A system for providing a standard electrocardiogram (ECG) signal for a human body using contactless ECG sensors for outputting to exiting medical equipment or for storage or viewing on a remote device. The system comprises a digital processing module (DPM) adapted to connect to an array of contactless ECG sensors provided in a fabric or the like. A selection mechanism is embedded into the DPM which allows the DPM to identify body parts using the ECG signals of the different ECG sensors and select for each body part the best sensor lead. The DPM may then produce the standard ECG signal using the selected ECG signals for the different body parts detected. The system is adapted to continuously re-examine the selection to ensure that the best leads are selected for a given body part following a movement of the body part, thereby, allowing for continuous and un-interrupted ECG monitoring of the patient.

An ear tip for an earpiece including a body, an insertion end, and a retention structure. Some examples include an elongated fin along a portion of an outer leg of the retention structure. Some examples include an extended insertion end configured to insert further into a user's ear canal and including a mushroom cap for providing contact with an interior portion of the user's ear canal and to form an acoustic seal. Some examples may include an umbrella associated with the insertion end, between the mushroom cap and the body. Electrically conductive elements may be associated with any of the elongated fin, the umbrella, and the mushroom cap, to provide electrical contact with the user's skin for sensing electrical signals or for delivery of electrical stimulation.

According to one embodiment, a proficiency determination apparatus includes a processing circuit. The processing circuit acquires first time-series data about biological information of a worker in a predetermined period. The processing circuit calculates second time-series data about a physiological index indicating a mental stress on the worker by analyzing the first time-series data. The processing circuit calculates an appearance condition of the physiological index by analyzing the second time-series data. The processing circuit determines a proficiency of the worker based on the appearance condition of the physiological index.

Systems and methods for assisting user with hearing by amplifying sound using an amplifier with gain and amplitude controls for a plurality of frequencies; and applying a learning machine to identify an aural environment and adjust the amplifiers for optimum hearing.

A myocardial excitation complementation/visualization apparatus includes an acquiring section that acquires intracardiac electrocardiograms of a subject, the intracardiac electrocardiograms being recorded by a recording unit having a plurality of electrodes, a processing section that performs a computation for completing and visualizing a state of excitation in a myocardium of the subject based on the intracardiac electrocardiograms, and a displaying section that displays the state of excitation in the myocardium of the subject based on an output of the processing section. The processing section includes a first generating section, a correcting section, a second generating section, and a third generating section. The displaying section displays a change of the state of excitation in the myocardium of the subject based on the visualized data.

A myocardial excitation complementation/visualization apparatus includes an acquiring section that acquires intracardiac electrocardiograms of a subject, the intracardiac electrocardiograms being recorded by a recording unit having a plurality of electrodes, a processing section that performs a computation for completing and visualizing a state of excitation in a myocardium of the subject based on the intracardiac electrocardiograms, and a displaying section that displays the state of excitation in the myocardium of the subject based on an output of the processing section. The processing section includes a first generating section, a correcting section, a second generating section, and a third generating section. The displaying section displays a change of the state of excitation in the myocardium of the subject based on the visualized data.

A patient monitor that acquires and displays first vital sign information and second vital sign information of a subject includes an event detection unit that is configured to detect an activation start event for starting an activation process of biological information processing software which performs a process pertaining to the second vital sign information and an activating event for activating the biological information processing software and a software control unit that causes the biological information processing software to be in a standby state, in which a part of the activation process of the biological information processing software has been performed, when the activation start event is detected by the event detection unit, and causes the biological information processing software to be in an active state from the standby state when the activating event is detected by the event detection unit.

Disclosed is a method of generating and processing analysis data regarding electrocardiogram signals of a target object. The method includes receiving an electrocardiogram signal of a target object and a first classification data regarding the electrocardiogram signal of the target object. The method further includes calculating statistical data in consideration of a past medical history and symptom information at time of measurement of the target object, generating a second classification data by applying the statistical data to the electrocardiogram signal of the target object, determining a section of interest to be analyzed in consideration of the electrocardiogram signal and the second classification data, extracting signal sections corresponding to the section of interest to be analyzed from the second classification data regarding the electrocardiogram signal, calculating an expected analysis time for the signal sections, and transmitting analysis data regarding the signal sections to an analyst terminal.

A method of delivering pulsed electrical energy to a target tissue region includes delivering a first therapeutic pulse, the delivering of the first therapeutic pulse includes delivering a first pulse for a first time period, the first pulse having a first voltage amplitude. A second pulse is delivered immediately after the first pulse for a second time period, the second pulse having a second voltage amplitude configured to electroporate the target tissue region, the second time period being less than the first time period. A third pulse is delivered without delay after the second pulse for a third time period, the third pulse having a third voltage amplitude being at least one from the group consisting of substantially the same as the first amplitude, larger than the first amplitude, and less than the first amplitude.

A method of delivering pulsed electrical energy to a target tissue region includes delivering a first therapeutic pulse, the delivering of the first therapeutic pulse includes delivering a first pulse for a first time period, the first pulse having a first voltage amplitude. A second pulse is delivered immediately after the first pulse for a second time period, the second pulse having a second voltage amplitude configured to electroporate the target tissue region, the second time period being less than the first time period. A third pulse is delivered without delay after the second pulse for a third time period, the third pulse having a third voltage amplitude being at least one from the group consisting of substantially the same as the first amplitude, larger than the first amplitude, and less than the first amplitude.