A rehabilitation assistant system for a patient with depression is provided, comprising a support unit, an audio stimulation unit, an acupoint stimulation unit, an electronic stimulation unit, a display and optical frequency-flashed stimulation and an exercise unit. The audio stimulation unit comprises two speakers configured for broadcasting a binaural beats with frequency following response which has an audio frequency difference to two ears of the user. The acupoint stimulation unit comprises acupoint agents, and at least a part of the acupoint agents are arranged on the support unit. The electronic stimulation unit comprises two electrical stimulation agents arranged on the support unit, and the display and optical frequency-flashed stimulation is arranged on the support unit and is switchable between a display mode and an optical frequency-flashed stimulation mode so that multiple stimulations are performed simultaneously in a single treatment course.

A rehabilitation assistant system for a patient with depression is provided, comprising a support unit, an audio stimulation unit, an acupoint stimulation unit, an electronic stimulation unit, a display and optical frequency-flashed stimulation and an exercise unit. The audio stimulation unit comprises two speakers configured for broadcasting a binaural beats with frequency following response which has an audio frequency difference to two ears of the user. The acupoint stimulation unit comprises acupoint agents, and at least a part of the acupoint agents are arranged on the support unit. The electronic stimulation unit comprises two electrical stimulation agents arranged on the support unit, and the display and optical frequency-flashed stimulation is arranged on the support unit and is switchable between a display mode and an optical frequency-flashed stimulation mode so that multiple stimulations are performed simultaneously in a single treatment course.

A process and a signal processing unit (5) approximately detect a respective characteristic heartbeat time {H_Zp[f](x), H_Zp[s](x.sub.1), . . . , H_Zp[s](x.sub.N)} per heartbeat for a sequence of heartbeats of a patient (P). A sensor array (2.1, 2.2) sends at least one sum signal [Sig.sub.Sum(1), Sig.sub.Sum(2)], which results from a superimposition of a cardiogenic signal and of a respiratory signal. A first detector (25.1) calculates a respective first detection result for each characteristic heartbeat time, and a second detector (25.2, . . . ) calculates a second detection result. The first detector (25.1) analyzes a different sum signal and/or applies a different method of analysis than the second detector (25.2, . . . ). The signal processing unit (5) calculates a respective estimation (representation) for each heartbeat time and uses this estimation as the characteristic heartbeat time. The signal processing unit (5) uses a first detection result and a second detection result to calculate the estimation.

A breath analyzer for detecting breathing events of a person ventilated with a respiratory gas, comprising an electronic computing and storage unit configured to receive a signal corresponding to a ventilation pressure and/or a respiratory flow and/or a tidal volume of the respiratory gas delivered to the person and, during a predetermined analysis duration, to detect a curve of the signal by a curve analyzer. A ventilator for ventilating a person with a respiratory gas, which ventilator comprises the breath analyzer and a method for detecting breathing events of a person ventilated with a respiratory gas is also described.

A blood pump system includes a catheter, a pump housing disposed distal of a distal end of the catheter, a rotor positioned at least partially in the pump housing, a controller, and an electrode coupled a distal region of the blood pump. The electrode can be used to sense electrocardiogram (EKG) signals and transmit the signals to a controller of the blood pump. The operation of the blood pump can be adjusted based on the EKG signal and on cardiac parameters derived from the EKG signal. Further, the controller can determine a need for defibrillation or pacing of the patient's heart based on the signal and can administer treatment with electrical shocks to the heart via the electrode coupled to the blood pump. The use of an electrode with a blood pump already in place in the heart allows for more efficient and safer treatment of serious cardiac conditions.

A method and system to manage a respiratory condition of a patient. An oxygen concentrator is configured to generate and deliver oxygen enriched air to the patient according to a selected dosage. The oxygen concentrator senses and collects physiological data of the patient and collects operational data during the generation and delivery of oxygen enriched air. The oxygen concentrator adjusts the dosage of oxygen enriched air based on the sensed physiological data. The oxygen concentrator transmits operational data and the physiological data to a health data analysis engine. The health data analysis engine collects the data transmitted by the oxygen concentrator. The health analysis engine detects a triggering event based on the collected data and determines an action to resolve the detected triggering event.

The subject matter described herein provides systems and techniques for enhancing a user’s performance. In particular, the physiological characteristics of the user can be altered toward target characteristics to bring about a particular physiological state in the user. Multiple physiological signals of the user may be sensed. Physiological characteristics indicative of a physiological state of the user may be determined. A differential between the physiological characteristics and selected target physiological characteristics may be determined. A selected energy signal associated with a correction action may be communicated to nerves associated with the user’s skin by outputting, using an energy generator, the energy signal toward the skin with one or more different energy types based on the differential. This may allow a particular targeted physiological state to be more rapidly brought about in the user.

The subject matter described herein provides systems and techniques for enhancing a user’s performance. In particular, the physiological characteristics of the user can be altered toward target characteristics to bring about a particular physiological state in the user. Multiple physiological signals of the user may be sensed. Physiological characteristics indicative of a physiological state of the user may be determined. A differential between the physiological characteristics and selected target physiological characteristics may be determined. A selected energy signal associated with a correction action may be communicated to nerves associated with the user’s skin by outputting, using an energy generator, the energy signal toward the skin with one or more different energy types based on the differential. This may allow a particular targeted physiological state to be more rapidly brought about in the user.

A system and method to configure a rule set used in connection with a medical monitoring system for monitoring patients and patient care equipment, especially medication delivery pumps, based on a variety of conditions and parameters associated with monitored biometric information and equipment information and for providing user-defined responses to those conditions and parameters.

A detection unit (88) detects a specific state of a wearer. A signal communication unit (92) wirelessly transmits, to an information processing apparatus, log information indicating a detection result obtained by the detection unit (88) detecting the specific state and a date and time when the specific state is detected. A stimulus application unit (94) applies a stimulus to the wearer when the specific state is detected by the detection unit (88).