounds. Examples of wounds that may be treated include but are not limited to bed sores, diabetic ulcers, burns, tears, gashes, surgical incisions, cuts, scrapes, irradiation and scars formation. The pad 200 ma accordingly be configured to adhere to the wound. in some embodiments, the apparatuses described herein, such as pad 200, .may be used for cosmetic procedures. For example, unwanted cosmetic features may be ablated or the electrolysis products may induce tightening of the skin. Example sites include infected tissue, acne, and/or the pad may be configured for placement on an implantable de vice (e.g. pacemaker, joint implant, or other medical device). When activated, the pad can then be used to treat an infection proximate the implanted device.
038) Other example sites for delivery of electrolysis products include a malignant tumor, an abdomen surface, a nerve, a benign tumor, a blood vessel surface, an intestinal surface, an esophagus surface, a urethra surface, a bladder surface, or combinations thereof
[039] Example apparatuses described herein , such as the pad 200 of Figure 2, may be packaged tor placement proximate a site for delivery of electrolysis products, in this manner, the device may be placed locally to the site for delivery such that the electrolysis products generated by the apparatus ma diffuse into and/or be driven toward the site. For example, during operation, the electrodes 210,220 shown in Figure 2 may be coupled to a power supply, such as a battery. While the pad 200 is applied to the site, the electrodes 210,220 may be energized by power supply, and electrolysis products are formed in the aqueous matrix 225. The electrolysis products may diffuse Into the site for an amount of time, A controller (not shown in Figure 2) may control the coupling of the electrodes 210, 220 to the power supply. The controller may modulate the connection between the electrodes '210, 220 to the power supply to turn on and off current in the aqueous matri 225, thereby controlling generation of electro lysis products .
f040j In some embodiments, the electrolytic reaction induces a flow of material through the aqueous matrix 225. The flow ma extend further into the treatment site. The iontophorctie, eiectro-osmoiic and/or eieetrophoretic flow may enhance transport of the electrolysis products into the treatment site. This may allow deeper tissue to be treated by the treatment a 200. In some embodiments, a negative pressure source (not shown) may be used in conjunction with the treatment pad 200 and may be applied to the tissue treated by the treatment pad 200. The negative pressure source may be a tube coupled to a vacuum, a hypobanc compartment, or a maiiual suction bulb. Other negative pressure sources may be used. The negative pressure source may urther enhance production of the electrolysis products at the treatment site and/or remove depleted products and/or ablated materials. In some embodiments, the negative pressure source is manually operated by a user. In some embodiments, the negative pressure source is operated by the controller.
[041 Figure 3 is a schematic illustration of an alternative arrangement of electrodes 300 according to an embodiment of the disclosure. In this arrangement, electrodes 305, 310 may be formed in the same horizontal plane and may he separated by an aqueous matrix 315, In some embodiments, the aqueous matrix 315 may he replaced by a nonconducting film on. which the electrodes 305, 315 are sputtered. The film may be embedded in or placed on or in an aqueous matrix .
[042 J Figure 4 is a schematic illustration of an alternative arrangement of electrodes 400 according to an embodiment of the disclosure. In this arrangement, an anode 10 is disk-shaped and mounted to a disk-shape cathode 405. As shown in Figure 4, the cathode 405 has a diameter greater than the diameter of the anode 410, however, in some embodiments, the anode 410 may have a diameter greater than the cathode 405. The cathode 405 and anode 410 may have an insulation layer coupled between them (not shown) in some embodiments. In some embodiments, the electrodes 400 are embedded in or placed on an aqueous matrix. | 43] Figures 1 -4 show various electrode configurations for performing electrolysis.
However, these configurations are exemplary, and the disclosure is not limited to these particular electrode configurations and additional electrode configurations may be used. For example, needle electrodes, wire electrodes, and or surface electrodes may be used. Needle electrodes may, for example, penetrate a tissue to which electrolysis products may be delivered. Surface electrodes may be placed on or near a surface of a tissue to which electrolysis products may be delivered. For example, surface pad electrodes may be used where electrodes are packaged in a pad which is placed proximate (e.g. on) tissue to be treated.
[Θ44| Figure 5 is a schematic illustration of a system 100 for producing electrolysis products (e.g. electrolytic product), which may be used to deliver electrolysis products to a site, for example for the treatment of a tissue surface according to an embodiment of the disclosure. A pad 105, which may be implemented using the pad 200 of Figure 2, may be proximate a site that is to be treated (e.g. tissue 10). The pad may be coupied to a power supply 1 15. An electrical circuit may be implemented through the pad and/or tissue using the circuit in Figure 1 in some examples. The production and delivery of electrolysis products to the tissue 1 b the pad 105 ma be controlled by a controller 1 10. The controller 1 10 may, for example, be programmed to provide an electronic signal to the pad 105 and/or power supply 1 1.5. The electronic signal may be indicative of a dose of electrolysis products. For example, the electronic signal may control the timing and magnitude of a current generated in the pad 105 to produce electrolysis products. This may allow a user to customize treatment of the tissue 10. For example, the controller 1 .1 may transmit an electronic signal to the pad 105 and/or the power supply 1 15 to cause the pad 105 to produce a particular flow (e.g. constant flow) of electrolysis products to the tissue 1 . In this manner, a controller may be used to electronically control the generation and application of electrolysis products to a site, where the site is proximal an example pad as described herein. Although shown as separate components coupled to the treatment pad 105, in some embodiments, the controller 1 .10 and/ or the power supply 1.15 may be integrated into the treatment pad 1 5. In some embodiments, the controller 1 .10 may include a programmable chip coupled to the treatment pad 105 and/or power supply 1 15. In some embodiments, the controller 1 10 ma be implemented using a computing device (not shown) and be remotely coupled to the treatment pad 105, The computing device may be implemented using, for example a desktop, laptop, server, handheld device, a personal computer, a tablet computer, and/or a smart phone. In some examples, the computing device may be integrated with and/or shared with another piece of medical equipment, such as an injection pump, a negative pressure system, or combinations thereof. In some examples, the controller may be programmed to provide an electronic signal indicative of electrolysis product dose and also control the other piece of medical equipment. The controller 1 1.0 may be coupled by a wire or communicate with the treatment pad 105 and/or the power supply 115 wireSessiy.
[Θ45| The controller may be programmed to provide an electronic signal indicative of a dose of the electrolysis products to an electrode described herein. The controller raay, for example, include such a program, or include one or more processing devices (e.g. processors) coupled to a memory encoded with executable instructions for electrolysis product delivery. The controller may cause the current through the electrodes to be pulsed. Other modulation patterns may also be used. The controller may also control the voltage of the power supply in some embodiments. Treatment dosage may also be adjusted by the magnitude of the current applied and duration of energy applied to the aqueous matrix of apparatuses described herein. In some examples, length and/or magnitude of the electronic signal may further indicate a desired depth of the electrolysis product delivery. Generally, a longer application of a current ma cause electrolysis produets to be produced for a longer time, allowing them to diffuse deeper into the site,
1046] The system 1 0 may further include a sensor (not shown) tor measurement of pH near at least one electrode in the apparatus for delivery of electrolysis produets, such as the pad 105. The sensor may sense pH near the electrode and provide the pH value to the controller, such as the controller 1 10. The controller 1 1.0 may further be programmed to adjust an electronic signal provided to the pad 105 and/or power supply 1 15 based on the pl:l near the electrode. If the pH varies outside of a predetermined range, additional components may be added to the aqueous matrix to adjust the pH to return it to a range desired for producing the electrolysis products.
[947] Figure 6 is a schematic illustration of art internal electrolysis apparatus according to an embodiment of the disclosure. A balloon catheter 500 may include an electrode 505 deposited or attached to aft outer balloon surface 510, The catheter 500 may include a rauhi lumen shaft 5.15 thai may allow for inlltatioa'deflaiioti of the balloon 51 , and one or more electrodes 505 to be coupled via conductors to a power source and/or controller, ϊη some embodiments, the multi-lumen shaft 15 may include one or more fluid transfer iumens 520. in some embodiments the balloon catheter 500 may be inserted or in contact with an aqueous matrix 530 around the electrode 505. The aqueous matrix 530 may include a manmade material, a biological material, or a combination thereof. In some embodiments one or more electrodes may be a remote needle or pad 525„ inserted o in contact with a tissue or with the aqueous .matrix 530. The aqueous matrix ma include a mammae material, a biological material or a combination thereof In some embodiments, the fluid transfer himen 520 may deliver and/or remove fluid substances proximate the electrodes 505. For example, a fluid transfer lumen 520 may deliver a saline solution to the electrodes 505 which may increase the production of hypoehSorous acid proximate the target site, in some embodiments, the fluid transfer lumen 520 may remove depleted solution, degraded electrolysis products, and/or ablated tissue from the target site. The addition and/or removal of fluids from the target site may allow for -adjustments to the properties of the solution such as H, ionic composition, -and/or dosage. In some embodiments, the removed fluids may be collected and analyzed. For example, the pH of the removed solution may be determined. The pH of the removed solution may determine the composition of new solution delivered to the target site, in another example, the solution may be analyzed for the presence of living microorganisms to determine the effectiveness of a sterilization procedure. Other analysis of the removed solution may also be performed.
I In some embodiments, the balloon 510 may prevent the flow of ions from the aqueous matrix 530 in an. undesirable direction. This may allow for diffusion of electrolysis products from the aqueous matrix 530 into a vessel wall or other target tissue, causing ablation on the targeted region, hi some embodiments, multiple balloons 510 may be included in the catheter 500. The balloons 510 may isolate a target tissue for treatment, which may allow for controlled diffusion of electrolysis products from the aqueous matrix 530 into the target tissue, in some embodiments, the balloon. 510 may be ring-shaped. That is, the balloon. 510 may include a channel near the middle portion which may allow at least partial flow of fluid through the 'balloon 510. This may allow the electrodes 505 to contact the target site for electrolysis, but allow for blood flow and/or other fluid How during treatment
l'049'l In some embodiments, the electrode 505 may be deposited on rite multi-lumen shaft 515 in addition to on the balloon 51 . In some embodiments, the electrode 505 may be deposited on the raulti-hrmen shaft 515 instead of on the balloon 510. The electrode 505 may be deposited on the mulH-lumen shaft 515 upstream and or downstream from the balloon 510. In. some embodiments, whe two balloons 510 are included in the catheter 500, the electrode 505 may be deposited on the multi-Jumen shaft 515 between the two balloons 510. Other electrode 505 locations may be used.
I'OSO'j Figure 7 is a schematic illustration of another internal electrolysis apparatus 600 according to an embodiment of the disclosure. The apparatus may include a spring electrode 605 design with an impermeable surface 610 attached to the back of the electrodes 605. The spring electrode 605 with the impermeable surface 610 ma be embedded in an aqueous matrix 620. The aqueous matrix 620 may include a manmade materiai a biological materiai or a combination thereof. The impermeable surface 10 may allow for controlled diffusion of electrolysis products from the -aqueous matrix 620 into the target tissue. The spring electrodes 605 may be a variet of different shapes and polarities. In some embodiments, the center shaft 61.5 may incorporate one polarity while the outer spring electrodes 605 are the same polarity and opposite polarity of the center shaft 615. In some embodiments, the apparatus 600 may allow for the application of electrolysis without occluding a vessel duct, and/or passage.
|0S1| Figure 8 is a schematic illustration of another internal electrolysis apparatus 700 according to an embodiment of the disclosure. The apparatus 700 may include a stent 705 embedded in an aqueous matrix 715. The aqueous matrix 715 may include a raanmade material, a biological material, or a combination thereof. The stent 705 may have one or more configurations. In some embodiments, the stent 705 may act as an electrode. For example, a wire mesh stent may be used to deliver a low voltage direct current to the tissue. In sons, embodiments, inner wall of the stent 705 may be coated on one side with the aqueous matrix. 715 and on the other side with an impermeable surface which may direct diffusion of electrolysis products from the aqueous matrix 715 into a target site, such as a vessel wall. In some embodiments, the stent 705 may be a nitinoi stent thai may have the inner surface of the stent 705 coated in a similar fashion. The stent 705 m y be configured as cither a monopolar electrodes with a shaft 710 as a return, or with a remote second electrode as illustrated in Figure 6 in a bipolar configuration with both polarities built into the stent 705 but separated by a nonconducting surface, in some embodiments, the impermeable surface may act as a nonconductor to separate the two conducting surfaces on die stent 705.
] Figure 9 is a schematic illustration of another internal electrolysis apparatus 800 according to an embodiment of the disciosore. The apparatus 800 may include a solid insert 805 a portion of which is at least one electrode 810. hi some examples, the electrode 810 is an anode. The electrode 810. which may be an anode, may be surrounded by an aqueous matrix 820. The aqueous matrix 820 may include a manmade material, a biological material, or a combination thereof. In some examples, the insert 805 is a needle, A second electrode 15 may be positioned on the surface of the insert 805 and or in. an aqueous matrix surrounding the insert, l'a some embodiments, the one or more electrodes may be mounted on the outer surface of the insert. The outer surface of the insert 805 may be electrically insulated except for the surface area of the electrodes 810, 815. The apparatus 800 may be directly introduced to the treatment site under imaging (CT. MR, Ultrasound) guidance. An electrical circuit including at least two electrodes and the aqueous matrix 820 may be coupled to a power source (not shown). The power source may be outside the body or inside the body. The power source may be a battery. The power source may be a constant DC current power supply. The treatmeat may be controlled by a microprocessor (not shown) to determine and deliver dose specific treatment parameters to the targeted treatment site, A treatment planning system ma he used to calculate optimal treatment zone placement over the targeted treatment area to guide placement of the insert electrode.
] The internal electrolysis apparatuses illustrated in Figures 6-9 ma include imaging components. This may allow real time monitoring of electrolysis treatment.] The internal electrolysis apparatuses described above may be used in multiple applications. Examples of applications include targeted lung denervation for chronic obstructive pulmonary disease, renal denervation, and carotid bod receptors for congesti ve heart failure. Another application ma in volve the use of a balloon catheter with electrodes a the treatment of percutaneous tens luminal coronary angioplasty (PTCA). tti this application, an apparatus, for example the apparatus 500, may be used for a traditional angioplasty procedure. The electrodes incorporated on the balloon surface may then be activated pre or post balloon dilation to treat the vessel walls through the production of hypoehlorous acid, which may reduce the rate of restenosis. The intraluminal electrolysis allows for treatment of the smooth muscle below the surface which may inhibit the formation of a neointima,
jOS5] in another application, for treatment of restenosis, art apparatus, such as the apparatus in Figure 8 may be applied to combine the use of a stent with the treatment of intraluminal electrolysis. In this approach, the stent may be placed by conventional means. Intraluminal electrolysis may be applied via the stent which may prohibit restenosis. The intraluminal electrolysis ma allow for treatment of the smooth muscle below the surface which may inhibit formation of a neointima.
|056j in another clinical application, intraluminal electrolysis may be used to treat
Deep Vein Thrombosis (DVT). An apparatus such as apparatus 500, may be used to combine a catheter based procedure with the treatment of transluminal electrolysis. In this approacii, the catheter may be positioned in a normal fashion to dilate the restricted vessel. Before or after dilation, intraluminal electrolysis may be applied, to produce hypoehlorous acid to treat the remaining clotted area as well as the surfaces belo the vessel wall which may pre vent recurrence. The low thermal aspects of the intraluminal electrolysis may make it particularly attractive for this type of application, because of the reduced or non-existent swelling of the tissue as a result of the thermal damage.
1057] In another application for the treatment of DVT, an apparatus, such as apparatus
700 ma be used to combine a stent with the treatment of the intraluminal electrolysis. In this approach, the stent may be place in a normal fashion. Intraluminal electrolysis may be applied via the stent in order to treat any remaining clotted area as well, as below the surface which may prevent recurrence.
f058j In another clinical application, intraluminal electrolysis may be used to treat Peripheral Artery Disease (PAD). An apparatus such as apparatus 500 may be used to combine a balloon catheter with intraluminal electrolysis, in this approach, the balloon may be placed by conventional means. Intraluminal electrolysis may be applied via the electrodes mounted on the balloon which may treat any remaining plaque as we l as the surfaces below the vessel wall which may prevent recurrence.
[059J In another application for PAD, an apparatus such as the apparatus 700 may be used to combine a stent with the treatment of intraluminal electrolysis. In this approach the stent may he placed in norma! fashion. Intraluminal electrolysis ma be applied via the stent to treat any remaining plaque as well as the surfaces below the vessel wail which may prevent recurrence.
{060] Addition clinical applications of intraluminal electrolysis may include ablation of malignant and benign cell growth on die inner surface of the esophagus (Barrett Syndrome), colon - tumors, rectal tumors, tumors in the mouth, opening of veins for treatment of varicose veins. Intraluminal electrolysis can be utilized inside the heart for ablation procedures that require full transmural lesions. The clinical applications discussed above are exemplaiy and should not be construed to limit the disclosure to the listed applications.
{061] Some specific experimental examples are provided below to facilitate appreciation of embodiments described herein. The experimental examples presented are not intended to be comprehensive or exhausti ve of all experiments performed or of ail results obtained.
|062| Example I
(063] In a first non-limiting e m le;, two electrodes of an electrolysis treatment system are configured similar to the electrodes in Figure 3, The anode is a L5-inch (39.4mm) diameter circle of Titanium, grade 2. It is .0005 inches (0.010mm) thick. The Ti was submersed In iridium chioride and then place in an oven at 450 C for 2 hours. The iridium chloride reacts with the oxygen at high temperatures and a layer of iridium oxide develops on the titanium and this serves as the anode in our system. An iridium oxide electrode was used here because it serves as a catalyst to the production of HC!O. There may be other materials that catalyze the production of RQO, such as Ruthenium Oxide.
{064] The larger circle with circumferential boles is made of Pyraiux (Dupont). It has an outer diameter of 2 inches (53mm) and a copper layer of 35mieron.s coated on one side with a high dielectric plastic of 45 micron. The copper surface serves as a cathode. Other materials can be used for cathodes such as Carbon, graphite, graphene, Ag/AgCl, The anode and cathode are attached across the plastic layer, which is used to electrically separate the anode from the cathode. Eight holes of a diameter of 0.085 inches {2.1mm) are equally spaced at a diameter of 0.2 inches (6.8mm) The holes serve aa important function, as a conduit for the transport of ions between the cathode and anode, which may be generally referred to as a salt bridge. A path for ion transport may be required for the system to function. Two strips extend from the anode and cathode for the purpose of connecting the electrodes to the power supply and the power delivery control system.
[Θ65| The electrodes are then embedded in a gel in the Petri dish. The gel is 0.7 gr. iJitraPitre Agarose (Invitrogen Cat No. 155510-027) dissolved in 100ml of distilled water. To maintain a pH of -- 4 , 590ml of 1 olar Citric Acid and 1 Oral of Sodium Citrat was introduced. To maintain a physiological saline composition, 9 gr of NaCl were mixed into the solution. The solution was cast in a 2" diameter, Petri dish that served as a moid, in such a. way that the electrode assembly was in the middle of the east. The thickness of the gel is 6 mm.
[066] Wires were coupled to the anode and. cathode of the electrode unit. The wires leaving the electrode unit are connected to an Agilent E363 lA constant current power supply. A top gel layer of a Methyl Violet (Fluka) dye infused agar gel, was set on top of the electrolysis gel in which the electrode unit was embedded to serve as a measurement: marker for the production of hypochlorous acid. The thickness of the measurement marker gel is 7mm and the diameter is 2 inch. Methyl Violet is denatured by hypochlorous acid and turns clear. As hypochlorous acid is produced at the anode and diffuses into the Methyl Violet dye gel layer, the gel becomes clear where the HCIO has interacted with the Methyl Violet. The bottom gel is a pH sensitive dye infused agar. The thickness of the gel is 7mm and the diameter is 2 inch (53mm). Whenever a basic or acid solution interacts with the dye a color change occurs. Hydroxides produced at the cathode, turn this gel into a blue color.
f067j A voltage of 4 V, (98 ÷/- 8 mA) was applied for 10 minutes across the electrodes. Knowing the time and the charge delivered, as well as the pH of the gel, allows a calculation of the amount of free chlorine produced by this system. In this case. It wa calculated that approximately 35mg of free chlorine was produced over the 10 min period. The ability to calculate the electrolysis products may facilitates a precise quantitative and temporal delivery of the disinfection species. Chlorine gas bubbles may form on the anode. These babbies may be trapped its the gel of the pad, between the anode and the gel. Because they are trapped and the chlorine produced species diffuse away into the treatment target, the amount produced during these 10 minutes of operation may be completely -utilized, which ma facilitate precise quantitative delivery of hypochlorous acid. In contrast, in systems that employ HCIO solutions in the form of a fluid open to the atmosphere, the active compounds can evaporate and dissipate. After 10 mm of activation, hypochlorous acid induced denaturation of the methyl violet dye at the interface between the electrolytic gel and the Methyl Violet stained gel The copper on the back oxidized, but continued to work. There was no leakage, and very little hydroxide was produced. To avoid this oxidation, the cathode could be made of other materials such as c arbon.
j Following 1 minutes of activation the current was stopped and the electrolytic- pad was allowed to remain in place for another 30 minutes. After 40 minutes of application, of which only 10 minutes were active, the penetration of HCIO and the discoloration is much larger that after the 10 minutes of activation. The gel pad may trap all the electrolysis products in the gel pad assenibiy. Afier 1 minutes activation ail the products are still in the gel The pH of 4 of the gel may assure that the products are primarily hypochlorous acid. The gel continues to supply the precise quantity of hypochlorous acid embedded in the gel. Thirty minutes after the electric activation of the pad has stopped, the hypochlorous acid continues to penetrate the methyl sample. However the amount delivered may be precise.
] There was little change in the pH dye gel facing the cathode. Except in some corners that may have been a result of leakage from the anode side. This indicates that this particular design favors the production of HCIO at the anode, facing the treatment site.
] Another experiment with the Methyl violet test pad with another design configuration. In this design configuration the gel pad with the electrodes was kept in the Petri disli, allowing only the anode side to be in contact with the test pad. The cathode side was in contact, with the Petri dish wall. In this experiment the electrodes wer activated for 20 minutes with a voltage of 4V and current of 1 18 mA, for a calculated total of 70 nig free chlorine. The treated pad became transparent The electrolysis device produced complete saturation of the treated pad, throughout the treated pad after 20 minutes of activation.
[0713 Example II
|072| In a second non-limiting example, experiments employed a large 6" ( 153 mm) Petri dish. A hole with a diameter of 3.5" (88 mm) was cut through the back of the Petri dish, to allow access to the precision electrolysis pad and to negative controls. The precision electrolysis pad was placed inside the hole, in this design the cathode side was covered with an impermeable coating. The two electrodes of the pad were connected to an Agilent E3631 A constant current power supply.
[Θ73| The large 6 inch. (153mm) Petri dish, was filled with physiological agar (Igram tryptone, 0.5g yeast, ,9g NaCi, ! .5g Agar per l O mL) to allow growth of E. Coli of an antibiotic resistant strain, ATCC 55244. The height of the gel, from the bottom of the Petri dish was 5 mm. The hole in the back of the Petri dish allowed contact with the active (anode) side of the electrolysis pad and to the negative controls of: a) Gauze saturated with Anasept (HCIO containing fluid), b) AHevyn - silver dressing, e) Proeellera wound pad (self-powered galvanic system generating Ag and Zu ions). The electrolysis pad anode side, was placed flush with the inner surface of the Petri dish, in good contact with the gel.
|074| A positive control was also prepared. The Petri dish had a 5 mm high agar gel as described earlier. As in all the experiments, a thin layer of E. Coli ATCC 55244 was spread on the top of the gel, on the surface opposite to the surface in contact with the bottom surface of the Petri dish. The control was left outside on the bench at room temperature for 50 minutes, similar to the protocols in which active sterilization was attempted. It was then piaced overnight, for 1 hours, in an incubator at 37 C.
[075J In the electrolysis experiments, the electrode pad was placed as described previously. As in all these experiments, a thin layer of E. Coli was spread on. the top agar plates surface. Electrolysi was generated by passing a voltage of 4 Volts (approximate current was 50-60nulliA.raps) through the electrodes for 20 minutes. Then the electrolysis pad was left i situ for 30 more minutes. Following the experiments all plates were collected and placed in an incubator overnight, for .18 hours at 37C, A region in which there was no E. Coli growth formed in relation to the hole at the bottom of the Petri dish, where the electrolysis pad was present. It was evident that the sterilization of the bacteria occurred within the outline of the anode on the pad. The pad was placed on the back side of surface contaminated with E. Coli. The distance between the pad and the contaminated surface was 5 mm. This suggests the electrolysis pad ma have the ability to sterilize deep irt the body.
f076 A first negative control study was performed by using in the same experimental configuration with a gauze saturated with a commercial HCIO product (Anasept). The pad was placed on the part of the gei with the hole, in a similar way to the placement of the precision electrolysis pad. The use was according to the manufacturer recommendations. Similar to the previous experiments, the E. Coli was spread on. tlie surface of the gei opposite the placement of the Anasept saturated gauze. The saturated gauze was kept in place for 50 minutes, after which the plates were collected and placed in an incubator for 18 hours at 37 C. Several large E. Coli colonies grew on the surface opposite the hole on which the gauze was placed.
{077 j A second negative control stud was performed with a. commercial product that employs a silver ion dressing, Allevyn, The Allevyn pad was placed on the surface of the gel facing the hole, as with the other experiments. The pad was applied according to the rrjanufaeiiirer instructions. The Allevyn pad was kept in place for 50 minutes, after which the plates were collected and placed in an incubator for 18 hours at 37 C. The part of the gel facing the hole was completely covered wi th E. Coli growth.
{078 j A third negative control study was performed with a commercial product that employs galvanic decomposition of Zn and Ag electrodes, Proceilera. The process here is driven, by the difference in electrochemical potential of Ag and Zn, and a galvanic, self powered, electrolytic reaction. The Proceilera pad was placed on the surface of the gel facing the hole, as with the other experiments. The Proceilera pad was applied according to the manufacturer instructions. The Proceilera padwas kept in place for 50 minutes, after which the plates were collected and placed in an incubator tor 18 hours at 37 C. The part of the gel facing the hole was completely covered with E. Coli growth.
{079J The above experiments demonstrate the function of the electrolytic pad and the advantage of this design over other sterilization configurations an systems, it is evident that while the electrolysis pad was able to sterilize antibiotic resistant E. Coli at a penetration of 5 mm from the applied surface, the three negative controls tested, using the manufacturer instructions, were unable io effectively destroy the microorganisms af a depth of 5 ram from the placement of the pads. This result illustrates a major problem with the current treatment of wound infections. It is evident that the current methods ma not sterilize bacterial infection in the wound depth. Sterilization on the wound surface - without penetrating die depth leaves open a possible source of contamination. The electrolysis technology may have the ability to sterilize deep into tissue, which could be particularly beneficial for deep infections,
|»8 ] Example Hi
1081] For a third non-limiting example. Figure 10 illustrates a precision electrolysis pad 900 in accordance with an embodiment of the invention. The precision electrolysis pad may include all the elements in. the same device. The precision electrolysis pad 900 may be provided in a container that i sealed and keeps the precision electrolysis pad 900 sterile until opened for use. The container may be a vacuum sealed bag or other suitable container.
|082 j Figure 10 is a view of the pad 900 from the side that may come into contact with a wound. The two-electrode unit 90S, similar to electrode 400 in Figure , is shown with the anode surface visible, the anode surface may be similar to anode 10 in Figure 4. All the components are on plane 910, embedded between two gel cylinders 915, 920. The gel cylinders 915, 920 may be made of agar gel or a hydrogel or any type of material that includes a saline solution and a pH buffer. The pH buffer may maintain a pH of between 2 and 6, preferably between 3 and 5, preferably 4, The gel may be l.Sgrams UltraPure Agarose (Jnvitrogen Cat No. 1555.10-027) dissolved in iOOral of distilled water. To maintain a pH of -- 4 , 590ml of .1 Molar Citric Acid and 410ml of Sodium Citrat may be used. Nine grams of NaCI were mixed into the solution to maintain salinity. The outer dimension of each gel cylinder 915, 920 may be 2 inches (53mm) and the ihicknessmay be 0.23 inches (6mm).
|083j The electronic components of the device may be assembled on a solid surface 925. The solid surface 925 may be connected to the electrodes 905 through electrical connections 930. A programmable microprocessor 935 may turn on and off the electric current may be mounted to the solid surface 925. The programmable microprocessor 935 may be a Bluetooth device that may be controlled from the exterior or a programmable chip or a simple on/off switch, in some embodiments, precision electrolysis electrodes 905 may be a separate unit or an integrated unit as shown in Figure 9, The power supplied to the electrodes may come from a stationary power source or from a portable power source that may also be another pad connected to the electrodes 905 by an electric wire. To verify that the unit is operational an LED 940 may be run in parallel with the connections 930. The power supply may be a battery. A battery (not shown) may be mounted to the opposite side of the solid surface 925. The battery may be a 3 Volt Lithium battery (Cr2032).
j084| Example IV
{085] The precision electrolysis concept may be implemented with other designs as well. The electrolytic process may be performed at the treatment site and precision raay be accomplished through placement of the electrodes at the desired location, control over the pH environment, and active control of the passage of current to generate the desired electrolysis products at the site.
086] in a fourth non-limiting example, a Petri dish was filled with a physiological solution based agar gel with anamycin. To contaminate the surface, an antibiotic resistant E. Coli strain (ATCC Product No. 55244) was used, which was spread evenly on the agar gel. The sterilization was performed using a physiological saline gel pad with a pH of 4 designed composition simitar to that in the previous experiments. .However, here the electrodes were two 0.7 mm diameter cylindrical electrodes made of carbon inserted vertical into the pad and not along the pad as previously described. The gel pad sterilization was activated with input from a constant voltage power supply connected to the two electrodes
108 . First die gel pad was applied on a contaminated surface of the Petri dish for one minute without activating the electrodes. The pad was then removed and transferred the dish to an incubator for 36 hours in conditions most amenable for bacteria growth, at 37 C. The dish was then removed, in the second experiment the gel pad was applied as in the first experiment, but the gel was activated at specific predetermined areas with two carbon electrodes, for a one minute activation of 20 V. The gel pad was then removed and the samples placed in the incubator for 36 hours.
[088] The gel pad was infused with pH sensitive dye. The activated area was shown through a change of color in the pad, a a function of the change in pH. A yellowish original color of the pad indicated a pH of 4. When electrolysis occurred, the color of the activaied part of the pad changed, according to the change in pH, This aspect of the gel pad may allow the users to know immediately if the electrolysis activation is successful or not and the site of activation.
089] After the one minute activation the gel pad was removed and the Petri dish incubated for 36 hours. After 36 hours the bacteria grew well across the entire petti dish. However, at areas in which gel pad was activated there was no spread of bac teria. This study may illustrate the feasibility of and the characteristics of a precision electrolysis active and controlled sterilization, gel pad. It illustrates different designs may be possible to accomplish the desired precision electrolysis.
09O| The examples provided are for explanatory purposes only and should not be considered to limit the scope of the disclosure.
091j The electrolysis apparatuses, devices, and systems described above and illustrated in Figures 1-9 may be used alone or in combination with other therapies. For example, precision electrolysis may be performed in conjunction with thermal ablation in some applications. In some applications, cells targeted for ablation may be permeabiized before, after, or during electrolysis. Examples of devices, pads and pernieabilmog techniques are described in co-pending PCX Application Serial No.
, filed November 14, 201 , entitled "METHODS, SYSTEMS, AND
APPARATUSES FOR TISSUE ABLATION USING ELECTROLYSIS AND PERMEABILIZATION/ ' which application is incorporated by reference herein in its entirety for any purpose.
092] The cells may be sonoporated, eiectroporated, or chemically permeabiized. In the case of electi poration, the same electrodes used tor electrolysis may also be used for elcetroporation in some embodiments. In some embodiments, the electrodes for elcetroporation and electrolysis are separate. The permeabiiization of the cells may increase the diffusion of electrolysis products into the ceils. The combination of therapies may increase the effectiveness of the electrolysis.
093j It is to be appreciated that any one of the above embodiments or processes may be combined with one or more other embodiments and/or processes or be separated and/or performed amongst separate devices or device portions in accordance with the present systems, devices and methods. Finally , the above-discussion is intended to be merely illustrative of the present devices, apparatuses, systems, and methods and should not be construed as limiting the appended claims to any particular embodiment or group of embodiments. Thus, while the present disclosure has been described in particular detail with reference to exemplary embodiments, it should also be appreciated that numerous modifications and alternative embodiments may be devised by those having ordinary skill in the art without departing from the broader and intended spirit and scope of the present disclosure as set forth in the claims that follow. Accordingly, the specification and drawings are to be regarded in. an illustrative maimer and are not intended to limit the scope of the appended claims.

Claims

What is claimed is; ί , An apparatus for delivery of electrolysis products to a site, the apparatus comprising:
an electrode;
a« aqiteous matrix in contact with the electrode, wherein the aqiieous matrix includes a saline solution;
whereiii the electrode comprises a material and the aqueous matrix has a pH, the material and the pH selected to produce the electrolysis products when a current is passed through the aqueous matrix, using the electrode; and
wherein the electrode and aqueous matrix are packaged for placement proximate the site.
2. The apparaiiis of claim 1 , wherein the aqueous matrix comprises a gel pad.
3. The apparatus of claim I, wherein the aqueous matrix has a pH between and including 3 and 5.
4. The apparatus of claim 3, wherein the aqueou s taatrix has a pH of 4.
5. The apparatus of claim 1 , further comprising a power supply coupled to the electrode.
6. The apparatus of claim 5, wherein the power supply, electrode, and aqiteous matrix are included in a circuit.
7. The apparatus of claim 1, wherein the circuit further includes a controller coop led to the power supply.
8. The apparatus of claim 1 , wherein the electrode is a first electrode, the apparatus further comprising a second electrode, atid wherein the electrolysis products are produced when the current is passed through the aqueous matrix using the first and second electrodes.
9. The apparatus of claim 1, wherein the electrode is a first electrode, and wherein the electrolysis products are produced when the current is passed through the aqueous matrix using the first electrode and a second electrode remote from the apparatus.
10. The apparatus of claim 1 , wherein the electrode is configured to receive an eiectronic signal from a controller, wherein the electronic signal is configured for control of at least one of the current or a voltage.
11. The apparatus of claim 10, wherein the controller is located remotely from the electrode.
12. The -apparatus of claim 10, wherein the controller is packaged with die electrode.
13. The apparatus of claim 1, wherein the site composes a tissue, and wherein the electrode and aqueous matrix are packaged in a pad configured to adhere to the tissue.
14. Tiie apparatus of claim 1 , wherein ihe site comprises tissue to be ablated, and wherein the electrode and aqueous matrix are packaged for placement on an implantable device.
15. The apparatus of claim 1, wherein the electrolysis products comprise hypoeh!orous acid and wherein die material comprises iridium oxide or rubidium oxide. ?,7
16. The apparatus of claim 1, wherein the electrode is a needle electrode.
17. The apparatus of claim I , wherein the electrode is included in a catheter,
18. The apparatus of claim 1 , wherein the electrode is a surface electrode,
19. A system for -delivery of electrolysis products to a site, the system comprising:
a device positioned proximate the site, wherein the device comprises an electrode and an aqueous matrix;
a power supply;
a controller, in electronic communication witfi the electrode; and wherein the controller is programmed to provide an electronic signal to produce the electrolysis products at the electrode, wherein the electronic signal is indicative of a dose of the electrolysis products.
20. The system of claim 1 , wtierei the electronic signal from the controller is further indicative of a time of delivery of the electrolysis products.
21. The system of claim 19, further comprising a negati ve pressure source positioned to remove fluids from proximate the device,
22. The system of claim 21, wherein the controller is further programmed to control the negative pressure source.
23. The system of claim 1 , further comprising sensor configured to measure pfl near the electrode.
24. The system of claim 19, wherein the controller is configured to wireless! y provide the electronic signal to the electrode.
25. The system of claim 19, wherein the site comprises a wound, and wherein th electrolysis products arc configured to sterilize the wound, the system further comprising a negative pressure device, irrigation system, fluid absorbing material, charged polymers, or combinations thereof
26. The system of claim 19, wherein the electronic signal comprises a waveform, wherein the waveform is indicative of a timing and dose of the electrolysis products to the site.
27. The system of claim 1 , wherein the electrode is a needle electrode.
28. The system of claim 19, wherein the electrode is a surface pad electrode.
29. The system of claim 1 , wherein the device includes a. catheter.
30. The system of claim 19, wherein the site comprises a tumor, an abdomen surface, a blood vessel surface, an intestinal surface, an esophagus surface, a "urethra surface, a bladder surface, a nerve, a heart surface or combinations thereof
31. The system of claim 1 , wherein the device is affixed to an implantable device comprising a pacemaker or joint implant.
32. A method for delivering electrolysis products to a site, the method comprising;
using a controller, generating an electrical signal indicative of a timing and dose of the electrolysis products;
providing the electrical signal to a device proximate the site, wherein the device is configured to generate the electrolysis products proximate the site responsive to the electrical signal.
33. The method of claim 32, wherein the device comprises at least one electrode and an aqueous matrix, wherein the electrolysis products are generated in the aqueous matrix responsive to the electrical signal applying a current through the aqueous matrix.
34. The method of claim 32, wherein the device comprises a pad, and wherein the method further comprises applying the pad to the site.
35. The method of claim 32, wherein the device comprises a pad, and wherein the method further comprises implanting the pad proximate the site,
36. The method of claim 32, whereiti the device comprises one of a surface pad, luminal catheter, or a needle.
37. The method of claim 32, wherein using the controller comprises accessing a. memory storing electrical signal patterns suitabie for particular doses arid depths of electrolysis product delivery.
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US20160296269A1 (en) 2016-10-13
US20220105256A1 (en) 2022-04-07

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