Abstract: Some embodiments include a system with a sensor with electrodes including an active electrode and a receiving electrode that is in physical contact with skin of a patient forming an electrical circuit with control electronics of a controller that can measure an electrical parameter using an active electrode and a receiving electrode within a closed loop electrical muscle stimulation system. A sense electrical pulse can be applied to the tissue using the sensor, an electrical parameter measured from the tissue, and a stimulation pulse applied to the tissue based at least in part on the measured electrical parameter. The stimulation is adjustably controlled by the controller to maintain a constant power output to the tissue based on the electrical parameter. A good is coupled to a computer readable medium configured to store usage data, the usage data relating to the patient's use of the good.

Abstract: Disclosed is a system including a good comprising a sensor in contact with human tissues of a patient and configured to obtain a power dissipation reading of the human tissues. The good also includes a storage medium for tangibly storing thereon a program for execution by a processor. The system also includes a control unit in communication with the good to form an electrical muscular stimulation (EMS) system that uses feedback in a closed loop manner to self tune electrical properties of the output. The control unit is configured to instruct the sensor to (a) apply a sense pulse to the human tissues, (b) measure power dissipation of the sense pulse, (c) adjust a stimulation pulse based on the measured power dissipation, (d) apply the stimulation pulse to the human tissues based on the power dissipation and based on the program in order to maintain constant power output across each pulse, and (e) repeat steps (a)-(d).

Abstract: In some embodiments, the system includes a wearable garment that is able to couple to electrode panels to secure the electrode panels in a position to contract transversus abdominis muscles and lumbar multifidus muscles. In some embodiments, the system includes a controller that couples to at least one electrode panel to deliver electrical power to electrodes. In some embodiments, the controller executes program instructions that can independently contract transversus abdominis muscles and lumbar multifidus muscles or can contract the transversus abdominis muscles and lumbar multifidus muscles simultaneously. In some embodiments, the controller executes an NMES and a TENS program simultaneously. In some embodiments, the NMES and TENS are executed by the same electrode.

Abstract: The disclosure is direct to a unique system for delivering NMES and/or TENS therapy to one or more portions of a biological structure. In some embodiments, the biological structure includes a limb such as an elbow or knee. In some embodiments, the system includes a flexible panel with an integrated flexible circuit. In some embodiments, the flexible panel is configured to couple to and bend with a garment. In some embodiments, the flexible panel enables the coupling of one or more electrodes. In some embodiments, the flexible panel is removable from the garment which allows for the garment to be washed without exposing flexible panel electrical connections to submersion in a fluid.

Abstract: This disclosure describes various aspects of a unique therapeutic does for an NMES system. In some embodiments, the system includes one or more electrodes and one or more controls that execute a therapy session program. The therapy session program causes the controller to implement a pulse to the one or more electrodes that, when viewed on a graph of amplitude vs. time, create a “chair” shape with an exponentially decreasing amplitude. In some embodiments, the pulse is considerably longer (e.g., 5 ms) than those implemented in the past (e.g., 300 ?s). In some embodiments, the pulse is held at a non-zero amplitude after an exponential decrease for a period of time before a non-electrical relaxation time period is implemented by the one or more controllers.

Abstract: Some embodiments include a system with a sensor with electrodes including an active electrode and a receiving electrode that is in physical contact with skin of a patient forming an electrical circuit with control electronics of a controller that can measure an electrical parameter using an active electrode and a receiving electrode within a closed loop electrical muscle stimulation system. A sense electrical pulse can be applied to the tissue using the sensor, an electrical parameter measured from the tissue, and a stimulation pulse applied to the tissue based at least in part on the measured electrical parameter. The stimulation is adjustably controlled by the controller to maintain a constant power output to the tissue based on the electrical parameter. A good is coupled to a computer readable medium configured to store usage data, the usage data relating to the patient's use of the good.

Abstract: Some embodiments include a system with a sensor with electrodes including an active electrode and a receiving electrode that is in physical contact with skin of a patient forming an electrical circuit with control electronics of a controller that can measure an electrical parameter using an active electrode and a receiving electrode within a closed loop electrical muscle stimulation system. A sense electrical pulse can be applied to the tissue using the sensor, an electrical parameter measured from the tissue, and a stimulation pulse applied to the tissue based at least in part on the measured electrical parameter. The stimulation is adjustably controlled by the controller to maintain a constant power output to the tissue based on the electrical parameter. A good is coupled to a computer readable medium configured to store usage data, the usage data relating to the patient's use of the good.

Abstract: Disclosed is a system including a good comprising a sensor in contact with human tissues of a patient and configured to obtain a power dissipation reading of the human tissues. The good also includes a storage medium for tangibly storing thereon a program for execution by a processor. The system also includes a control unit in communication with the good to form an electrical muscular stimulation (EMS) system that uses feedback in a closed loop manner to self tune electrical properties of the output. The control unit is configured to instruct the sensor to (a) apply a sense pulse to the human tissues, (b) measure power dissipation of the sense pulse, (c) adjust a stimulation pulse based on the measured power dissipation, (d) apply the stimulation pulse to the human tissues based on the power dissipation and based on the program in order to maintain constant power output across each pulse, and (e) repeat steps (a)-(d).

Abstract: The present invention relates to methods and systems for connecting doctors with patients. More particularly, the present invention relates to computer implemented methods and systems that permit doctors to screen a plurality of patients based on preselected filter criteria.

Abstract: Some embodiments include a system with a sensor with electrodes including an active electrode and a receiving electrode that is in physical contact with skin of a patient forming an electrical circuit with control electronics of a controller that can measure an electrical parameter using an active electrode and a receiving electrode within a closed loop electrical muscle stimulation system. A sense electrical pulse can be applied to the tissue using the sensor, an electrical parameter measured from the tissue, and a stimulation pulse applied to the tissue based at least in part on the measured electrical parameter. The stimulation is adjustably controlled by the controller to maintain a constant power output to the tissue based on the electrical parameter. A good is coupled to a computer readable medium configured to store usage data, the usage data relating to the patient's use of the good.

Abstract: The present invention relates to methods and systems for connecting doctors with patients. More particularly, the present invention relates to computer implemented methods and systems that permit doctors to screen a plurality of patients based on preselected filter criteria.

Abstract: Some embodiments include a system with a sensor with electrodes including an active electrode and a receiving electrode that is in physical contact with skin of a patient forming an electrical circuit with control electronics of a controller that can measure an electrical parameter using an active electrode and a receiving electrode within a closed loop electrical muscle stimulation system. A sense electrical pulse can be applied to the tissue using the sensor, an electrical parameter measured from the tissue, and a stimulation pulse applied to the tissue based at least in part on the measured electrical parameter. The stimulation is adjustably controlled by the controller to maintain a constant power output to the tissue based on the electrical parameter. A good is coupled to a computer readable medium configured to store usage data, the usage data relating to the patient's use of the good.

Abstract: Embodiments of the invention provide a system and method for delivering stimulation therapy or relief to a patient. The system includes a stimulation electrode pair coupled to a good that can couple to a patient to deliver stimulation controlled through a wired or wireless link. The system includes a controller that can generate and apply a stimulation pulse to the stimulation electrode pair based on the stimulation program and the signal or data. The system includes a sensor coupled to the controller and the good, and a user interface enabling a user to remotely view or exchange information through the link, and to monitor and set or reconfigure the stimulation pulse. In some embodiments, the good includes a brace assembly that can be a brace, a stay, a sleeve, a sling, a garment, a wrap, or a strap.

Abstract: Some embodiments include a system with a sensor with electrodes including an active electrode and a receiving electrode that is in physical contact with skin of a patient forming an electrical circuit with control electronics of a controller that can measure an electrical parameter using an active electrode and a receiving electrode within a closed loop electrical muscle stimulation system. A sense electrical pulse can be applied to the tissue using the sensor, an electrical parameter measured from the tissue, and a stimulation pulse applied to the tissue based at least in part on the measured electrical parameter. The stimulation is adjustably controlled by the controller to maintain a constant power output to the tissue based on the electrical parameter. A good is coupled to a computer readable medium configured to store usage data, the usage data relating to the patient's use of the good.

Abstract: A brace includes a closed loop feedback system that provides electrical muscle stimulation (EMS) to a joint of a human patient in response to feedback from the joint and surrounding muscles. In one aspect, a brace for treating a human joint of a patient is provided. The brace includes one or more sensors in physical contact with the skin of the patient and configured to obtain a galvanic reading of resistance of the skin. The brace also includes brace control electronics in communication with the sensor(s) to form a closed loop system via a combination of bracing the joint and electrical muscle stimulation (EMS). The brace control electronics is configured to receive the galvanic reading of the resistance of the skin of the patient and is further configured to instruct the sensor to apply a current/voltage/power onto the skin based on the galvanic reading.

Abstract: Embodiments of the invention provide a system and method for delivering stimulation therapy or relief to a patient. The system includes a stimulation electrode pair coupled to a good that can couple to a patient to deliver stimulation controlled through a wired or wireless link. The system includes a controller that can generate and apply a stimulation pulse to the stimulation electrode pair based on the stimulation program and the signal or data. The system includes a sensor coupled to the controller and the good, and a user interface enabling a user to remotely view or exchange information through the link, and to monitor and set or reconfigure the stimulation pulse. In some embodiments, the good includes a brace assembly that can be a brace, a stay, a sleeve, a sling, a garment, a wrap, or a strap.

Abstract: Disclosed is a system including a good comprising a sensor in contact with human tissues of a patient and configured to obtain a power dissipation reading of the human tissues. The good also includes a storage medium for tangibly storing thereon a program for execution by a processor. The system also includes a control unit in communication with the good to form an electrical muscular stimulation (EMS) system that uses feedback in a closed loop manner to self tune electrical properties of the output. The control unit is configured to instruct the sensor to (a) apply a sense pulse to the human tissues, (b) measure power dissipation of the sense pulse, (c) adjust a stimulation pulse based on the measured power dissipation, (d) apply the stimulation pulse to the human tissues based on the power dissipation and based on the program in order to maintain constant power output across each pulse, and (e) repeat steps (a)-(d).

Abstract: Disclosed is a system including a good comprising a sensor in contact with human tissues of a patient and configured to obtain a power dissipation reading of the human tissues. The good also includes a storage medium for tangibly storing thereon a program for execution by a processor. The system also includes a control unit in communication with the good to form an electrical muscular stimulation (EMS) system that uses feedback in a closed loop manner to self tune electrical properties of the output. The control unit is configured to instruct the sensor to (a) apply a sense pulse to the human tissues, (b) measure power dissipation of the sense pulse, (c) adjust a stimulation pulse based on the measured power dissipation, (d) apply the stimulation pulse to the human tissues based on the power dissipation and based on the program in order to maintain constant power output across each pulse, and (e) repeat steps (a)-(d).

Abstract: A brace includes a closed loop feedback system that provides electrical muscle stimulation (EMS) to a joint of a human patient in response to feedback from the joint and surrounding muscles. In one aspect, a brace for treating a human joint of a patient is provided. The brace includes one or more sensors in physical contact with the skin of the patient and configured to obtain a galvanic reading of resistance of the skin. The brace also includes brace control electronics in communication with the sensor(s) to form a closed loop system via a combination of bracing the joint and electrical muscle stimulation (EMS). The brace control electronics is configured to receive the galvanic reading of the resistance of the skin of the patient and is further configured to instruct the sensor to apply a current/voltage/power onto the skin based on the galvanic reading.

Abstract: A brace includes a closed loop feedback system that provides electrical muscle stimulation (EMS) to a joint of a human patient in response to feedback from the joint and surrounding muscles. In one aspect, a brace for treating a human joint of a patient is provided. The brace includes one or more sensors in physical contact with the skin of the patient and configured to obtain a galvanic reading of resistance of the skin. The brace also includes brace control electronics in communication with the sensor(s) to form a closed loop system via a combination of bracing the joint and electrical muscle stimulation (EMS). The brace control electronics is configured to receive the galvanic reading of the resistance of the skin of the patient and is further configured to instruct the sensor to apply a current/voltage/power onto the skin based on the galvanic reading.