Disclosed herein are embodiments of a conductive polymer doped with silica nanoparticles. In several embodiments, a coated electrode comprising a coating of the conductive polymer on a conductive surface of the electrode is provided. In some embodiments, the silica nanoparticles of the conductive polymer are mesoporous and are loaded with a pharmaceutical agent. Methods of using the conductive polymer doped with silica nanoparticles are also provided, including methods of recording or stimulating a bioelectric signal and methods of administering a pharmaceutical agent to a subject.

A high-density bioprobe array is provided comprising conductive or optical shanks. A method of making high-density bioprobe arrays also is provided. A bioprobe system using the array also is provided.

Electrocardiogram (ECG) system has been adopted for almost a century to diagnose cardiovascular disease (CVD). Monitoring the cardiac signal provides an insight of CVD and function as an aiding tool for physician towards early detection of cardiac events. A method and wearable device to continuously monitor and determine the cardiac health of the person have been provided. The device is configured to monitor the cardiac system continuously in a partially or fully non-contact manner. The non-contact sensing is achieved by using a hybrid sensing technique. The device consists of a pair of electrodes, one electrode could be a contact sensor that will be touching the skin and the second sensor could be a non-contact sensor. The device facilitates to alert cardiac health monitoring locally or remote location. The device monitors cardiac health in the work environment rather than inducing stress among the participants by making them undergo a stress test.

Electrocardiogram (ECG) system has been adopted for almost a century to diagnose cardiovascular disease (CVD). Monitoring the cardiac signal provides an insight of CVD and function as an aiding tool for physician towards early detection of cardiac events. A method and wearable device to continuously monitor and determine the cardiac health of the person have been provided. The device is configured to monitor the cardiac system continuously in a partially or fully non-contact manner. The non-contact sensing is achieved by using a hybrid sensing technique. The device consists of a pair of electrodes, one electrode could be a contact sensor that will be touching the skin and the second sensor could be a non-contact sensor. The device facilitates to alert cardiac health monitoring locally or remote location. The device monitors cardiac health in the work environment rather than inducing stress among the participants by making them undergo a stress test.

The present invention provides a biosignal measuring and stimulating device having bioelectrodes in which a signal measurement unit (200) including bioelectrodes composed of a plurality of microelectrodes (210) is disposed on a substrate (100), wherein the signal measurement unit (200), a measured signal processing unit (300), and at least one of a driving power unit (400) and a wireless communication unit (500) are disposed on the substrate (100) in a vertical or lateral direction, and the biosignal measuring and stimulating device measures biosignals or stimulates from the microelectrodes formed in an array pattern.

This fiber net includes a fiber net having an electrode part, in which a fiber constituting the electrode part includes a core material, a relaxation layer which covers at least a part of a surface of the core material and contains a material having a higher Young's modulus than a material forming the core material, and a conductive layer which covers a surface of the relaxation layer on a side opposite to the core material side.

A method for manufacturing a deep intracranial electrode, a bending-resistant deep intracranial electrode and an electroencephalograph is disclosed. The method comprises the following steps: manufacturing a support rod of the deep intracranial electrode with a shape memory alloy material, the shape memory alloy having a preset phase-transformation temperature; subjecting the support rod in a straight state to an annealing process such that the support rod memorizes a straight shape.

Disclosed is a sandwich assembly containing a thin film electrode array for use with high density electrodes. To minimize the volume required by the associated electronics, the electrode array and integrated circuits are sandwiched over a Printed Circuit Board (PCB), which may have other integrated circuits on an opposite side. Among other things, the disclosed apparatus, system, and method improve over previous systems by providing holes and vias that facilitate communication between a custom chip above the PCB and a field-programmable gate array (FPGA) below. The thin film electrode array can be fastened by bucking a pillar of stacked gold or other metal balls to rivet the thin film flex circuit. The system can include a thin film array having embedded wire traces and holes, a PCB having vias aligned with the holes, chips including an analog-to-digital converter (ADC) sandwiching the thin film, and solder connections from the chips through the holes to the vias.

A bioelectrode and a method for producing the bioelectrode are provided. The bioelectrode has a non-complicated structure, satisfactory elasticity, and is capable of preventing an increase of contact impedance due to an increase of the number of times of usage. The bioelectrode includes a support member, which is an electrically conductive member, and at least one electrode member, which is a member projecting from the support member. At least the electrode member is molded from an electrically conductive rubber containing a silicone rubber and treated metal particles containing a crosslinkable functional group on a surface thereof.

An electrode for electrocardiogram (ECG) waveform measurement of the present disclosure is proposed. The present disclosure provides an electrode device capable of accurately measuring and monitoring an electrocardiogram of a person by maintaining a uniform amount of electric charge even when a contact area of the electrode changes due to vigorous physical activity such as walking or running, or moisture permeation due to ambient conditions or sweat released during exercise.