At least one example embodiment relates to a measuring system for measuring bioelectrical signals of a patient, the measuring system comprising a sensor electrode, and a mechanical mounting for the sensor electrode, the mechanical mounting being at least partially compressible and comprising a frame structure and a supporting structure. The mechanical mounting is fastened to a substrate of the measuring system and supports the sensor electrode against the substrate, the supporting structure is arranged beneath the sensor electrode, the frame structure at least partially surrounds the supporting structure, and the supporting structure is configured higher than the frame structure.

A physiological data collection device obtains physiological data from a subject interface on a subject. The physiological data collection device includes a data connector such as a USB connector for connecting directly to a computer. When the physiological data collection device is connected to the computer, the physiological data is uploaded to a remote data processing center for computer-based analysis and review by a medical professional. A report can be provided to the subject based on the analysis and review. When the subject interface is physically connected to the physiological data collection device, the data connector is prevented from being connected to an external device such as the computer.

Systems, devices and methods for advanced electrode management in neurological monitoring applications include receiving sockets configured to receive connectors having groups of electrodes. The physician is not required to manually map each electrode with its corresponding input channel. Electrodes are coupled to the corresponding input channels in groups through connectors having a unique identification (ID). The system is configured to read the unique ID of each connector and establish its identity. Based on the ID, the system configures itself to automatically correlate or associate each electrode with its corresponding input channel when the connectors are first inserted into the receiving sockets, and again if the connectors are removed and re-inserted into different positions in the receiving sockets, to insure the electrodes are always mapped to the same input channels.

A coupling arrangement for a bio-signal measurement, comprises at least two spring connectors of a bio-signal processing device, and a holder comprising a combination of a wall and a substrate, which form a pocket inside the holder, the wall following an outer contour of the bio-signal processing device. The holder has an aperture for inserting the bio-signal processing device into the pocket and removing the bio-signal processing device from the pocket. The holder includes electric conductor lines, which are in a wired electric contact with electrodes of the substrate, the electrodes receiving at least one bio-signal. The electric conductor lines are attached on the substrate inside the pocket, the electric conductor lines and the at least two spring connectors connecting electrically with each other in response to insertion of the bio-signal processing device in the pocket.

The present invention relates to a method for configuring pin-out of a nondirectional USB terminal assembly capable of measuring the electrocardiogram regardless of a connection direction between an electrocardiogram electrode device-side terminal and an electrocardiogram measurement device-side terminal and an electrocardiogram measurement device and an electrode device having a nondirectional USB terminal with pin-out configured by the method. The present invention relates to a result of research with the support of the Information Communication Planning and Evaluation Institute with the funding of the Korean government (Ministry of Science and Technology Information and Communication) in 2020 (Task number: 2020-0-00224 and task name: Development of Wireless Multi-channel ECG Device and Heart diagnosis Solution).

The present invention relates to an ECG monitor device including a removable electrode pad and a monitor element configured for use with a single lead that receives and processes information associated with a plurality of leads.

At least some aspects of the present disclosure direct to systems and methods for monitoring a physiological condition with a plurality of sensors. The system includes a wireless adaptor device and a wireless sensor device. The wireless adaptor device is configured to transmit wireless identification of the wireless adaptor device to the wireless sensor device via a NFC communication. The wireless sensor device is configured establish a wireless communication with the wireless adaptor device using the wireless identification of the wireless adaptor device. The wireless sensor device is further configured to transmit sensor signals to the wireless adaptor device via the established wireless communication.

A portable medical device having an intravenous line flow sensor integrated into a cable. The portable medical device may be a defibrillator having an ECG or electrode cable couple to ECG or electrode leads. The flow sensor may be integrated into the ECG or electrode cable. The portable medical device uses the flow sensor to capture and store information about fluids delivered to a patient being treated with the portable medical device. The information may include total volume provided, flow rate, and the like. The information may then be used to evaluate the treatment provided to the patient.

Systems and methods are provided for water resistant connectors. A male connector includes a rib or a draft angle that creates a seal when engaged with a female connector. A male connector includes an overmold that includes or is made of a thermoplastic elastomer. Male or female connectors include molds that include or are made of a thermoplastic polymer, such as polypropylene. A female connector includes spring contacts that fit within individual pockets of the female connector.

A set of precordial electrodes are pre-attached along a single electrical cord where the electrodes can adjust in separation distances to accommodate different sizes of patients without cord looping or tangling. The invention employs cord corrals that permit a distance between adjacent electrodes to be shortened or lengthened while organizing excess cord. By allowing the adjacent electrode connectors to be shortened or lengthened, the lead array of electrode connectors may be used on a variety of different patient demographics and body sizes. While the single electrical cord eliminates the need for individual attachment of each of the lead wires of each of the electrodes to the ECG monitor.