Abstract: An exemplary method is disclosed that can be used in the diagnosis of hypertrophic cardiomyopathy (HCM) using a biophysical-sensor system configured to non-invasively and concurrently acquire electrocardiographic signals, seismographic signals, photoplethysmographic, and/or phonocardiographic signals, collectively referred to herein as biophysical signals, from at least the thoracic region of a subject. The acquired biophysical signals may be assessed for one or more conditions or indicators of hypertrophic cardiomyopathy and concurrently with other cardiac diseases, conditions, or indicators of either.

Abstract: The exemplified methods and systems (e.g., machine-learned systems) facilitate the acquisition of ballistocardiographic signals and the determination and use of ballistocardiographic signal related features, or parameters, in a model or classifier to estimate metrics associated with the physiological state of a subject, including for the presence or non-presence of a disease, medical condition, or indication of either. The estimated metric may be used to assist a physician or other healthcare provider in diagnosing the presence or non-presence and/or severity and/or localization of diseases, medical condition, or indication of either or in the treatment of said diseases or indicating conditions. In some embodiments, certain ballistocardiographic signals can also be used to remove motion artifacts from biophysical signals used for the estimation.

Abstract: Methods, systems, and devices for voice-activated medical assistance are described. The method may include receiving an indication of an audio request from a user and determining whether a response to the audio request includes medical information associated with a patient. After determining whether the response includes medical information, the medical assistance server may identify an access class of the medical information and a permission level associated with accessing the access class of the medical information. The method may further include determining whether the user is authorized to access the access class based on the permission level and transmitting an indication of the response to the audio request based on determining whether the user is authorized.

Abstract: Methods, systems, and devices for athlete monitoring are described. The method may include receiving, at a gateway device, physiological measurement data from a sensor configured to transmit wireless signals according to a Bluetooth 5 protocol. The method may further include identifying a user associated with the received physiological measurement data based at least in part on an identity of the sensor and storing at least the received physiological measurement data. In some cases, the method may include receiving the physiological measurement data via one or more of a plurality of repeaters that are configured to transmit wireless signals according to the Bluetooth 5 protocol.

Abstract: Methods, systems, and devices for patient monitoring are described. The method may include receiving an alarm indication associated with a default alarm threshold for a measured physiological parameter and detecting that a clinician is accessing the medical device in response to the alarm indication. After detecting that the clinician is accessing the medical device, the medical device may display an alarm message associated with the alarm indication. The method may further include storing an intervention action associated with an action of the clinician in response to the alarm indication.

Abstract: Methods, systems, and devices for voice-activated medical assistance are described. The method may include receiving an indication of an audio request from a user and determining whether a response to the audio request includes medical information associated with a patient. After determining whether the response includes medical information, the medical assistance server may identify an access class of the medical information and a permission level associated with accessing the access class of the medical information. The method may further include determining whether the user is authorized to access the access class based on the permission level and transmitting an indication of the response to the audio request based on determining whether the user is authorized.

Abstract: Methods, systems, and devices for determining pulseless electrical activity (PEA) are described. The method may include determining by using a first sensor on a person, a heart rate of the person based on sensed electrical activity of the person. A pulse rate of the person may be determined using a second sensor, the pulse rate of the person being based on at least one sensed parameter other than the sensed electrical activity. The method may then include determining a correlation of the determined heart rate and the determined pulse rate and then generating an alert event based at least in part on the correlation being outside of a predetermined threshold.

Abstract: Methods, systems, and devices for video conferencing between a patient and a clinician are described. The method may include receiving a video image of a video conference between the patient and the clinician. The method may also receive an indication of medical information associated with the patient to be displayed during the video conference. The method may further include configuring a viewing window of a video conference device to display the video image and the medical information during the video conference. The configuration of the viewing window may be based on a characteristic of the medical information to be displayed.

Abstract: Methods, systems, and devices for initiating a video conference between a patient and a clinician are described. The method may include receiving an indication of an availability of the patient to participate in the video conference with the clinician, where the indication is based on detecting a proximity of the patient to a video conference device. The method may also determine an availability of the clinician to participate in the video conference with the patient. The method may further include initiating the video conference between the patient and the clinician, via the video conference device, based on the received indication of the availability of the patient and the determined availability of the clinician.

Abstract: Methods, systems, and devices for patient monitoring are described. The method may include receiving an alarm indication associated with a default alarm threshold for a measured physiological parameter and detecting that a clinician is accessing the medical device in response to the alarm indication. After detecting that the clinician is accessing the medical device, the medical device may display an alarm message associated with the alarm indication. The method may further include storing an intervention action associated with an action of the clinician in response to the alarm indication.

Abstract: Methods, systems, and devices for determining pulseless electrical activity (PEA) are described. The method may include determining by using a first sensor on a person, a heart rate of the person based on sensed electrical activity of the person. A pulse rate of the person may be determined using a second sensor, the pulse rate of the person being based on at least one sensed parameter other than the sensed electrical activity. The method may then include determining a correlation of the determined heart rate and the determined pulse rate and then generating an alert event based at least in part on the correlation being outside of a predetermined threshold.

Abstract: Methods, apparatuses and systems are described for associating remote physiological monitoring with an at-risk falling condition of a patient. The methods may include receiving movement data of a patient from one or more sensors. The methods may also include determining a patient posture and a patient activity level based, at least in part, on the received movement data, and determining that an at-risk condition is satisfied by the patient posture or the patient activity level. Once it is determined that the at-risk condition is satisfied, the methods may also include issuing an alert based, at least in part, on the determination that the at-risk condition is satisfied.

Abstract: Methods, apparatuses and systems are described for associating remote physiological monitoring with an at-risk falling condition of a patient. The methods may include receiving movement data of a patient from one or more sensors. The methods may also include determining a patient posture and a patient activity level based, at least in part, on the received movement data, and determining that an at-risk condition is satisfied by the patient posture or the patient activity level. Once it is determined that the at-risk condition is satisfied, the methods may also include issuing an alert based, at least in part, on the determination that the at-risk condition is satisfied.

Abstract: Methods, apparatuses and systems are described for associating remote physiological monitoring with an at-risk falling condition of a patient. The methods may include receiving movement data of a patient from one or more sensors. The methods may also include determining a patient posture and a patient activity level based, at least in part, on the received movement data, and determining that an at-risk condition is satisfied by the patient posture or the patient activity level. Once it is determined that the at-risk condition is satisfied, the methods may also include issuing an alert based, at least in part, on the determination that the at-risk condition is satisfied.

Abstract: Methods, apparatuses and systems are described for determining respiration through impedance measurements using only two electrodes. A drive signal may be applied to a person, using only two electrodes. Using the same electrodes, the fluctuations in the voltage of the drive signal are determined. The voltage fluctuations in the drive signal are the result of impedance variations in the person's thoracic cavity due to respiration. Therefore, the voltage fluctuations may be used to determine a respiration rate of the person. In doing so, the voltage fluctuations may be digitized using a sampling rate that is much less than the frequency of the applied drive signal.

Abstract: Methods, apparatuses and systems are described for monitoring patient position in order to prevent the development of pressure ulcers. The methods may include initiating a first turn timer to calculate a first amount of time spent by a patient in a first position. The methods may further include initiating a first perfusion timer to calculate a second amount of time spent by the patient out of the first position. The methods may then include determining whether to reset the first turn timer based, at least in part, on whether the second amount of time meets or exceeds a predetermined perfusion time threshold. Once the patient has met or exceeded the predetermined perfusion time threshold, an alert may be issued.

Abstract: Methods, apparatuses and systems are described for monitoring patient position in order to prevent the development of pressure ulcers. The methods may include initiating a first turn timer to calculate a first amount of time spent by a patient in a first position. The methods may further include initiating a first perfusion timer to calculate a second amount of time spent by the patient out of the first position. The methods may then include determining whether to reset the first turn timer based, at least in part, on whether the second amount of time meets or exceeds a predetermined perfusion time threshold. Once the patient has met or exceeded the predetermined perfusion time threshold, an alert may be issued.

Abstract: Methods, apparatuses and systems are described for associating remote physiological monitoring with an at-rest condition of a patient. The methods may include receiving activity data and physiological data of a patient. The methods may also include determining that an at-rest condition is satisfied by at least one of the received activity data and physiological data. Once it is determined that the at-rest condition is satisfied, the methods may also include associating an at-rest indicator with one or more physiological measurements of the patient.

Abstract: Methods, apparatuses and systems are described for outputting unsynchronized physiological data. The methods may include receiving a plurality of data streams, each data stream representing a physiological parameter for a person. The methods may also include selecting an epoch. Once the epoch is selected, the methods may also include determining, for each of the plurality of data streams, an epochal or summary value to represent each of the physiological parameters for the person in the epoch. The methods may additionally include outputting the epochal values with an indication of the selected epoch.

Abstract: Methods, apparatuses and systems are described for monitoring physiological parameters by using one or more sensors at a person. First and second physiological parameters of the person are monitored. A determination may be made, at the one or more sensors, that at least one of the first and second physiological parameters has crossed a threshold. An alert event may be generated at the one or more sensors, based on the crossed thresholds. The alert event may then be transmitted to a computing device that is separate from the one or more sensors.