A device and a method of manufacturing the device may be provided. The device (10) includes a support member (11); two or more electrodes (12) configured to obtain data, the two or more electrodes (12) being positioned on the support member (11); and one or more location identifiers (13) positioned on the support member (11), each of the one or more location identifiers (13) identifying a location to position one of the two or more electrodes (12) to obtain data corresponding to the one or more muscle groups of a body.

A method for measuring sound from vortices in the carotid artery comprising: first and second quality control provisions, wherein the quality control compares detected sounds to pre-determined sounds, and upon confirmation of the quality control procedures, detecting sounds generated by the heart and sounds from vortices in the carotid artery for at least 30 seconds.

An integrated health platform operative to autonomously monitor a wide variety of health parameters and graphically display them in a manner intuitively straight-forward to non-medical users. The platform is further operative to promote interaction and sensory provocation in case of abnormal health readings. The platform is further operative to propose possible therapeutic actions and administer therapeutic treatments responsively to the detection of abnormal health parameters so as to address early stages of potentially serious medical conditions.

There is provided an apparatus for positioning a front sensor and/or a back sensor across a thorax of a target individual, the apparatus comprising: a back positioning element comprising: a collar sized and shaped for fitting to a shoulder line and base of a back of a neck of the target individual, and an elongated element having a first end region connected to the collar, and a second end region with a location marker set to correspond to a target anatomical feature of the spine of the target individual, wherein when in use, the elongated element is positioned parallel to and over a long axis of a spine on the back of the target individual, and at least one front sensor and at least one back sensor are positioned on the thorax of the patient relative to the back positioning element for transmitting to and/or sensing from the target region.

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.

Disclosed herein are surgical robotics, and particularly a perfusion and suction pumping system of a medical instrument for operation within organs of a patient's body. Methods for using the same are also provided.

The present disclosure provides methods for targeting a biomedical system. Aspects of the subject methods include determining the trajectory of a targeting device using magnetic resonance imaging (MRI) of a MRI-visible style of a trajectory guide that is compatible with the targeting device. Targeted biomedical systems may be utilized for a variety of purposes including targeted delivery of a therapeutic, holding a therapeutic device, positioning of a therapeutic device and other uses. Also provided are devices and systems that can be used in practicing the described methods including but not limited to trajectory guides and adjustable targeting systems, as well as non-transitory computer readable medium storing instructions that, when executed by a computing device, cause a computing device to perform steps of the described methods.

The present disclosure provides methods for targeting a biomedical system. Aspects of the subject methods include determining the trajectory of a targeting device using magnetic resonance imaging (MRI) of a MRI-visible style of a trajectory guide that is compatible with the targeting device. Targeted biomedical systems may be utilized for a variety of purposes including targeted delivery of a therapeutic, holding a therapeutic device, positioning of a therapeutic device and other uses. Also provided are devices and systems that can be used in practicing the described methods including but not limited to trajectory guides and adjustable targeting systems, as well as non-transitory computer readable medium storing instructions that, when executed by a computing device, cause a computing device to perform steps of the described methods.

An electrode assembly including: a plurality of medical electrode members; and at least two covering sheets removably attached to the plurality of medical electrode members. The at least one covering sheet includes: a first covering sheet removably attached to one side of each of the plurality of medical electrode members; and a second covering sheet removably attached to an opposite side of each of the plurality of medical electrode members.

Embodiments described herein relate to apparatus and techniques for aligning and coupling a sensor device to a wearable patch. A shoe apparatus is coupled to the wearable patch. The sensor device is coupled to the shoe apparatus via one or more connectors of the shoe apparatus. As the sensor device is inserted into the shoe apparatus, features of the shoe apparatus enable alignment of the sensor device with the shoe apparatus and the one or more connectors.