Patent application number | Description | Published |
20090112182 | METHOD AND APPARATUS FOR VASCULAR ACCESS - A vascular access device comprises a bridge having first and second bores therethrough, a dilator in the first bore, and a needle guide in the second bore. The second bore is at an angle with respect to the first bore such that the needle guide is at the angle with respect to the dilator. The device is useful, for example to achieve dual site entrance to a blood vessel. | 04-30-2009 |
20090177069 | CATHETER WITH ELECTRODES FOR IMPEDANCE AND/OR CONDUCTION VELOCITY MEASUREMENT - An apparatus comprises a catheter comprising a first electrode. The apparatus also comprises a second electrode electrically attached to a person and coupled to the first electrode via the person's tissue. Logic is coupled to the electrodes and generates an electrical signal that is provided through the electrodes and computes an impedance or conduction velocity associated with the electrodes based on the electrical signal. The logic stores a threshold against which said computed impedance or conduction velocity is compared by said logic | 07-09-2009 |
20100174169 | INTRODUCER SHEATHE WITH ELECTRODES - An apparatus comprises a sheathe for introducing a catheter into a blood vessel, a first electrode provided on the sheathe, a second electrode; and a measuring device to which the first and second electrodes are coupled. The measuring device measures the impedance or conduction velocity between the first electrode on the sheathe and the second electrode | 07-08-2010 |
20100174170 | INTRODUCER SHEATH WITH ELECTRODES - An apparatus comprises a sheath for introducing a catheter into a blood vessel, at least one electrode provided on the sheath, at least one other electrode; and a measuring device to which at least one pair of electrodes are coupled. The measuring device measures the impedance or conduction velocity between the first electrode on the sheath and the second electrode. | 07-08-2010 |
20110282162 | Sternal Closure Wire For Sensing And Therapeutic Energy Delivery - An embodiment includes a sensor coupled to a sternal closure wire. The sternal closure wire holds two sternum portions of a patient adjacent to one another and the first sensor senses a biological signal of the patient. An embodiment includes a current source coupled to a sternal closure wire. The sternal closure wire holds two sternum portions of a patient adjacent to one another, and the current source delivers an electrical current to the patient via the sternal closure wire. Other embodiments are described herein. | 11-17-2011 |
20110288405 | DEVICE, SYSTEM, AND METHOD FOR A STRESS SENSING MEDICAL NEEDLE - In an embodiment, an apparatus comprises a needle (e.g., hypodermic needle or trocar) and sensor (e.g., fiber Braggs grating sensor) coupled to a system to determine (e.g., in real time) stress and/or vibrations encountered by the needle. Consequently, various embodiments may (a) help identify nearby vessels, (b) determine whether the needle penetrated a hollow body structure, and (c) accurately guide needles towards a target structure (e.g., vessel). Other embodiments are described herein. | 11-24-2011 |
20110306970 | Sheath And Method Of Use - In an embodiment a sheath allows one to simultaneously ablate tissue, using a catheter located in the sheath, and remove fluid from a patient's pericardial space, via the same sheath, all without withdrawing the ablation catheter from the sheath. Applying pressure (positive or negative) to fenestrations in the sheath may allow one to withdraw fluid from the space, navigate the sheath within the space, and/or adhere the sheath to tissue in the space. Other embodiments are described herein. | 12-15-2011 |
20120197100 | Guided Ablation Devices, Systems, And Methods - An embodiment of the invention includes a system for the guidance of a catheter to different regions of tissue (e.g., cardiac tissue) for therapy (e.g., ablation therapy). A plurality of electrodes, such as an array of electrodes, may be configured to perform various tasks. First, some electrodes may measure cardiac polarization. Second, some electrodes may function as magnets (e.g., electromagnets) that guide a separate ablation catheter towards the electromagnetic electrodes. These electromagnetic electrodes may be positioned adjacent tissue that is now recognized (possibly due to the electrodes that measure cardiac polarization) as being in need of ablation therapy. Thus, the electromagnetic electrodes may cooperate with an ablation catheter to render a system with magnetic guidance capabilities using intracardiac magnetic field generation. The system may control electromagnetic forces from the array of electrodes to guide the ablation catheter tip to the desired therapy location. Other embodiments are described herein. | 08-02-2012 |