Wearable sensors that measure one or more parameters such as pressure, force, acceleration, or skin temperature, are used to measure, record, display and monitor the efficacy of therapeutic maneuvers applied to a subject by an operator. Systems and methods for assessing the physiological efficacy of therapeutic maneuvers performed by an operator on a subject in need thereof, and provide a way to guide subsequent therapeutic maneuvers toward optimal outcome. In some embodiments, the systems and methods measure, record, and display physiological parameters of an operator and/or subject during application of cardiopulmonary resuscitation (CPR).

A computer-implemented system may include a treatment device configured to be manipulated by a user while the user is performing a treatment plan, a patient interface comprising an output device configured to present telemedicine information associated with a telemedicine session, and a first computing device configured to: receive treatment data pertaining to the user while the user uses the treatment device to perform the treatment plan; identify at least one aspect of the at least one measurement pertaining to the user associated with a first treatment device mode of the treatment device; determine whether the at least one aspect of the measurement correlates with a secondary condition of the user; and, in response to a determination that the at least one aspect of the at least one measurement is correlated with the at least one secondary condition of the user, generate secondary condition information indicating at least the secondary condition.

The disclosure pertains to methods and devices for administering a vibration expulsion therapy (VET) to a subject to expulse a urinary stone. The method comprises circumferentially administering vibrations to a subject's torso to facilitate movement of a urinary stone through the urinary system or to alleviate pain associated with a urinary stone. In certain embodiments, the method comprises circumferentially administering vibrations to a subject via a vest configured to envelope and tightly fit contours on the subject's torso, particular, the subject's lower torso and cover the subject's kidneys, ureter, and/or urinary bladder. Further provided is a system comprising a processor and a computer-readable medium comprising instructions that, when executed by the processor, causes the processor to actuate a vest placed on the subject's torso to circumferentially administer vibrations to the subject's torso or a portion thereof.

A multimodal optical imaging platform is used to obtain cerebral perfusion-metabolism mismatch metrics for rapid assessment of acute brain injury, ongoing (real-time) feedback to optimize cardiopulmonary resuscitation to improve neurological outcome, and rapid prognosis of recovery. Light of several wavelengths and types is delivered to the tissue, which is then absorbed and scattered by tissue components such as blood and cellular components. Some of this light scatters back to the surface, where it is captured by a detector. The resulting data are processed to obtain blood flow and oxygenation parameters, as well as tissue scattering. These parameters are then combined to calculate metabolism and flow-metabolism coupling/decoupling metrics, which are used to determine ischemic damage, ongoing need for optimal blood flow and oxygenation, and to predict cerebral recovery in patients with acute brain injury during and immediately after cardiac arrest, stroke, traumatic brain injury, etc.

Systems and methods for applying enhanced guided active compression decompression cardiopulmonary resuscitation are provided. Exemplary systems include a load cell, a handle, an adhesive pad. The handle and the adhesive pad are configured for magnetic coupling.

Support device (1) for supporting at least one body part of a user at least in portions, optionally completely, comprising a support body (2), which comprises at least one support region (3) for supporting at least one body part of a user at least in portions, optionally completely, wherein at least the support region (3) has, at least in portions, optionally completely, a geometric-structural design that is individually configured on the basis of the data describing at least one body part of a user that is to be supported on the support region (3) at least in portions, optionally completely.

Various implementations include a method of decreasing oxygen saturation levels in a patient, including securing a leg and foot of the patient to a splint having a leg supporting portion, a foot supporting portion, and an inflatable device. The leg supporting portion includes a leg support body and leg support surface. The foot supporting portion includes a foot support body and foot support surface. The inflatable device rotates the foot support surface relative to the leg support surface from a first position to a second position. The angle between a leg longitudinal axis and a foot longitudinal axis is less in the second position than in the first position. The method further includes inflating the inflatable device to rotate the foot support surface from the first position to the second position and maintaining the second position to decrease oxygen saturation levels in the patient.

Systems and methods for analysis of symmetry between sides of a body. A wearable device includes a body mounting portion structured and arranged to, in use, be mounted to one or more parts of a body of a patient on one side of the body. The wearable device includes at least one sensor configured to output a signal indicative of at least one physiological parameter from a side of the body to which the wearable device is mounted. At least one processor is configured to receive at least one physiological parameter from the wearable device while mounted to a first side of the body, and at least one physiological parameter from the wearable device while mounted to a second side of the body. An indicator of symmetry between the first side and the second side of the body is determined based at least in part on the at least one physiological parameter from the first side of the body and the at least one physiological parameter from the second side of the body.

An apparatus may be configured for providing feedback to caregivers during a code blue scenario when adhered to the chest of a subject undergoing resuscitation by sensing and transmitting information associated with the code blue scenario. Such information may include one or more of vital signs of the subject during resuscitation, information associated with chest movements of the subject during resuscitation, and audio information from an environment of the subject during resuscitation. One or more processors may generate real-time feedback for communication to the caregivers during the code blue scenario based on the sensed and transmitted information.

A medical system includes a manual patient ventilation unit defining an airflow path arranged so that when the unit is applied to a patient the airflow path is in fluid communication with the patient's airway. The patient ventilation unit includes a ventilation bag configured to enable manual ventilation of the patient by a rescuer, an airflow sensor in the airflow path positioned to sense the presence of ventilation airflow and measure a gas flow rate in the airflow path, and a pressure sensor in the airflow path positioned to sense gas pressure in the airflow path. The system also includes a processor arranged to receive data generated by the airflow sensor and the pressure sensor and determine one or more ventilation quality parameters based at least in part on a gas flow volume calculated based on the sensed gas flow rate and gas pressures.