Abstract: This invention provides a dermatological preparation to improve skin cosmesis or conditioning by using different formulations in a sequence that suits the needs of the skin at different points of the hormonal cycle. In its simplest implementation, this would be a two-phase skin treatment, such as a cosmetic, lotion or soap whose formulation changes to balance the differing states of hydration and reactivity of the skin during the early and late phases of the cycle. The formulations would be made in a way to be easily identified and delivered conveniently for use at different times of a hormonal cycle. The preparation would be packaged to permit the convenient purchase and dispensing of the different formulations in a manner that could be easily sequenced with the hormonal cycle.

Abstract: A method and system for treatment of incontinence, urgency, frequency, and/or pelvic pain includes implantation of electrodes on a lead or the discharge portion of a catheter adjacent the perineal nerve(s) or tissue(s) to be stimulated. Stimulation pulses, either electrical or drug infusion pulses, are supplied by a stimulator implanted remotely, and through the lead or catheter, which is tunneled subcutaneously between the stimulator and stimulation site. For instance, the system and method reduce or eliminate the incidence of unintentional episodes of bladder emptying by stimulating nerve pathways that diminish involuntary bladder contractions, improve closure of the bladder outlet, and/or improve the long-term health of the urinary system by increasing bladder capacity and period between emptying.

Abstract: Recovery from peripheral nerve and nerve plexus injuries is usually slow and incomplete because the regenerating motor axons often head erroneously toward sensory receptors rather than muscle fibers and because the target muscles atrophy while waiting for the slow process of reinnervation. Research has suggested that electrical stimulation with different waveforms and temporal patterns at different times during the regeneration process might improve the clinical outcome through various mechanisms, but a practical means to deliver such stimulation has been lacking. This invention teaches the use of miniature electrical stimulators that can be implanted alongside the injured nerve(s) at the time of surgical repair and that can be powered and controlled by transmission of radiofrequency energy from outside the body so as to provide a variety of electrical stimuli at different times during the recovery process.

Abstract: Many patients suffer from diseases and surgical damage that result in failure of the stomach and intestinal tract to contract and relax normally in order to transfer contents distally. Electrical stimulation applied to one or more sites on the surface of the gastrointestinal viscera can treat this problem by triggering or altering muscle contractility. The present invention provides such stimulation by implanting leadless microstimulators in or on the walls of the viscera that can be programmed or controlled from a source outside the body.

Abstract: A method and apparatus for conditioning muscles during sleep. The apparatus includes microminiature electrical stimulators that are injected into the muscles to be exercised and a system of transmission coils located in or on the mattress of a bed. The transmission coils transmit power and command signals to the implanted electrical stimulators while the patient sleeps or rests. The implanted electrical stimulators can be programmed so as to produce the desired pattern of muscle exercise without producing cutaneous sensations that would disturb the patient.

Abstract: An instrumentation system for monitoring various physiological functions in small animals utilizes injectable electronic devices. These implanted devices receive power and control data from an RF carrier signal by inductive coupling. The RF carrier is generated by an external control unit with a coil that surrounds the animals and simultaneously energizes one or more implanted devices. Digitally encoded commands can be addressed to each uniquely addressed implant. These commands permit the implant to select among analog signals from various sensors and to adjust the gain of amplification before digitizing these signals. These commands instruct each implant in turn to generate a back-telemetry signal during pauses in the externally generated RF carrier. The back-telemetry signal is an amplitude-modulated RF signal that encodes the digitized data from the selected sensor. The back-telemetry signal is detected by the external coil and control unit.

Abstract: A method and apparatus for conditioning muscles during sleep. The apparatus includes microminiature electrical stimulators that are injected into the muscles to be exercised and a system of transmission coils located in or on the mattress of a bed. The transmission coils transmit power and command signals to the implanted electrical stimulators while the patient sleeps or rests. The implanted electrical stimulators can be programmed so as to produce the desired pattern of muscle exercise without producing cutaneous sensations that would disturb the patient.

Abstract: Many patients suffer from diseases and surgical damage that result in failure of the stomach and intestinal tract to contract and relax normally in order to transfer contents distally. Electrical stimulation applied to one or more sites on the surface of the gastrointestinal viscera can treat this problem by triggering or altering muscle contractility. The present invention provides such stimulation by implanting leadless microstimulators in or on the walls of the viscera that can be programmed or controlled from a source outside the body.

Abstract: Recovery from peripheral nerve and nerve plexus injuries is usually slow and incomplete because the regenerating motor axons often head erroneously toward sensory receptors rather than muscle fibers and because the target muscles atrophy while waiting for the slow process of reinnervation. Research has suggested that electrical stimulation with different waveforms and temporal patterns at different times during the regeneration process might improve the clinical outcome through various mechanisms, but a practical means to deliver such stimulation has been lacking. This invention teaches the use of miniature electrical stimulators that can be implanted alongside the injured nerve(s) at the time of surgical repair and that can be powered and controlled by transmission of radiofrequency energy from outside the body so as to provide a variety of electrical stimuli at different times during the recovery process.

Abstract: A method and system for treatment of incontinence, urgency, frequency, and/or pelvic pain includes implantation of electrodes on a lead or the discharge portion of a catheter adjacent the perineal nerve(s) or tissue(s) to be stimulated. Stimulation pulses, either electrical or drug infusion pulses, are supplied by a stimulator implanted remotely, and through the lead or catheter, which is tunneled subcutaneously between the stimulator and stimulation site. For instance, the system and method reduce or eliminate the incidence of unintentional episodes of bladder emptying by stimulating nerve pathways that diminish involuntary bladder contractions, improve closure of the bladder outlet, and/or improve the long-term health of the urinary system by increasing bladder capacity and period between emptying.

Abstract: Electrodes are implanted at strategic locations within a patient and are then controlled in a manner so as to stimulate muscle and nerve tissue in a constructive manner which helps open blocked airways. In a preferred method, at least one microstimulator treats sleep apnea in an open loop fashion by providing electrical stimulation pulses in a rhythm or cycle having a period corresponding approximately to the natural respiratory rhythm of the patient. Such open loop stimulation entrains the patient's respiratory rate to follow the pattern set by the microstimulator so that stimulation is applied to open the airway during a period of inspiration by the patient.

Abstract: One or more implantable microminiature electronic devices, termed “microstimulators”, are used to treat sleep apnea. The microstimulators are implanted at strategic locations within the patient and are then controlled in a manner so as to stimulate muscle and nerve tissue in a constructive manner which helps open blocked airways. In one embodiment, the microstimulators sense blockage of a patient's airway and provide electrical stimuli in a closed loop fashion to open the airway. In another embodiment, at least one microstimulator treats sleep apnea in an open loop fashion by providing electrical stimulation pulses in a rhythm or cycle having a period corresponding approximately to the natural respiratory rhythm of the patient. Such open loop stimulation entrains the patient's respiratory rate to follow the pattern set by the microstimulator so that stimulation is applied to open the airway during a period of inspiration by the patient.

Abstract: Improved implantable microstimulators are covered with a biocompatible polymeric coating in order to provide increased strength to the capsule and to capture fragments of the microstimulator should it become mechanically disrupted. Such coating also makes the microstimulator safer and easier to handle. The coating may include one or more diffusible chemical agents that are released in a controlled manner into the surrounding tissue. The chemical agents, such as trophic factors, antibiotics, hormones, neurotransmitters and other pharmaceutical substances, are selected to produce desired physiological effects, to aid, support or to supplement the effects of the electrical stimulation. Further, microstimulators in accordance with the invention provide systems that prevent and/or treat various disorders associated with prolonged inactivity, confinement or immobilization of one or more muscles. Such disorders include pressure ulcers, venous emboli, autonomic dysreflexia, sensorimotor spasticity and muscle atrophy.

Abstract: Improved implantable microstimulators are covered with a biocompatible polymeric coating in order to provide increased strength to the capsule and to capture fragments of the microstimulator should it become mechanically disrupted. Such coating also makes the microstimulator safer and easier to handle. The coating may include one or more diffusible chemical agents that are released in a controlled manner into the surrounding tissue. The chemical agents, such as trophic factors, antibiotics, hormones, neurotransmitters and other pharmaceutical substances, are selected to produce desired physiological effects, to aid, support or to supplement the effects of the electrical stimulation. Further, microstimulators in accordance with the invention provide systems that prevent and/or treat various disorders associated with prolonged inactivity, confinement or immobilization of one or more muscles. Such disorders include pressure ulcers, venous emboli, autonomic dysreflexia, sensorimotor spasticity and muscle atrophy.

Abstract: Improved implantable microstimulators are covered with a biocompatible polymeric coating in order to provide increased strength to the capsule and to capture fragments of the microstimulator should it become mechanically disrupted. Such coating also makes the microstimulator safer and easier to handle. The coating may include one or more diffusible chemical agents that are released in a controlled manner into the surrounding tissue. The chemical agents, such as trophic factors, antibiotics, hormones, neurotransmitters and other pharmaceutical substances, are selected to produce desired physiological effects, to aid, support or to supplement the effects of the electrical stimulation. Further, microstimulators in accordance with the invention provide systems that prevent and/or treat various disorders associated with prolonged inactivity, confinement or immobilization of one or more muscles. Such disorders include pressure ulcers, venous emboli, autonomic dysreflexia, sensorimotor spasticity and muscle atrophy.

Abstract: Improved implantable microstimulators are covered with a biocompatible polymeric coating in order to provide increased strength to the capsule and to capture fragments of the microstimulator should it become mechanically disrupted. Such coating also makes the microstimulator safer and easier to handle. The coating may include one or more diffusible chemical agents that are released in a controlled manner into the surrounding tissue. The chemical agents, such as trophic factors, antibiotics, hormones, neurotransmitters and other pharmaceutical substances, are selected to produce desired physiological effects, to aid, support or to supplement the effects of the electrical stimulation. Further, microstimulators in accordance with the invention provide systems that prevent and/or treat various disorders associated with prolonged inactivity, confinement or immobilization of one or more muscles. Such disorders include pressure ulcers, venous emboli, autonomic dysreflexia, sensorimotor spasticity and muscle atrophy.

Abstract: A system and method for conditioning pelvic muscle tissue for the purpose of treating urinary incontinence uses one or more tiny implantable stimulators (20)--termed "microstimulators"--implanted in or near certain pelvic structures so as to contact target muscle tissue. The microstimulators (20) are small enough to allow their implantation using a hypodermic needle (104). Once implanted, the microstimulators (20) are controlled using a controller (105, 106) and an appropriate coupling coil (102) that couples modulated radio frequency (RF) power into the microstimulators. A fitting station (110) facilitates adjusting the stimulus pattern and amplitude to best meet the needs of a given patient. Once fitted, electrical stimulation is thus provided to the target tissue in accordance with a specified externally-controlled exercise or other regime.

Abstract: Improved implantable microstimulators covered with a biocompatible polymeric coating in order to provide increased strength to the capsule thereof and to capture fragments of the microstimulator should it become mechanically disrupted and to make the microstimulator safer and easier to handle are provided here. The coating may include one or more diffusible chemical agents that are released in a controlled manner into the surrounding tissue. The chemical agents, such as trophic factors, antibiotics, hormones, neurotransmitters and other pharmaceutical substances, are selected to produce desired physiological effects, to aid, support or to supplement the effects of the electrical stimulation. Further, provided herein are systems employing the improved microstimulators to prevent and/or treat various disorders associated with prolonged inactivity, confinement or immobilization of one or more muscles.