| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 121 | 플라즈마 시스템 | KR1020077010288 | 2005-11-03 | KR1020070095286A | 2007-09-28 | 오네일리암; 도빈피터; 스월로우프랭크; 리들리스튜어트 |
| A non-equilibrium atmospheric pressure plasma incorporating an atomised surface treatment agent is generated by applying a radio frequency high voltage to at least one electrode positioned within a dielectric housing while causing a process gas to flow from the inlet of the housing past the electrode to the outlet. The voltage applied is sufficiently high to generate a non-equilibrium atmospheric pressure plasma extending from the electrode at least to the outlet of the housing. The electrode may be combined with an atomiser for the surface treatment agent within the housing. The electrode may comprise a radioactive material. The surface to be treated can be positioned adjacent to the plasma outlet so that the surface is in contact with the plasma, and moved relative to the plasma outlet. | ||||||
| 122 | 플러그형 플라즈마 방전관 장치 | KR1020177020429 | 2015-01-12 | KR1020170105528A | 2017-09-19 | 왕서우궈 |
| 플러그형플라즈마방전관장치에있어서, 상기장치는, 상기장치는휴대용케이싱(100)과플러그방식으로연결되는플라즈마방전관을포함하고, 상기플라즈마방전관내에싱글전극(101)이설치되고, 그주변에다른전극이설치되어있지않고, 상기싱글전극(101)은플라즈마전원(107)의한 출력단에연결되고, 상기플라즈마전원(107)의다른한 출력단은그 자체선로의접지선에연결되고, 상기플라즈마전원(107)의입력단은 12V이하의직류전원또는배터리에연결되며, 상기플라즈마의발생방식은접촉식의관 외부감응방전방식이거나, 또는기체공급원이있는관 내자체적으로탑재된방전방식일수 있고. 상기플라즈마방전관은쿼시-글로의상압저온플라즈마를발생할수 있는, 플러그형플라즈마방전관장치이다. 발생되는플라즈마는민감한표면의소독, 피부조직감염치료및 암세포의소멸에사용될수 있다. | ||||||
| 123 | 암 예방 또는 치료용 액상 플라즈마 | KR1020150153582 | 2015-11-03 | KR101657063B1 | 2016-09-13 | 김철호; 김선용 |
| 본발명은암 예방또는치료용플라즈마를제조하는방법에관한것이다. 또한본 발명은상기플라즈마를처리하여제조되는암 예방또는치료용액상플라즈마및 이를포함하는암 예방또는치료용약학적조성물에관한것이다. 본발명의플라즈마및 액상플라즈마는외과적수술없이, 또는외과적수술후 처리과정에서암 세포의사멸을효과적으로유도할수 있으므로, 신규한암 치료제및 치료방법으로유용하게사용될수 있다. | ||||||
| 124 | 비열 플라즈마를 사용한 DNA 백신의 경피 전달 | KR1020167017383 | 2014-12-04 | KR1020160093658A | 2016-08-08 | 칼가티,사미르; 안토나카스,다프네,파파스; 차이,충-찬; 그레이,로버트,엘. |
| DNA 백신전달의예시적인시스템및 방법이본원에개시된다. DNA 백신전달의예시적인방법론은하나이상의세공을열기에충분한시간의기간동안처치영역에플라즈마를적용하기위한플라즈마발생기를제공하는것을포함한다. 처치영역에국소 DNA 백신을적용하는단계및 DNA 백신이하나이상의세공을통과하도록허용하는일정시간의기간동안대기하는단계. 예시적인방법론은 DNA 백신의세포내흡수를야기하기에충분한설정에서처치영역에플라즈마를적용하는것을더 포함한다. | ||||||
| 125 | 저압 플라즈마를 이용한 생체 조직 처리 장치 및 방법 | KR1020157016379 | 2013-10-21 | KR1020150118581A | 2015-10-22 | 스르프,조세프; 꼬로우스,조세프; 힌터코프,얀 |
| 본발명은, a) 고주파수전자기장을생성하는변압기(1); b) 변압기(1)에전기적으로연결될수 있는프로브(2); 및 c) 변압기(1)에의해생성된고주파수전자기장을제어하는제어장치(3) 를포함하는, 저압플라즈마를이용한생체조직(G) 처리장치에관한것으로, 정보장치가상기프로브(2)와관련되고, 정보장치를이용하여, e) 조직(G)에대한장치의전력출력의지속시간이측정되어시각적으로그리고/또는청각적으로표시될수 있고, 그리고/또는 f) 장치에의해상기조직(G)으로출력되는전류세기또는전력이측정가능하여, 미리정해진한계값을초과되면, 장치의전력공급이차단되고, 그리고/또는 g) 처리될조직(G)으로부터의프로브(2)의처리면의거리가측정되어시각적으로그리고/또는청각적으로표시될수 있다. | ||||||
| 126 | 플라즈마 시스템 | KR1020127005108 | 2005-11-03 | KR101212967B1 | 2012-12-18 | 오닐리암; 도빈피터; 카스태그나월터 |
| 표면을플라즈마처리하는공정에서, 비평형대기압플라즈마는유입구및 유출구를갖고있고공정기체가유입구로부터유출구로유동하는유전체하우징내에서생성된다. 적어도일부가유전체재료로형성된튜브는하우징의유출구로부터외부로연장되어, 튜브의말단이플라즈마유출구를형성한다. 처리될표면은플라즈마와접촉되도록플라즈마유출구에인접하게배치되어플라즈마유출구에따라이동된다. | ||||||
| 127 | 가스 화학종 발생 장치 | KR1020127015603 | 2010-11-11 | KR1020120101453A | 2012-09-13 | 홀베헤토마스빅포드 |
| 본 발명은 비열성 가스 플라즈마의 유동을 발생시키기 위한 장치(10)를 제공하며, 상기 플라즈마의 유동은 상기 장치로부터 방출되는 가스 플라즈마 구름 형태의 가스 플라즈마의 유동일 수 있다. 상기 장치는 압력 하에서 가스(14)를 보유하기 위한 가스 캡슐 또는 압력 용기(12)를 포함하며, 상기 가스 캡슐 또는 압력 용기(12)는 상기 가스 캡슐로부터 배출될 때 플라즈마 발생기(16)를 통해 애플리케이터(18)로 가스의 유동을 형성한다. 가스 캡슐로부터 배출되는 가스는 플라즈마 발생기에서 여기되어, 가스 플라즈마를 형성한다. 상기 장치는 플라즈마 발생기(16), 배터리(116), 및 플라즈마 발생기를 여기시키기 위한 신호 발생기(58)를 위한 하우징(28)을 갖는다. 가스 캡슐(12)은 하우징(28)과 도킹된다. 장치는 가스 캡슐(12)에 의해 일반적으로, 휴대되도록 구성되며, 예를 들어, 치아 세척 및 미백을 위해, 사용될 수 있도록 작동한다.
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| 128 | 플라즈마 시스템 | KR1020077010288 | 2005-11-03 | KR101157410B1 | 2012-06-21 | 오네일리암; 도빈피터; 스월로우프랭크; 리들리스튜어트 |
| 분무된 표면처리제가 혼입된 비평형 대기압 플라즈마는, 유전체 하우징 내부에 배치된 하나 이상의 전극에 고주파 고전압을 인가하면서, 프로세스 기체를 하우징의 유입구로부터 전극을 경유하여 배출구로 유동시킴으로써 생성된다. 상기 전압은, 전극으로부터 적어도 하우징의 배출구로 연장되는 비평형 대기압 플라즈마를 생성시킬 정도로 충분히 높다. 상기 전근은 하우징 내부의 표면처리제용 아토마이저와 조합될 수 있다. 상기 전극은 방사선 활성 물질을 포함할 수 있다. 처리될 표면은 플라즈마 배출구에 인접하게 배치되어, 표면이 플라즈마와 접촉하여 플라즈마 배출구를 향해 이동할 수 있다. 비평형 대기압 플라즈마, 아토마이저, 분무된 표면처리제, 고주파 고전압, 프로세스 기체. | ||||||
| 129 | 가스종을 발생시키기 위한 장치 | KR1020117023774 | 2010-03-09 | KR1020110136839A | 2011-12-21 | 로이드제프리모건; 디버리코맥존; 홀베헤토마스빅포드 |
| 본 발명은 장치(10)로서, 장치로부터 방출되는 가스 플라즈마 플룸의 형태의 가스 플라즈마의 유동일 수 있는 비-열 기체 화학종(24)을 발생시키기 위한 장치(10)를 제공한다. 장치는 가스 캡슐 또는 압력 용기를 포함하며, 가스 캡슐 또는 압력 용기는 가스 또는 가스들(14)을 압력 하에서 유지하고, 캡슐로부터 방출될 때 반응 발생기(16)를 통과해 어플리케이터(18)로의 가스의 유동을 형성한다. 가스 캡슐로부터 방출된 가스는 반응 발생기 내에서 에너자이징되어 가스 플라즈마를 형성한다. 장치는 핸드헬드형이도록 구성되며, 그것이 예를 들어 치아를 클리닝하고 미백화하기 위해 사용되게 하도록 작동된다.
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| 130 | 플라즈마 시스템 | KR1020077010259 | 2005-11-03 | KR1020070083998A | 2007-08-24 | 오닐리암; 도빈피터; 카스태그나월터 |
| In a process for plasma treating a surface, a non-equilibrium atmospheric pressure plasma is generated within a dielectric housing having an inlet and an outlet through which a process gas flows from the inlet to the outlet. A tube formed at least partly of dielectric material extends outwardly from the outlet of the housing, whereby the end of the tube forms the plasma outlet. The surface to be treated is positioned adjacent to the plasma outlet so that the surface is in contact with the plasma and is moved relative to the plasma outlet. | ||||||
| 131 | COLD PLASMA OZONE GENERATOR | US15766789 | 2016-10-06 | US20180297844A1 | 2018-10-18 | Yuval Rodan; Meir Badalov; Moty Vizel |
| The present invention provides a cold plasma ozone generator, comprising: an inlet gas port; at least one in-electrode, said in-electrode having a plurality of holes substantially at a perimeter of the same; said plurality of perimeter holes are in fluid communication with said inlet gas port, said plurality of perimeter holes configured to allow said dry gas to pass therethrough; at least one out-electrode, said out-electrode having at least one hole at the center of the same, said at least one hole configured to allow gas to pass therethrough; said in-electrode and said out-electrode configured to maintain said high voltage AC therebetween; at least one spacer between said in-electrode and said out-electrode, said spacer configured to maintain a constant-width gap between said in-electrode and said out-electrode; an outlet port. | ||||||
| 132 | Cold plasma treatment devices and associated methods | US15237252 | 2016-08-15 | US10039927B2 | 2018-08-07 | Gregory A. Watson; David J. Jacofsky |
| A cold plasma helmet application device for delivery of cold plasma benefits to the head of a patient. An appropriate gas is introduced into a helmet receptacle within a containment dome of the helmet. The gas is energized by one or more dielectric barrier devices that receive energy from a pulsed source. The dielectric barrier devices can be configured to match the treatment area. Such a device and method can be used to treat large surface areas treatment sites associated with the head, head trauma, brain cancer, the control of brain swelling with closed head injury or infection, as well as treating male pattern baldness. | ||||||
| 133 | PROCESS FOR ELECTRO-HYDRODYNAMICALLY ENHANCED DESTRUCTION OF CHEMICAL AIR CONTAMINANTS AND AIRBORNE INACTIVATION OF BIOLOGICAL AGENTS | US15572461 | 2016-05-06 | US20180117209A1 | 2018-05-03 | Herek L. CLACK; Krista R. WIGGINTON |
| A method and apparatus for electro-hydrodynamic destruction of an aerosol. The method includes receiving air having large aerosols, greater than about 1 micron, and small aerosols, smaller than about 1 micron, and entraining the large aerosols and small aerosols within an airflow. The airflow is directed to an electric field, which causes the large aerosols to react with the electric field to accumulate an electric charge resulting in extraction of the large aerosols from the airflow. The airflow is also directed to a non-thermal plasma such that the small aerosols remain entrained in the airflow and are subject to electro-hydrodynamic (EHD) phenomena. The non-thermal plasma outputs at least one of radicals, excited species, and ionized atoms and molecules capable of reacting with the small aerosols to result in physical and/or chemical destruction of the small aerosols. | ||||||
| 134 | PLASMA DEVICE WITH A REPLACEABLE (PLUG-IN) DISCHARGE TUBE | US15111094 | 2015-01-12 | US20170303381A1 | 2017-10-19 | Shou Guo WANG |
| This is a pluggable plasma discharge tube device having a replaceable discharge tube and a hand-held shell into which the replaceable discharge tube is plugged. There is a single electrode inside of the tube and no other electrodes outside. This electrode is connected to an output of a power supply and another output of the power supply is connected to a ground wire of its circuit. The input of the power supply is a 12V or lower, DC (direct current) source, or a battery. The plasma is generated via a contact-tube outside discharge, or a plasma jet from the tube, that uses working inert gas. The plasma discharge tube will produce atmospheric pressure, cold quasi-glow plasma, which can be used for sensitive surface disinfection, sterilization, as well as facial skin rejuvenation, treatment of skin tissue infections and destruction of cancer cells. | ||||||
| 135 | MICROWAVE PLASMA STERILISATION SYSTEM AND APPLICATORS THEREFOR | US15585911 | 2017-05-03 | US20170232122A1 | 2017-08-17 | Christopher Paul HANCOCK |
| A sterilization system having a controllable non-ironing microwave radiation source for providing microwave energy for combining with a gas to produce atmospheric low temperature plasma for sterilizing biological tissue surfaces or the like. A plasma generating region may be contained in a hand held plasma applicator. The system may include an impedance adjustor e.g. integrated in the plasma applicator arranged to set a plasma strike condition and plasma sustain condition. The gas and microwave energy may be transported to a plasma generating region along an integrated cable assembly. The integrated cable assembly may provide a two way gas flow arrangement to permit residual gas to be removed from the surface. Invasive surface plasma treatment is therefore possible. The plasma applicator may have multiple plasma emitters to produce a line or blanket of plasma. | ||||||
| 136 | PLASMA TREATMENT OF AN INFECTED NAIL OR INFECTED SKIN | US15500932 | 2015-08-04 | US20170216615A1 | 2017-08-03 | Nick Christopher Pledge; Thomas Bickford Holbeche |
| A non-thermal plasma for use in the treatment of an infected nail or infected skin. The plasma is used in the method by (a) applying the plasma to the infected nail or skin; (b) rehydrating the infected nail or skin; (c) applying the plasma to the infected nail or skin; and (d) optionally rehydrating the infected nail or skin. In each of steps (a) and (c) the plasma is applied to a portion of the nail or skin until a hydration level of the plasma-treated portion drops by at most 30 wt % based on the initial moisture content of the plasma-treated portion. | ||||||
| 137 | Harmonic cold plasma devices and associated methods | US14949469 | 2015-11-23 | US09656095B2 | 2017-05-23 | Gregory A. Watson; Robert M. Hummel; Marc C. Jacofsky; David J. Jacofsky |
| A nozzle for attachment to a cold plasma device configured to maintain delivery of a stable cold plasma. The nozzle can have many different shaped apertures to support different applications requiring different shaped cold plasma plumes. Use of a disc of foam material within a nozzle can expand the size of aperture of a nozzle while maintaining delivery of a stable cold plasma. The nozzle can be an elongated cannula tube for internal delivery of a cold plasma treatment. The cannula tube can provide an aperture at its distal end or one or more apertures along its length. A shroud can partially enclose the distal aperture of the nozzle. A sterile sleeve can be used in conjunction with a nozzle to provide a sterile means of attachment and operation of the nozzle with a cold plasma device. In addition, various shaped apertures may be deployed to provide selective targeting of the cold plasma to a treatment area, while shielding other biological structures from cold plasma exposure. Such apertures also provide an opportunity for manual manipulation of tissues in the treatment area prior to or during cold plasma treatment. | ||||||
| 138 | Method and Apparatus for Proximity Control in Cold Plasma Medical Devices | US15262790 | 2016-09-12 | US20170007845A1 | 2017-01-12 | Marc C. JACOFSKY; Michel H. YOON |
| Methods and apparatus are described that use an array of light sources that project converging light beams to control treatment distance. This approach controls treatment distance without contacting the patient or increasing the risk of pathogenic contamination. The approach can be used to control an optimal distance, and is compatible with various medical treatment devices including cold plasma treatment devices. | ||||||
| 139 | NON-THERMAL PLASMA | US15113054 | 2015-01-22 | US20170000546A1 | 2017-01-05 | Thomas Bickford Holbeche; Rodney Stewart Mason |
| A plasina-generation device for applying plasma to a human body, having a reservoir containing a gas, a plasma zone in fluid connection with the reservoir, and means for generating a plasma by electrical discharge in the plasma zone. The gas has a composition of 92% to 99.5% Helium and 0.5% to 8% Argon; or 95% to 99.5% Helium and 1% to 20% Neon; or 99.95% to 99.99% Helium and 0.01% to 0.05% Oxygen. | ||||||
| 140 | Cold plasma electroporation of medication and associated methods | US14145320 | 2013-12-31 | US09521736B2 | 2016-12-13 | Marc C. Jacofsky; David J. Jacofsky; Gregory A. Watson |
| A method and device to apply a cold plasma to a substance at a treatment surface of a patient to cause electroporation of the substance into cells of the patient. The substance can be previously applied to the treatment surface. Alternatively, the substance can be placed in a foam-like material within a tip that passes the cold plasma from the cold plasma device to the treatment area. The tip can be a cannula device with an aperture at the distal end. The cannula device can also have apertures along a portion of the length of the cannula device. | ||||||
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