A neck massaging device includes an elastic arm, a handle comprising first outer shell, comprising a connecting end and a free end opposite to the connecting end, and first inner shell buckled with the first outer shell, a connecting member connected the handle to the elastic arm, which is connected to the connecting end of the handle and buckled with the inner shell, an electrode assembly, and an electric pulse generating device electrically connected with the electrode assembly. The free end of the handle may swing with the connecting member as a pivot under the action of external force to drive the first inner shell to be separated from the connecting member.

A device for performing electrotherapeutic massage on the human head, neck, and shoulders includes an inner core structure, at least four protruding nodules, plural electrical wires, and an outer covering. The inner core structure has a central horizontal accommodating opening for accommodating the neck and plural horizontal cushion openings. The horizontal accommodating opening matches the curvature and alignment of the human cervical spine and the kyphotic curvature of the thoracic vertebrae. Each protruding nodule is made of an electrically conductive fabric and sewn to the wall of the corresponding horizontal cushion opening in order to deliver the electrical nerve stimulation pulses generated by an electrotherapeutic signal generator to the corresponding body portion, thereby relaxing the nerve and muscle groups therein. The electrical wires electrically connect the protruding nodules to the electrotherapeutic signal generator. The outer covering encloses the inner core structure while exposing the protruding nodules.

A posture correcting device using vibration or emitted electrical pulses in a pre-determined time sequence that may be adjusted in timing, intensity or strength, and a device for securing said posture correcting device to a body of a wearer.

A method is provided for detecting neural interference between a bone anchor and a neural element during or subsequent to the application of force on the bone anchor to adjust the orientation of one or more vertebral bodies relative to the spinal column. The method includes engaging at least one bone anchor to the vertebral body and applying force to the bone anchor to adjust the positioning or orientation of the vertebral body. A nerve monitoring system provides an electrical signal and is operable to detect a neural element and its proximity to the bone anchor as a function of a characteristic of the electrical signal.

A method includes receiving monitoring data from at least one sensing device coupled to a subject and analyzing the monitoring data to identify one or more physiologic parameters of the subject. The method also includes providing signaling to at least one stimulating device in response to the identified physiologic parameters, the signaling comprising instructions to apply a stimulus to the subject. The method further includes receiving additional monitoring data from the at least one sensing device, analyzing the additional monitoring data to identify one or more changes in the one or more physiologic parameters of the subject after application of the stimulus to the subject, and providing additional signaling to the at least one stimulating device, the additional signaling comprising instructions to modify the stimulus applied to the subject based on the identified changes in the one or more physiologic parameters.

A neck massaging device includes an elastic arm, a handle, a connecting member, an electrode assembly, and an electric pulse generating device. The handle includes a first outer shell and a first inner shell. The first outer shell includes a connecting end and a free end opposite to the connecting end, and the first inner shell is buckled with the first outer shell. The connecting member is for connecting the handle to the elastic arm. The connecting member is connected to the connecting end of the handle and buckled with the first inner shell. The electric pulse generating device is electrically connected with the electrode assembly. The free end of the handle may swing with the connecting member as a pivot under an action of external force to drive the first inner shell to be separated from the connecting member.

Systems and methods are disclosed to stimulate tissue to treat medical conditions involving tissues such as the bone, spine, stomach, nerves, brain and the cochlea. The disclosed invention uses electrical stimulation of the tissue, where vibrational (or acoustic) energy from a source is received by an implanted device and converted to electrical energy and the converted electrical energy is used by implanted electrodes to stimulate the pre-determined tissue sites. The vibrational energy is generated by a controller-transmitter, which could be either implanted or located externally. The vibrational energy is received by a receiver-stimulator, which could be located at or close to the stimulation site.

An implantable pulse generator (IPG) is disclosed having a plurality of electrode nodes, each electrode node configured to be coupled to an electrode to provide stimulation pulses to a patient's tissue. The IPG includes a digital-to-analog converter configured to amplify a reference current to a first current specified by first control signals; a first resistance configured to receive the first current, wherein a voltage across the first resistance is held to a reference voltage at a first node; a plurality of branches each comprising a second resistance and configured to produce a branch current, wherein a voltage across each second resistance is held to the reference voltage at second nodes; and a switch matrix configurable to selectively couple any branch current to any of the electrode nodes via the second nodes.

A method includes receiving monitoring data from at least one sensing device coupled to a subject and analyzing the monitoring data to identify one or more physiologic parameters of the subject. The method also includes providing signaling to at least one stimulating device in response to the identified physiologic parameters, the signaling comprising instructions to apply a stimulus to the subject. The method further includes receiving additional monitoring data from the at least one sensing device, analyzing the additional monitoring data to identify one or more changes in the one or more physiologic parameters of the subject after application of the stimulus to the subject, and providing additional signaling to the at least one stimulating device, the additional signaling comprising instructions to modify the stimulus applied to the subject based on the identified changes in the one or more physiologic parameters.

A method includes receiving monitoring data from at least one sensing device coupled to a subject and analyzing the monitoring data to identify one or more physiologic parameters of the subject. The method also includes providing signaling to at least one stimulating device in response to the identified physiologic parameters, the signaling comprising instructions to apply a stimulus to the subject. The method further includes receiving additional monitoring data from the at least one sensing device, analyzing the additional monitoring data to identify one or more changes in the one or more physiologic parameters of the subject after application of the stimulus to the subject, and providing additional signaling to the at least one stimulating device, the additional signaling comprising instructions to modify the stimulus applied to the subject based on the identified changes in the one or more physiologic parameters.