The invention provides a body-worn patch sensor for simultaneously measuring a blood pressure (BP), pulse oximetry (SpO2), and other vital signs and hemodynamic parameters from a patient. The patch sensor features a sensing portion having a flexible housing that is worn entirely on the patient's chest and encloses a battery, wireless transmitter, and all the sensor's sensing and electronic components. It measures electrocardiogram (ECG), impedance plethysmogram (IPG), photoplethysmogram (PPG), and phonocardiogram (PCG) waveforms, and collectively processes these to determine the vital signs and hemodynamic parameters. The sensor that measures PPG waveforms also includes a heating element to increase perfusion of tissue on the chest.

An adhesive composition including resin and electro-conductive material, wherein the electro-conductive material is one or more salts from sodium salt, potassium salt, and calcium salt of fluorosulfonic acid having 5 or more carbon atoms shown by the general formula (1): (R.sup.1XYSO.sub.3.sup.).sub.nM.sup.n+(1), wherein, R.sup.1 represents a monovalent hydrocarbon group having 1-30 carbon atoms and optionally substituted by a heteroatom or optionally interposed by a heteroatom; X represents any of a single bond, ether group, ester group, and amide group; Y represents a linear or branched alkylene group having 2-4 carbon atoms, containing 1-6 fluorine atoms, and optionally containing a carbonyl group; M.sup.n+ represents any of a sodium ion, potassium ion, and calcium ion. This can form a living body contact layer for a bio-electrode with electric conductivity, biocompatibility, and light weight, which can be manufactured at low cost and without electric conductivity large lowering even when wetted with water or dried.

A flexible photonic skin is provided, including a functional layer, an adhesive layer used for fixing the functional layer and made of hypoallergenic polyvinyl ethyl ether, and a packaging layer made of a polyurethane semi-transparent film and adhered to the adhesive layer, which are arranged successively from the top down, wherein the functional layer consists of two electrodes located on two sides and used for acquiring electrocardiographic signals of a human body, and a polymer-based photonic integrated chip located between the two electrodes and used for acquiring body temperature, pulse, blood pressure and blood glucose signals of the human body; and, the polymer-based photonic integrated chip processes and outputs the acquired electrocardiographic signals of the human body as well as the body temperature, pulse, blood pressure and blood glucose signals of the human body.

Provided is a biological electrode tool including an electrode portion (10) attached to a human body to acquire a biological signal, and a lead portion (20) for externally leading out the biological signal from the electrode portion (10). The entire areas of the upper and lower surfaces of the electrode portion (10) are covered with a nonwoven fabric (30) except for a portion that contacts the living body (13). The entire areas of the upper and lower surfaces of the lead portion (20) are also covered with nonwoven fabric except for an external lead-out end portion (14). The full circumferential peripheries of the nonwoven fabrics (30) on the upper and lower surfaces of the electrode portion (10) and the lead portion (20) are bonded except for the portion that contacts the living body (13) and the external lead-out end portion (14). Neither the electrode (11) of the electrode portion (10) nor a thin-film lead wire (21) of the lead portion (20) are exposed.

Wearable thoracic element for detecting, monitoring and reporting the physiological status of an individual.

The thoracic element, in the shape of a band, comprises a support layer (5) including a first and second sensors (1),(2) and a processing unit (3) inside a casing (8). The first sensor (1) is a laminated strain gauge located on an elastic portion (5c) of the support layer (5) and the second sensor (2) is formed by a first and a second laminated electro-conductive elements (2a), (2b) cooperating to obtain an ECG measurement, Each of the sensors (1), (2) includes at their ends a connector (21a, 21b, 11a, 11b) to be attached to terminals (4a), (4b) of the casing (8). The laminated electro-conductive elements are superimposed and separated by an electric insulating rigid laminar layer (6). The support layer has two openings (5a) and (5b) at a given distance, through which the electro-conductive elements (2a and 2b) can contact the skin of the individual.

An electrocardiography monitor configured for self-optimizing ECG data compression is provided. ECG waveform characteristics are rarely identical in patients with cardiac disease making this innovation crucial for the long-term data storage and analysis of complex cardiac rhythm disorders. The monitor includes a memory and a micro-controller operable to execute under a micro-programmable control and configured to: obtain a series of electrode voltage values; select one or more of a plurality of compression algorithms for compressing the electrode voltage series; apply one or more of the selected compression algorithms to the electrode voltage series; evaluate a degree of compression of the electrode voltage series achieved using the application of the selected algorithms; apply one or more of the compression algorithms to the compressed electrode voltage series upon the degree of compression not meeting a predefined threshold; and store the compressed electrode voltage series within the memory.

In a method of manufacturing a biomimetic highly stretchable conductive dry adhesive patch, a mold including a plurality of holes is provided by etching a semiconductor substrate including an insulation layer based on a footing effect. A conductive polymer composite is provided by dispersing mixed conductive fillers in a liquid elastomer. The mixed conductive fillers are formed by mixing one-dimensional conductive fillers and two-dimensional conductive fillers. The conductive polymer composite is applied on the mold such that the conductive polymer composite is injected into the plurality of holes. A conductive dry adhesive structure including a plurality of micropillars corresponding to the plurality of holes is obtained by performing a post-treatment on the conductive polymer composite applied on the mold and by removing the mold. Each of the plurality of micropillars includes a body portion and a tip portion. The tip portion has a spatula shape, is formed on the body portion, and has an area larger than that of the body portion in a plan view.

A heart monitoring system enables a person or user to create and evaluate and ECG without the assistance of a medical professional. A self-adhesive patch with leads is placed over the heart of the person and places the leads in an optimal position to thoroughly monitor the patterns emitted from the heart. The data samples are transmitted to a personal device for display and analysis.

The present disclosure relates to a wearable monitor device and methods and systems for using such a device. In certain embodiments, the wearable monitor records cardiac data from a mammal and extracts particular features of interest. These features are then transmitted and used to provide health-related information about the mammal.

A system and method for facilitating a cardiac rhythm disorder diagnosis based on subcutaneous cardiac monitoring data with the aid of a digital computer are provided. Cutaneous action potentials of a patient are recorded as electrocardiogram (EGC) data over a set time period using a subcutaneous insertable cardiac monitor. A set of R-wave peaks is identified within the ECG data and an R-R interval plot is constructed. A difference between recording times of successive pairs of the R-wave peaks in the set is determined. A heart rate associated with each difference is also determined. The pairs of the R-wave peaks and associated heart rate are plotted as the R-R interval plot. A diagnosis of cardiac disorder is facilitated based on patterns of the plotted pairs of the R-wave peaks and the associated heart rates in the R-R interval plot.