Abstract: Improving motor function in spinal cord injury patients (among others) via electrical stimulation, and associated systems and methods are disclosed. A representative method includes, in a patient having a spinal cord injury, improving the patient's gait response by delivering an electrical signal that includes repeating pulse packets delivered at a first frequency of from 2 Hz to 200 Hz. The electrical signal is delivered from an epidural location at the patient's spinal cord, and the individual pulse packets include a first period during which pulses are delivered at a first frequency of from 1 kHz to 5 kHz and a first pulse width of from 80 microseconds to 400 microseconds and a first amplitude from 0.1 mA to 20 mA, followed by a second period during which pulses are (a) not delivered, or (b) delivered at a second frequency higher than the first frequency, and/or a second pulse width shorter than the first pulse width, and/or a second amplitude less than the first amplitude.

Abstract: Improving motor function in spinal cord injury patients (among others) via electrical stimulation, and associated systems and methods are disclosed. A representative method includes, in a patient having a spinal cord injury, improving the patient's gait response by delivering an electrical signal that includes repeating pulse packets delivered at a first frequency of from 2 Hz to 200 Hz. The electrical signal is delivered from an epidural location at the patient's spinal cord, and the individual pulse packets include a first period during which pulses are delivered at a first frequency of from 1 kHz to 5 kHz and a first pulse width of from 80 microseconds to 400 microseconds and a first amplitude from 0.1 mA to 20 mA, followed by a second period during which pulses are (a) not delivered, or (b) delivered at a second frequency higher than the first frequency, and/or a second pulse width shorter than the first pulse width, and/or a second amplitude less than the first amplitude.

Abstract: A method and apparatus for transurethral resection of the prostate, which includes inserting a transurethral incisional device through the patient's urethra, incising off at least one piece of targeted prostatic tissue using the incisional device, inserting a morcellation probe through the patient's urethra, morcellating the excised piece of targeted prostatic tissue with the morcellation probe, and aspirating the morcellated prostatic tissue through the morcellation probe and out of the patient. The morcellation probe of the present invention includes an elongated inner probe tube that defines an aspiration channel therein and an aperture with opposing cutting edges formed adjacent to its distal end. The inner probe tube is slidably disposed inside an outer probe tube, and moves relative thereto in a longitudinal reciprocating manner. The outer probe tube has an open distal end and another aperture with opposing cutting edges.

Abstract: A method and apparatus for transurethral resection of the prostate, which includes inserting a transurethral incisional device through the patient's urethra, incising off at least one piece of targeted prostatic tissue using the incisional device, inserting a morcellation probe through the patient's urethra, morcellating the excised piece of targeted prostatic tissue with the morcellation probe, and aspirating the morcellated prostatic tissue through the morcellation probe and out of the patient.The morcellation probe of the present invention includes an elongated inner probe tube that defines an aspiration channel therein. The inner probe tube is slidably disposed inside an outer probe tube. The outer probe tube has a first aperture with a first cutting edge for cutting tissue. The inner probe tube has a second aperture or a spiral shaped groove defining a second cutting edge that moves relative to the first cutting edge to cut tissue drawn through the first aperture.

Abstract: An electromagnetic accelerometer includes a rigid shell with a cavity in which two magnets are fixed at either and of the rigid shell and one magnet is allowed to move between the fixed magnets. The three magnets are arranged so that the movable magnet is suspended between the fixed magnets by magnetic forces from the fixed magnets. A coil of wire surrounds the shell and magnets. An acceleration of the accelerometer causes a displacement of the movable magnet with the cavity. As a result, an electrical current is induced in the coil of wire. The voltage in the coil of wire is proportional to the acceleration experienced by the accelerometer. The electromagnetic accelerometer is particular useful in an implantable pacemaker or defibrillator and can be included in either or both a lead or the housing of the pacemaker. Further, the accelerometer generates its own voltage in response to acceleration and the resulting electrical energy can be used as a power source.