Devices, apparatuses, and systems configured to assist in the location of an ABTT terminus and then to measure the temperature of the ABTT terminus.

Apparatuses, systems, and techniques are described to detect one or more biological conditions. In one or more implementations, the presence of anemia can be detected in individuals. A wearable device can collect data regarding amounts of attenuation of electromagnetic radiation having one or more wavelength ranges. The amounts of attenuation of the electromagnetic radiation can be used to determine measures of biomolecules and the measures of biomolecules can be used to determine probabilities of individuals being diagnosed with anemia. Additionally, one or more implementations of a computational platform can facilitate the exchange of information between healthcare practitioners and patients regarding the diagnosis and treatment of one or more biological conditions. The computational platform can also analyze large amounts of information to generate computational models to determine probabilities of individuals being diagnosed with anemia and to determine candidate treatments for anemia.

A method comprises registering a robotic system with a patient based on first image data of the patient generated by a first modality to form a registered system, determining, within the registered system, a location for placing an electrode on the patient based on an area of interest for the patient, and causing the robotic system to place the electrode at the location on the patient.

A wearer's risk of developing a lower back pain symptom during work time of heavy muscular work to handle an object is forecasted by continuously estimating the wearer's intervertebral disk pressure force on the basis of weight of the object and the wearer's body height and body weight, and the wearer's trunk angle, and measuring elapsed time in chronological order with respect to each section of the intervertebral disk pressure force according to a load level.

Arrangements described herein relate to systems, apparatuses, and methods for a headset system that includes a transducer configured to collect physiological data of a subject, a device housing configured to support the transducer, an insert portion disposed on the device housing, a support structure comprising a baseplate and a receiving portion, and a head cradle supported by the baseplate. The receiving portion extends in a direction that is oblique with respect to the baseplate. The insert portion is sized and shaped to engage the receiving portion to removably attach the device housing to the baseplate.

A headgear for magnetoencephalography includes a body defining a plurality of ports, where the body includes a first portion and a second portion; an adjustment mechanism coupled to the first portion and the second portion of the body and configured to adjust a separation between the first and second portion to facilitate fitting the headgear to a head of a user; and a plurality of optically pumped magnetometer (OPM) modules, where each of the OPM modules includes at least one vapor cell and is configured to be removably inserted into a one of the ports of the body, where each of the OPM modules is configured for coupling to a light source for receiving light.

Disclosed embodiments provide an electroencephalogram system and method. A novel electrode holder provides multiple net grooves for quick attachment and detachment from an electroencephalogram net. The electrode holder further includes a slot adapted to receive a tab that holds the electrode securely in place. The electrode holder can be configured to operate without gel by using sponges containing water or saline solution that provides moisture for enhancing conductivity. The electrode holder can alternatively be configured to operate with gel by using a tab that keeps the gel in contact with the electrode, for situations that warrant the use of gel instead of water.

A face device for monitoring biomedical parameters of a user provides a support and housing structure shaped so as to be applied to the head of the user, an oximetry sensor fitted to the support and housing structure so as to adhere, in an operating position, to the face of the user at the facial artery, a sound source fitted to the support and housing structure so as to adhere, in an operating position, to a cranial bone of the user, an independently powered electronic board for processing data, received in the support and housing structure and connected to the oximetry sensor and to the sound source so as to detect and process signals coming from the oximetry sensor and to provide information on biomedical parameters to the user acoustically through the sound source. This face device does not engage or distract the user.

Embodiments of systems and methods for monitoring use of an orthopedic device are at least disclosed. In some embodiments, the system can include an orthopedic device, a housing, and a controller. The orthopedic device can provide support to a limb of an individual. The orthopedic device can include a magnet configured to generate a magnetic field. The housing can attach to the individual, and the housing can support a magnetometer configured to generate a signal responsive to the magnetic field. The controller can determine from the signal whether the individual is using the orthopedic device to provide support to the limb and accordingly output usage indications.

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 predetermined 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.