Abstract: The embodiments and methods described herein relate to an improved functional electrical stimulation (FES) orthosis. An apparatus can include a frame assembly, an electrode assembly, and an electric stimulator. The frame assembly is removably coupleable to a portion of a limb. The electrode assembly is configured to be in electrical communication with a portion of a neuromuscular system of the limb, and includes first and second sets of electrodes. The electric stimulator is in electrical communication with the electrode assembly. The electric stimulator is configured to send a first signal substantially during a first time period and via a first channel to the first set of electrodes for stimulation of a neuromuscular system of the limb, and is configured to send a second signal, during at least one of the first time period or a subsequent second time period, via a second channel to the second set of electrodes for stimulation of the neuromuscular system of the limb.

Abstract: A body weight support system includes a trolley, a powered conductor operatively coupled to a power supply, and a patient attachment mechanism. The trolley can include a drive system, a control system, and a patient support system. The drive system is movably coupled to a support rail. At least a portion of the control system is physically and electrically coupled to the powered conductor. The patient support mechanism is at least temporarily coupled to the patient attachment mechanism. The control system can control at least a portion of the patient support mechanism based at least in part on a force applied to the patient attachment mechanism.

Abstract: An apparatus includes a power adapter having a housing and a circuit at least partially disposed in the housing. The housing is configured to be coupled to an implantable device for disposition in a body. The circuit is configured to be electrically connected to a power circuit of the implantable device when the housing is coupled to the implantable electrical conductor. When the housing is coupled to the implantable electrical conductor and implanted in a body, the circuit is configured to (1) receive, transcutaneously from a power supply, a first energy, (2) convert the first energy to a second energy, and (3) transfer, to the implantable device, the second energy such that the second energy powers the implantable device.

Abstract: An apparatus includes a frame, a sensor, and an electric stimulator. The frame is removably couplable to a portion of a limb. The sensor is configured to produce a first signal associated with a gait characteristic at a first time, and a second signal associated with the gait characteristic at a second time, after the first time. The electric stimulator is removably coupled to the frame and is in electrical communication with an electrode assembly and the sensor to receive the first signal substantially at the first time and the second signal substantially at the second time. Based in part on the gait characteristic at the first time, the electric stimulator sends a third signal to the electrode assembly to provide an electric stimulation to a portion of a neuromuscular system of the limb substantially during a time period defined between the first time and the second time.

Abstract: A body weight support system includes a tether configured to be coupled to an attachment device worn by a user to couple the user to the body weight support system. A method of providing gait training includes defining a reference length of the tether when the attachment device is in an initial position and defining a threshold length of the tether. A first amount of body weight support is provided during the gait training as the user moves relative to a surface and the length of the tether is less than the threshold length. A second amount of body weight support is provided during the gait training as the user moves relative to the surface and the length of the tether is greater than the threshold length. The method further includes displaying data associated with the gait training on a display of an electronic device.

Abstract: The embodiments and methods described herein relate to an improved functional electrical stimulation (FES) orthosis. An apparatus can include a frame assembly, an electrode assembly, and an electric stimulator. The frame assembly is removably coupleable to a portion of a limb. The electrode assembly is configured to be in electrical communication with a portion of a neuromuscular system of the limb, and includes first and second sets of electrodes. The electric stimulator is in electrical communication with the electrode assembly. The electric stimulator is configured to send a first signal substantially during a first time period and via a first channel to the first set of electrodes for stimulation of a neuromuscular system of the limb, and is configured to send a second signal, during at least one of the first time period or a subsequent second time period, via a second channel to the second set of electrodes for stimulation of the neuromuscular system of the limb.

Abstract: An apparatus includes a frame, a sensor, and an electric stimulator. The frame is removably couplable to a portion of a limb. The sensor is configured to produce a first signal associated with a gait characteristic at a first time, and a second signal associated with the gait characteristic at a second time, after the first time. The electric stimulator is removably coupled to the frame and is in electrical communication with an electrode assembly and the sensor to receive the first signal substantially at the first time and the second signal substantially at the second time. Based in part on the gait characteristic at the first time, the electric stimulator sends a third signal to the electrode assembly to provide an electric stimulation to a portion of a neuromuscular system of the limb substantially during a time period defined between the first time and the second time.

Abstract: An apparatus includes a drive mechanism, a patient support mechanism, and an electronic system. The drive mechanism is included in a trolley and is configured to suspend the trolley from a support track. The drive mechanism includes a first sensor configured to sense an operating condition of the drive mechanism. The patient support mechanism couples to the trolley and includes a tether and a second sensor. The tether can be operatively coupled to a patient such that the patient support mechanism supports the patient. The second sensor is configured to sense an operating condition of the patient support mechanism. The electronic system is included in the trolley and has at least a processor and a memory. The processor is configured to define a gait characteristic of the patient based at least in part on a signal received from the first sensor and a signal received from the second sensor.

Abstract: A body weight support system includes a support track, a trolley, and a power rail. The support track has a first portion and a second portion. The trolley has a support assembly and a drive assembly. The support assembly is configured to support at least a portion of a body weight of a user. The drive assembly is configured to movably suspend the trolley from the first portion of the support track when the user moves along a first surface and is configured to movably suspend the trolley from the second portion of the support track when the user moves along a second surface separate from the first surface. The power rail is coupled to the support track and is configured to be in electrical contact with a portion of the trolley as the trolley moves along the first portion and the second portion of the support track.

Abstract: A body weight support system includes a trolley, a powered conductor operatively coupled to a power supply, and a patient attachment mechanism. The trolley can include a drive system, a control system, and a patient support system. The drive system is movably coupled to a support rail. At least a portion of the control system is physically and electrically coupled to the powered conductor. The patient support mechanism is at least temporarily coupled to the patient attachment mechanism. The control system can control at least a portion of the patient support mechanism based at least in part on a force applied to the patient attachment mechanism.

Abstract: A body weight support system includes a trolley, a powered conductor operatively coupled to a power supply, and a patient attachment mechanism. The trolley can include a drive system, a control system, and a patient support system. The drive system is movably coupled to a support rail. At least a portion of the control system is physically and electrically coupled to the powered conductor. The patient support mechanism is at least temporarily coupled to the patient attachment mechanism. The control system can control at least a portion of the patient support mechanism based at least in part on a force applied to the patient attachment mechanism.

Abstract: A body weight support system includes a trolley, a powered conductor operatively coupled to a power supply, and a patient attachment mechanism. The trolley can include a drive system, a control system, and a patient support system. The drive system is movably coupled to a support rail. At least a portion of the control system is physically and electrically coupled to the powered conductor. The patient support mechanism is at least temporarily coupled to the patient attachment mechanism. The control system can control at least a portion of the patient support mechanism based at least in part on a force applied to the patient attachment mechanism.

Abstract: A body weight support system includes a trolley, a powered conductor operatively coupled to a power supply, and a patient attachment mechanism. The trolley can include a drive system, a control system, and a patient support system. The drive system is movably coupled to a support rail. At least a portion of the control system is physically and electrically coupled to the powered conductor. The patient support mechanism is at least temporarily coupled to the patient attachment mechanism. The control system can control at least a portion of the patient support mechanism based at least in part on a force applied to the patient attachment mechanism.

Abstract: The embodiments and methods described herein relate to an improved functional electrical stimulation (FES) orthosis. An apparatus can include a frame assembly, an electrode assembly, and an electric stimulator. The frame assembly is removably coupleable to a portion of a limb. The electrode assembly is configured to be in electrical communication with a portion of a neuromuscular system of the limb, and includes first and second sets of electrodes. The electric stimulator is in electrical communication with the electrode assembly. The electric stimulator is configured to send a first signal substantially during a first time period and via a first channel to the first set of electrodes for stimulation of a neuromuscular system of the limb, and is configured to send a second signal, during at least one of the first time period or a subsequent second time period, via a second channel to the second set of electrodes for stimulation of the neuromuscular system of the limb.

Abstract: An apparatus includes a drive mechanism, a patient support mechanism, and an electronic system. The drive mechanism is included in a trolley and is configured to suspend the trolley from a support track. The drive mechanism includes a first sensor configured to sense an operating condition of the drive mechanism. The patient support mechanism couples to the trolley and includes a tether and a second sensor. The tether can be operatively coupled to a patient such that the patient support mechanism supports the patient. The second sensor is configured to sense an operating condition of the patient support mechanism. The electronic system is included in the trolley and has at least a processor and a memory. The processor is configured to define a gait characteristic of the patient based at least in part on a signal received from the first sensor and a signal received from the second sensor.

Abstract: A body weight support system includes a trolley, a powered conductor operatively coupled to a power supply, and a patient attachment mechanism. The trolley can include a drive system, a control system, and a patient support system. The drive system is movably coupled to a support rail. At least a portion of the control system is physically and electrically coupled to the powered conductor. The patient support mechanism is at least temporarily coupled to the patient attachment mechanism. The control system can control at least a portion of the patient support mechanism based at least in part on a force applied to the patient attachment mechanism.

Abstract: A body weight support system includes a tether configured to be coupled to an attachment device worn by a user to couple the user to the body weight support system. A method of providing gait training includes defining a reference length of the tether when the attachment device is in an initial position and defining a threshold length of the tether. A first amount of body weight support is provided during the gait training as the user moves relative to a surface and the length of the tether is less than the threshold length. A second amount of body weight support is provided during the gait training as the user moves relative to the surface and the length of the tether is greater than the threshold length. The method further includes displaying data associated with the gait training on a display of an electronic device.

Abstract: A body weight support system includes a trolley, a powered conductor operatively coupled to a power supply, and a patient attachment mechanism. The trolley can include a drive system, a control system, and a patient support system. The drive system is movably coupled to a support rail. At least a portion of the control system is physically and electrically coupled to the powered conductor. The patient support mechanism is at least temporarily coupled to the patient attachment mechanism. The control system can control at least a portion of the patient support mechanism based at least in part on a force applied to the patient attachment mechanism.

Abstract: A body weight support system includes a trolley, a powered conductor operatively coupled to a power supply, and a patient attachment mechanism. The trolley can include a drive system, a control system, and a patient support system. The drive system is movably coupled to a support rail. At least a portion of the control system is physically and electrically coupled to the powered conductor. The patient support mechanism is at least temporarily coupled to the patient attachment mechanism. The control system can control at least a portion of the patient support mechanism based at least in part on a force applied to the patient attachment mechanism.

Abstract: An apparatus includes a power adapter having a housing and a circuit at least partially disposed in the housing. The housing is configured to be coupled to an implantable device for disposition in a body. The circuit is configured to be electrically connected to a power circuit of the implantable device when the housing is coupled to the implantable electrical conductor. When the housing is coupled to the implantable electrical conductor and implanted in a body, the circuit is configured to (1) receive, transcutaneously from a power supply, a first energy, (2) convert the first energy to a second energy, and (3) transfer, to the implantable device, the second energy such that the second energy powers the implantable device.