| Patent application number | Description | Published |
|---|
| 20090087816 | Optical Therapeutic Treatment Device - Methods and devices for Live Biofilm Targeted Thermolysis (LBTT) are disclosed. The disclosed LBTT methods can be used for thermolysis and coagulation of the live periodontal Biofilm with incandescent light and a targeting agent as heat sink. A delivery assembly can be used to deliver the incandescent light generated through the secondary quantum optical and thermal emissions from a carbonized near infrared diode laser delivery fiber, otherwise known as a “hot tip,” to an application region that includes live biofilm. With this novel targeted approach of exploiting the incandescent hot tip's radiant energy (ie. its optical and thermal emissions), the physical nature of the targeted live biofilm in the periodontal pocket is changed from a mucinous liquid-gel, to a semi-solid coagulum, which then facilitates its removal from the effected pocket, with traditional mechanical SRP periodontal techniques. | 04-02-2009 |
| 20090105790 | Near Infrared Microbial Elimination Laser Systems (NIMELS) - Methods, systems, and apparatus for Near Infrared Microbial Elimination Laser Systems (NIMELS) including use with medical devices are disclosed. The medical devices can be situated in vivo. Suitable medical devices include catheters, stents, artificial joints, and the like. NIMELS methods, systems, and apparatus can apply near infrared radiant energy of certain wavelengths and dosimetries capable of impairing biological contaminants without intolerable risks and/or adverse effects to biological moieties other than a targeted biological contaminant associated with traditional approaches described in the art (e.g., loss of viability, or thermolysis). Lasers including diode lasers may be used for one or more light sources. A delivery assembly can be used to deliver the optical radiation produced by the source(s) produced to an application region that can include patient tissue. Exemplary embodiments utilize light in a range of 850 nm-900 nm and/or 905 nm-945 nm at suitable NIMELS dosimetries. | 04-23-2009 |
| 20090299263 | Near-Infrared electromagnetic modification of cellular steady-state membrane potentials - Systems and methods are disclosed herein for applying near-infrared optical energies and dosimetries to alter the bioenergetic steady-state trans-membrane and mitochondrial potentials (ΔΨ-steady) of all irradiated cells through an optical depolarization effect. This depolarization causes a concomitant decrease in the absolute value of the trans-membrane potentials ΔΨ of the irradiated mitochondrial and plasma membranes. Many cellular anabolic reactions and drug-resistance mechanisms can be rendered less functional and/or mitigated by a decrease in a membrane potential ΔΨ, the affiliated weakening of the proton motive force Δp, and the associated lowered phosphorylation potential ΔGp. Within the area of irradiation exposure, the decrease in membrane potentials ΔΨ will occur in bacterial, fungal and mammalian cells in unison. This membrane depolarization provides the ability to potentiate antimicrobial, antifungal and/or antineoplastic drugs against only targeted undesirable cells. | 12-03-2009 |
| 20090299441 | Near Infrared Microbial Elimination Laser Systems (NIMEL) - Methods, systems, and apparatus for Near Infrared Microbial Elimination Laser Systems (NIMELS) including use with medical devices are disclosed. The medical devices can be situated in vivo. Suitable medical devices include catheters, stents, artificial joints, and the like. NIMELS methods, systems, and apparatus can apply near infrared radiant energy of certain wavelengths and dosimetries capable of impairing biological contaminants without intolerable risks and/or adverse effects to biological moieties other than a targeted biological contaminant associated with traditional approaches described in the art (e.g., loss of viability, or thermolysis). Lasers including diode lasers may be used for one or more light sources. A delivery assembly can be used to deliver the optical radiation produced by the source(s) produced to an application region that can include patient tissue. Exemplary embodiments utilize light in a range of 850 nm-900 nm and/or 905 nm-945 nm at suitable NIMELS dosimetries. | 12-03-2009 |
| 20110070552 | USE OF SECONDARY OPTICAL EMISSION AS A NOVEL BIOFILM TARGETING TECHNOLOGY - Provided herein are methods and compositions useful for the treatment of periodontal disease exploiting optical and thermal emissions of near-infrared laser systems and fibers in order to target chromophore-stained biofilm while minimizing damage to healthy tissues. | 03-24-2011 |
| 20110082525 | NEAR INFRARED MICROBIAL ELIMINATION LASER SYSTEMS (NIMELS) - Methods, systems, and apparatus for Near Infrared Microbial Elimination Laser Systems (NIMELS) including use with medical devices are disclosed. The medical devices can be situated in vivo. Suitable medical devices include catheters, stents, artificial joints, and the like. NIMELS methods, systems, and apparatus can apply near infrared radiant energy of certain wavelengths and dosimetries capable of impairing biological contaminants without intolerable risks and/or adverse effects to biological moieties other than a targeted biological contaminant associated with traditional approaches described in the art (e.g., loss of viability, or thermolysis). Lasers including diode lasers may be used for one or more light sources. A delivery assembly can be used to deliver the optical radiation produced by the source(s) produced to an application region that can include patient tissue. Exemplary embodiments utilize light in a range of 850 nm-900 nm and/or 905 nm-945 nm at suitable NIMELS dosimetries. | 04-07-2011 |
| 20110208274 | LOW ASPECT RATIO DIFFUSING FIBER TIP - A kit for treating an antimicrobial resistant biological contaminate at a treatment site is disclosed which includes a diffuser tip adapted to receive near infrared therapeutic light from a light delivery system and diffuse the light to illuminate at least a portion of the treatment site; a quantity of an antimicrobial; agent; instructions to use the antimicrobial agent in conjunction with the therapeutic light to potentiate the antimicrobial agent to treat the biological contaminate; and suitable packaging. | 08-25-2011 |
| 20110295343 | NEAR-INFRARED ELECTROMAGNETIC MODIFICATION OF CELLULAR STEADY-STATE MEMBRANE POTENTIALS - Systems and methods are disclosed herein for applying near-infrared optical energies and dosimetries to alter the bioenergetic steady-state trans-membrane and mitochondrial potentials (ΔΨ-steady) of all irradiated cells through an optical depolarization effect. This depolarization causes a concomitant decrease in the absolute value of the trans-membrane potentials ΔΨ of the irradiated mitochondrial and plasma membranes. Many cellular anabolic reactions and drug-resistance mechanisms can be rendered less functional and/or mitigated by a decrease in a membrane potential ΔΨ, the affiliated weakening of the proton motive force Δp, and the associated lowered phosphorylation potential ΔGp. Within the area of irradiation exposure, the decrease in membrane potentials ΔΨ will occur in bacterial, fungal and mammalian cells in unison. This membrane depolarization provides the ability to potentiate antimicrobial, antifungal and/or antineoplastic drugs against only targeted undesirable cells. | 12-01-2011 |
