Example apparatuses and systems are disclosed for providing controlled delivery of electrolysis products to a site which may be used for treatment of infection and ablation of undesirable cells and tissue. A system disclosed may include a power supply, two electrodes, an aqueous matrix that may close the electric circuit between the electrodes at the treated site, and a controller. The controller may control the electrical circuit to induce a direct current through the electrodes and an aqueous matrix to produce electrolysis products. The duration and magnitude of the charge applied may determine the dose of the products applied to the treatment site. The composition of the electrodes and the aqueous matrix may be chosen to produce desired products. An apparatus is disclosed that may be in the form of a pad for applying to a wound. An apparatus is disclosed that may be used for treating internal tissue.

A system includes an endotracheal tube having a plurality of electrodes, wherein the electrodes include at least one stimulating electrode configured to stimulate tissue of a patient and at least one monitoring electrode configured to monitor at least one nerve of a patient. The system includes a nerve integrity monitor device configured to send a stimulation signal to the at least one stimulating electrode to evoke a reflex response, and configured to receive a monitoring signal from the at least one monitoring electrode.

A medical device includes a shaft including a lumen configured to direct a flow of fluid through the shaft and an electrode. A proximal end of the electrode and a distal end of the shaft form a coupling configured to releasably couple the proximal end of the electrode with the distal end of the shaft. When the proximal end of the electrode is coupled to the distal end of the shaft, fluid delivered through the lumen is emitted from the electrode.

Respiratory distress apparatuses, systems and methods are described. An example respiratory distress management device includes a housing, and further has a mechanical ventilation apparatus and a controller within the housing. The controller may include a processor and a memory. The controller may be configured to determine whether, at a particular time, a fault mode condition exists. If a fault mode condition is determined not to exist, then the controller may be configured to enable control of the mechanical ventilation apparatus of the respiratory distress management device by a source in delivering mechanical ventilation to a patient, via signals received by the controller from the source. If a fault mode condition is determined to exist, then the controller may be configured to control the mechanical ventilation apparatus of the respiratory distress management device in delivering mechanical ventilation to the patient.

A fully implanted automatic disorder response system is devised to act as a backup “immune” system, automatically detecting and dispensing an enzyme, for example, deficient due to an inborn error of metabolism. In response to a disease, the agent released is one or more drugs. By directly pipeline-targeting agents through a closed system of drug reservoirs, fluid and electrical lines, and leak-free, durable, and safe tissue connectors to the site of disease, the system achieves a level of efficiency critically superior to the systemic dispersal of an agent into the circulation, fundamentally liberalizing the use of drugs. In comorbid disease, each morbidity is assigned to an arm or channel in a hierarchical control system. Beginning with symptomatic indicia sensors, data is analyzed and passed up through successively higher-level nodes that generate a cross-morbidity view passed up to an implanted microprocessor which effectuates a release of drugs calculated to optimize homeostasis.

A system for intravascular oxygenation may include a catheter shaft, a vibratory member, and an oxygen source. The catheter shaft may have a wall that extends from a proximal end to a distal end along a longitudinal axis to form a lumen. The distal end may terminate in an atraumatic tip that seals off an interior space of the lumen from an adjacent exterior space. The distal end may include a coiled spring whose coils are tightly disposed against adjacent coils. The vibratory member may be configured to produce and transmit via the wall, to the coiled spring, mechanical vibration or high-frequency acoustic energy. The oxygen source may be configured to be coupled to the proximal end and to deliver a flow of oxygen to an interior space for communication to the exterior space, through gaps that exist or are created between adjacent coils of the coiled spring.

A removable power supply cover assembly for an infusion pump is disclosed. The assembly includes a housing body configured to removably attach to an infusion pump, a conductor assembly attached to the housing body, a power supply contact assembly, and a spring attached to the power supply contact assembly and the conductor assembly. An electrical coupling between a power supply to the conductor assembly is formed through the spring.

Aspects of this disclosure describe methods and systems for phrenic nerve stimulation using a stimulation lead placed in a blood vessel. The stimulation lead includes at least one deformable segment that has at least two configurations. For example, the deformable segment may have an elongate configuration and a non-elongate configuration. In the elongate configuration, the deformable segment may be substantially straight, thereby allowing placement of the stimulation lead using a catheter. In the non-elongate configuration, the deformable segment may be a circle or spiral. The deformable segment may transition from the elongate configuration to the non-elongate configuration after the stimulation lead is positioned in the vein. The stimulation lead may be fixated to the vein at a fixation element. Additionally, the stimulation lead may include electrodes distributed along the deformable segment and at least one elongate segment.

Systems and methods for nitric oxide generation are provided. In an embodiment, an NO generation system can include a controller and disposable cartridge that can provide nitric oxide to two different treatments simultaneously. The disposable cartridge has multiple purposes including preparing incoming gases for exposure to the NO generation process, scrubbing exhaust gases for unwanted materials, characterizing the patient inspiratory flow, and removing moisture from sample gases collected. Plasma generation can be done within the cartridge or within the controller. The system has the capability of calibrating NO and NO.sub.2 gas analysis sensors without the use of a calibration gas.

There is provided a system for monitoring a heart of a subject and monitoring impedance-related parameters, comprising: a feeding tube, an electrode disposed(s) on a distal end of the feeding tube, a controller that performs, while the feeding tube is in located in an esophagus and feeding is delivered to a subject via the feeding tube, in a plurality of iterations: continuously measuring voltage at the electrode(s) of the feeding tube, applying alternating current(s) between the electrode(s) of the feeding tube and at least one other electrode, computing impedance measurement(s) from the electrode(s) of the feeding tube according to the applied alternating current(s) and the measured voltage, computing impedance-related parameter(s) based on the impedance measurement(s), terminating the application of the alternating current(s), obtaining an electrocardiogram (ECG) measurement based on the voltage measured at the electrode(s) of the feeding tube, and providing the impedance-related parameter(s) and the ECG measurement.