A system and method are presented that electrically stimulates the phrenic nerve whereby said stimulation results in muscle activation of the diaphragm as observed by a measurement of work or power of breathing associated with the inspiratory portion of a stimulated breath.

A system and method are presented that electrically stimulates the phrenic nerve whereby said stimulation results in muscle activation of the diaphragm as observed by a measurement of work or power of breathing associated with the inspiratory portion of a stimulated breath.

A system and method are presented that electrically stimulates the phrenic nerve whereby said stimulation results in muscle activation of the diaphragm as observed by a measurement of work or power of breathing associated with the inspiratory portion of a stimulated breath.

A system and method are presented that electrically stimulates the phrenic nerve whereby said stimulation results in muscle activation of the diaphragm as observed by a measurement of work or power of breathing associated with the inspiratory portion of a stimulated breath.

The present disclosure describes a system that automatically detects patient-ventilator asynchrony and trends in patient-ventilator asynchrony. The present disclosure describes a framework that uses pressure, flow, and volume waveforms to detect patient-ventilator asynchrony and the presence of secretions in the ventilator circuit.

A system is for detection of leakage or abnormal resistance in a ventilation system. The ventilation system includes a breathing apparatus which provides a mechanical ventilation to a patient. The system includes a bioelectric sensor arrangement detecting a bioelectric signal indicative of the patient's effort to breathe and a control computer configured to receive the bioelectric signal detected by the bioelectric sensor arrangement. The control computer is further configured to determine a change in the bioelectric signal and to establish leakage or abnormal resistance in the ventilation system based on the change in the bioelectric signal.

An electro-magnetic induction device for activating a target tissue in a body via its muscular or neural system includes an electro-magnetic field generator with a coil design configured to generate an electro-magnetic field, a mounting arrangement holding the coil design at the body, a sensor member configured to detect an activation of a target tissue, an electro-magnetic field adjustment mechanism configured to automatically adjust the position and a field strength of the electro-magnetic field, and a calibration unit in communication with the sensor member and the electro-magnetic field adjustment mechanism. The calibration unit is configured to control the electro-magnetic field adjustment mechanism to automatically vary the position and the field strength of the electro-magnetic field, to receive an activation feedback signal from the sensor, and to control the electro-magnetic field adjustment mechanism to automatically stop variation of the position of the electro-magnetic field generated by the coil design.

A mechanical ventilation system comprises a plurality of ventilation therapy sub-systems. Each of the ventilation therapy sub-systems is adapted to assist a respiratory function of the patient. The system also comprises a detector of the respiratory drive of the patient, an operator interface receiving one or more control parameters, and a main controller. The main controller assigns a therapeutic contribution to each of the ventilation therapy sub-systems based on the respiratory drive of the patient and on the control parameters. The controller modulates the respiratory drive of a patient by controlling each of the plurality of the ventilation therapy sub-systems according to its assigned therapeutic contribution. Distinct ventilation therapy sub-systems may apply negative pressure on the abdomen of the patient, deliver a non-pressurizing inspiratory flow to the patient, or induce a positive pressure in the airways of the patient.

A mechanical ventilation system comprises a plurality of ventilation therapy sub-systems. Each of the ventilation therapy sub-systems is adapted to assist a respiratory function of the patient. The system also comprises a detector of the respiratory drive of the patient, an operator interface receiving one or more control parameters, and a main controller. The main controller assigns a therapeutic contribution to each of the ventilation therapy sub-systems based on the respiratory drive of the patient and on the control parameters. The controller modulates the respiratory drive of a patient by controlling each of the plurality of the ventilation therapy sub-systems according to its assigned therapeutic contribution. Distinct ventilation therapy sub-systems may apply negative pressure on the abdomen of the patient, deliver a non-pressurizing inspiratory flow to the patient, or induce a positive pressure in the airways of the patient.