A pessary system for providing pelvic floor support for USL and other ligaments. The pessary has an elongated probe with independently inflatable balloons each located substantially the same distance from the insertion end of the probe and which inflate into separate radial sectors. The probe can be inserted into a vaginal cavity and the balloons inflated provide mechanical support to the USLs. Independent inflation of each balloon allows the mechanical USL support provided to be varied on left and right sides to compensate for differences in the degree of degradation and positioning of the USL ligaments on either side.

A system for measuring EEG signals, comprises a wearable body adapted to fit over a scalp, a plurality of electrodes mounted on the wearable body, and optionally also a plurality of controllable actuators for applying force to the electrodes. A controller optionally controls each actuator or group of actuators to apply force to at least one electrode. A signal processor receives and processes signals from the electrodes and optionally transmits control signals to the controller based on the processing.

A system for measuring EEG signals, comprises a wearable body adapted to fit over a scalp, a plurality of electrodes mounted on the wearable body, and optionally also a plurality of controllable actuators for applying force to the electrodes. A controller optionally controls each actuator or group of actuators to apply force to at least one electrode. A signal processor receives and processes signals from the electrodes and optionally transmits control signals to the controller based on the processing.

Assembly of harness and sensor substrate plates for monitoring vital signals of a patient is provided. More specifically, the present invention provides a harness, a sensor substrate plate, and related devices for non-invasively monitoring vital signals of a patient. The sensor substrate plate provides removable attachment to the skin of a patient to measure vital signals of the patient. The sensor substrate plate comprises an elongated main body comprising an upper surface and an under surface. The upper surface is configured to removably contact the skin surface of the patient. Further, a plurality of slots on the upper surface of the main body is mechanically and electrically configured to hold sensors or electrodes for monitoring biometric parameters of the patient. The upper surface also includes a first through hole mechanically and electrically configured to hold an electrical connector; and a first end and a second end of the main body.

Disclosed is an extensible electrode array (102) for accurately locating a pelvic floor muscle, and its design method and an extensible pelvic floor electrode. The design method includes: (1) obtaining a three-dimensional muscle anatomy map of a pelvic floor muscle, dividing a muscle according to the three-dimensional muscle anatomy map and determining a muscle fiber trend, and for each muscle, determining a plurality of three-dimensional coordinate points for marking each muscle along the muscle fiber trend (S101); (2) after projecting all three-dimensional coordinate projects onto a two-dimensional plane unfolded in a shape of an elastic cavity (101), taking each two-dimensional coordinate point in the two-dimensional plane as a location to dispose an electrode plate (S102); (3) simulating a mechanical property of the elastic cavity (101), and determining a deformation rate of an extensible electrode wire (105) of the electrode plate when the extensible electrode wire (105) of the electrode plate is arranged along a muscle fiber direction of the pelvic floor muscle (S103); and (4) according to a design result, mounting the electrode plate and the extensible electrode wire (105) on the elastic cavity (101) to form the extensible electrode array (102) (S104). The design method enables each electrode plate to locate the pelvic floor muscle before and after expansion, thereby improving accuracy in collecting a myoelectric signal of the pelvic floor muscle.

A pessary system for providing pelvic floor support for USL and other ligaments. The pessary has an elongated probe with independently inflatable balloons each located substantially the same distance from the insertion end of the probe and which inflate into separate radial sectors. The probe can be inserted into a vaginal cavity and the balloons inflated provide mechanical support to the USLs. Independent inflation of each balloon allows the mechanical USL support provided to be varied on left and right sides to compensate for differences in the degree of degradation and positioning of the USL ligaments on either side.

The present invention provides a personalized, three-dimensional printed, human auricle-specific multiple auricular points' bio-signal acquisition, health status monitoring, and bio-stimulation device, including an artificial ear model made of at least one bio-compatible, flexible polymer, a plurality of sensing and stimulating electrodes with at least one sensing end and a signal acquisition/processing end penetrating through a body of the ear mold conformably with a human auricle so that a surface of the ear mold where sensing end of the electrodes is disposed creates an electrode-human skin interface for bio-signal detection and bio-stimulation responsive thereto. Methods of fabricating the device based on 3-D printing, 3D scanning and modelling techniques and using thereof for bio-signal acquisition, analysis, health status monitoring and bio-stimulation are also provided.

A force-controlled electroencephalogram (EEG) monitoring device maintains a constant pressure between electrodes and the scalp of a user thereby increasing user comfort. Arms on the EEG monitoring device position the electrodes in contact with specific regions on the head of the user. The dimension, shape, and curvature of the arms affect the amount of force with which an electrode is held in contact with the user's scalp. The amount of pressure may be different for different regions of the user's head to achieve a balance between comfort and conductivity. The amount of pressure may be further modulated by the use of spring-loaded electrode holders that allow an electrode to move relative to the holder. To further improve user comfort, the tips of the electrodes may be hemispherical rather than pointed. The EEG monitoring device can be used as input for a brain-computer interface (BCI).

A multifunctional electrophysiological monitoring system includes a body-worn tattoo sensor pattern and an electrophysiological monitor connected to sensor contacts of the pattern. A dongle performs a supplemental function, such as acquiring information about a physiological parameter. The dongle interfaces with a port of the monitor. The monitor interfaces wirelessly with a mobile communication device and a monitor network. In an embodiment, the monitor transmits ECG, EMG, or EEG signals. The dongle may provide further monitoring such as body temperature or blood oxygen saturation level. In some embodiments a plurality of dongles may be connected to the monitor.

This invention is a dry EEG electrode with an articulated distal base and/or a plurality of articulated conductive proximal protrusions which penetrate between strands of hair for good electromagnetic contact without causing discomfort or skin irritation.