A dry electrode and a physiological multi-parameter monitoring equipment are disclosed. The waterproof dry electrode comprises an encapsulation, extraction electrode and a contact surface layer, wherein the extraction electrode and the contact surface layer are connected with each other and disposed in the encapsulation; the contact surface layer comprises an exposed part and an embedded part encapsulation; the encapsulation comprises flexible silica gel and hard plastic portion, the embedded part being embedded into the hard plastic portion, and the hard plastic portion being packaged in the flexible silica gel. Through the above arrangement in the present invention, the dry electrode can reach a waterproof grade of IPX7, which is higher than living waterproof grade of an ordinary dry electrode. The PMPME can be a patch-type acquisition and monitoring equipment which is convenient for long time wearing and physiological multi-parameter monitoring, with excellent sealing and waterproofness, and the electrode is reusable.

A dry electrode and a physiological multi-parameter monitoring equipment are disclosed. The waterproof dry electrode comprises an encapsulation, extraction electrode and a contact surface layer, wherein the extraction electrode and the contact surface layer are connected with each other and disposed in the encapsulation; the contact surface layer comprises an exposed part and an embedded part encapsulation; the encapsulation comprises flexible silica gel and hard plastic portion, the embedded part being embedded into the hard plastic portion, and the hard plastic portion being packaged in the flexible silica gel. Through the above arrangement in the present invention, the dry electrode can reach a waterproof grade of IPX7, which is higher than living waterproof grade of an ordinary dry electrode. The PMPME can be a patch-type acquisition and monitoring equipment which is convenient for long time wearing and physiological multi-parameter monitoring, with excellent sealing and waterproofness, and the electrode is reusable.

Ocular photosensitivity analyzer. In an embodiment, a programmable light source, comprising a plurality of multi-spectra light modules, is configured to emit light according to a lighting condition. For one or a plurality of iterations, the programmable light source is activated to emit the light according to the lighting condition, and collect a response, by a subject, to the emitted light via a sensing system comprising one or more sensors. Between iterations, the programmable light source may be reconfigured based on the response to determine a visual photosensitivity threshold of the subject.

Ocular photosensitivity analyzer. In an embodiment, a programmable light source, comprising a plurality of multi-spectra light modules, is configured to emit light according to a lighting condition. For one or a plurality of iterations, the programmable light source is activated to emit the light according to the lighting condition, and collect a response, by a subject, to the emitted light via a sensing system comprising one or more sensors. Between iterations, the programmable light source may be reconfigured based on the response to determine a visual photosensitivity threshold of the subject.

A device for skin-contact biological measurement includes one or more electrodes to enable signal transmission through a skin contact and a control mechanism coupled to the one or more electrodes to adjust an electrode-to-skin impedance (ESI). The control mechanism is configured to implement the ESI adjustment using a thermal actuator.

A device for skin-contact biological measurement includes one or more electrodes to enable signal transmission through a skin contact and a control mechanism coupled to the one or more electrodes to adjust an electrode-to-skin impedance (ESI). The control mechanism is configured to implement the ESI adjustment using a thermal actuator.

An electrode configured for use in electromyography procedures including a shaft having a first end and a second end, where the shaft consists of a conductive material; an electrically insulative first coating configured to encase the conductive material; a tapered tip at the first end of the shaft, where the tip is angled and is formed by removing the first coating from a first portion of the shaft and exposing a first length of conductive material; and a hub positioned at the second end of the shaft, wherein the hub is positioned after removing the first coating from a second portion of the shaft and exposing a second length of conductive material, wherein the hub is configured to electrically couple a lead wire to the second length of conductive material at the second end.

An electrode configured for use in electromyography procedures including a shaft having a first end and a second end, where the shaft consists of a conductive material; an electrically insulative first coating configured to encase the conductive material; a tapered tip at the first end of the shaft, where the tip is angled and is formed by removing the first coating from a first portion of the shaft and exposing a first length of conductive material; and a hub positioned at the second end of the shaft, wherein the hub is positioned after removing the first coating from a second portion of the shaft and exposing a second length of conductive material, wherein the hub is configured to electrically couple a lead wire to the second length of conductive material at the second end.

A glove-mountable system for pelvic floor muscle (PFM) examination includes a first flexible member including a force sensor configured to detect a force applied to a PFM of a patient by a user. A second flexible member includes an electromyography (EMG) electrode, a stimulation electrode, and a 3-D digitization probe. The second flexible member is stacked on the first flexible member and each flexible member is secured to an examination glove. An actuation button is actuated by the user when at least one point of interest is detected in at least on PFM. A computer including a processor and a memory is in communication with the first flexible member, the second flexible member and the actuation button. The computer generates a 3-D map of a plurality of PFMs of the patient based on data received from the first flexible member, the second flexible member and the actuation button.

A glove-mountable system for pelvic floor muscle (PFM) examination includes a first flexible member including a force sensor configured to detect a force applied to a PFM of a patient by a user. A second flexible member includes an electromyography (EMG) electrode, a stimulation electrode, and a 3-D digitization probe. The second flexible member is stacked on the first flexible member and each flexible member is secured to an examination glove. An actuation button is actuated by the user when at least one point of interest is detected in at least on PFM. A computer including a processor and a memory is in communication with the first flexible member, the second flexible member and the actuation button. The computer generates a 3-D map of a plurality of PFMs of the patient based on data received from the first flexible member, the second flexible member and the actuation button.