Systems and methods of delivering a therapeutic session to affect a mental or an emotional state of a user include providing a wearable stimulation device having a transducer adapted to generate tactile transcutaneous vibratory output; with a user interface, obtaining data regarding an event to be experienced by the user; communicating the data regarding an event to be experienced by the user to a computer processor; with the computer processor, creating a therapeutic session parameters comprising the following steps: assigning a set of contiguous output segments for the event, and based on the event, assigning a perceived pitch of transcutaneous vibratory output and a perceived beat of transcutaneous vibratory output to each output segment; sending, from the computer processor, the therapeutic session parameters to the transducer; and generating, with the transducer, transcutaneous vibratory output for the therapeutic session based on the therapeutic session parameters.

Systems and methods of treating a sleep disorder of a subject include providing a therapeutic stimulation device comprising a transducer configured to emit transcutaneous vibratory output to a body part of the subject; generating physiological data with a worn sensor and providing it to a processor; providing a stimulation pattern for transcutaneous vibratory output to be emitted by the transducer comprising a perceived pitch, a perceived beat, and an intensity; causing the transducer to emit the transcutaneous vibratory output in the stimulation pattern; determining if the subject is in a pre-sleep state or a sleep state based on the physiological data; and altering the stimulation pattern based on determining the subject is in at least one of a pre-sleep state or a sleep state comprising at least one of (i) reducing a frequency of the perceived pitch, (ii) increasing an interval of the perceived beat, or (iii) reducing the intensity.

Systems and methods of delivering a therapeutic session to affect a mental or an emotional state of a user include providing a wearable stimulation device having a transducer adapted to generate tactile transcutaneous vibratory output; with a user interface, obtaining data regarding an event to be experienced by the user; communicating the data regarding an event to be experienced by the user to a computer processor; with the computer processor, creating a therapeutic session parameters comprising the following steps: assigning a set of contiguous output segments for the event, and based on the event, assigning a perceived pitch of transcutaneous vibratory output and a perceived beat of transcutaneous vibratory output to each output segment; sending, from the computer processor, the therapeutic session parameters to the transducer; and generating, with the transducer, transcutaneous vibratory output for the therapeutic session based on the therapeutic session parameters.

Embodiments of the present disclosure relate generally to the use of spectral sensors during a cardiac arrest event. More specifically, the present disclosure relates to the use of spectral sensors for measuring changes in pH and muscle oxygen saturation to estimate subject down time and evaluating the effectiveness of the clinical treatment administered during a cardiac arrest event. Given the narrow window of time in which emergency treatment must be administered, as well as the lack of information concerning the subject's condition, there is a need for a fast and accurate method of estimating the onset of the cardiac arrest emergency and evaluating the effectiveness of the emergency treatment being administered.

A therapeutic device includes sensors for collecting biometric health-related parameter information, such as a person's vital signs, during a therapy session for a particular user. A therapeutic program includes an artificial intelligence learning algorithm that uses the biometric health-related information for a particular user acquired during one or more training periods to customize therapeutic parameter values of a therapeutic program to deliver a specialized massage/therapy session that minimizes detriment, and maximizes benefit, to a user by comparing biometric health-related information collected during a therapy session to criteria that corresponds to the health-related information. Biometric health-related information may be stored to a database either local or remote relative to the therapeutic device. Users may retrieve biometric health-related information associated with therapy sessions and view graphical comparisons of changes to their vital signs and other collected data relative to changes in therapeutic parameter values as modified by the therapeutic program.

A method of controlling a mobility device including at least one drive component that drives at least one joint component is described. The control may include providing said mobility device, providing an electronic communication device having a control application to be executed by the electronic control device, receiving an input of settings information to the electronic communication device, the settings information being stored by the control application, electronically connecting the electronic communication device to the mobility device, and executing the control application with the electronic communication device to perform a session of using the mobility device. The electronic communication device executes the control application to control the at least one drive component of the mobility device to selectively configure and modulate the at least one joint component in accordance with the settings information. The control application may be based on multiple device and/or user profiles with the settings being set based on the profiles. Session information may be displayed in real time as a displayed session dashboard, and stored in session logs for future review and analysis.

Systems, and methods relate to a medical device receiving a treatment parameter operating point within a first operating region defined by a first set of operating points for which automatic incremental adjustment of a parameter in the current operation is permitted. In an illustrative example, incremental adjustment may use artificial intelligence based on patient feedback and sensor measurement of outcomes. Some exemplary devices may receive a request to alter the current treatment parameter operating point to a second treatment parameter operating point outside the first operating region and in a second operating region in a known safe operation zone, bounded by a known unsafe zone unavailable to the user. In the second operating region, some examples may restrict the step size of incremental adjustments requested by the user. Data may be collected for cloud-based analysis, for example, to facilitate discovery of more effective treatment protocols.

Smart phones capable of detecting electrical impedances of and providing electronic pulse stimuli to acupuncture points located on a human body are disclosed. An example smart phone is equipped with a hardware diagnosis module and a hardware treatment module that function based on the principle of holography of protruding parts of the human body, in addition to having regular smart phone functions. The diagnosis module may receive electrical impedance data detected from protruding parts of a human body and determine the type of illness according to the analog electrical impedance data. The treatment module may generate electronic pulse stimuli on acupoints located on the human body (such as ears, hands and feet), thereby performing electronic acupuncture treatment. The example smart phone may also detect blood pressure, heart rate, blood oxygen value and blood glucose values of the human body.

Smart phones capable of detecting electrical impedances of and providing electronic pulse stimuli to acupuncture points located on a human body are disclosed. An example smart phone is equipped with a hardware diagnosis module and a hardware treatment module that function based on the principle of holography of protruding parts of the human body, in addition to having regular smart phone functions. The diagnosis module may receive electrical impedance data detected from protruding parts of a human body and determine the type of illness according to the analog electrical impedance data. The treatment module may generate electronic pulse stimuli on acupoints located on the human body (such as ears, hands and feet), thereby performing electronic acupuncture treatment. The example smart phone may also detect blood pressure, heart rate, blood oxygen value and blood glucose values of the human body.

Systems, and methods relate to a medical device receiving a treatment parameter operating point within a first operating region defined by a first set of operating points for which automatic incremental adjustment of a parameter in the current operation is permitted. In an illustrative example, incremental adjustment may use artificial intelligence based on patient feedback and sensor measurement of outcomes. Some exemplary devices may receive a request to alter the current treatment parameter operating point to a second treatment parameter operating point outside the first operating region and in a second operating region in a known safe operation zone, bounded by a known unsafe zone unavailable to the user. In the second operating region, some examples may restrict the step size of incremental adjustments requested by the user. Data may be collected for cloud-based analysis, for example, to facilitate discovery of more effective treatment protocols.