Devices, systems, and methods for specializing, monitoring, and/or evaluating therapeutic nasal neuromodulation are disclosed herein. A targeted neuromodulation system configured in accordance with embodiments of the present technology can include, for example, an evaluation/modulation assembly at a distal portion of a shaft and including a plurality of electrodes. The electrodes are configured to emit stimulating energy at frequencies for identifying and locating target neural structures and detect the resultant bioelectric properties of the tissue. The system can also include a console that maps locations of the target neural structures. The evaluation/modulation assembly can then apply therapeutic neuromodulation energy in a highly tailored neuromodulation pattern based on the mapped locations of the target neural structures. Accordingly, the system provides therapeutic neuromodulation to highly specific target structures while avoiding non-target structures to reduce collateral effects.

Described here are devices and methods for increasing ocular mucin and other tear protein release using intranasally delivered electrical stimulation. Generally, the devices may deliver electrical stimulation to the nasal mucosa. Intranasal stimulation may trigger degranulation of conjunctival goblet cells, which in turn releases secretory mucins into the tear fluid. The intranasal stimulation may also trigger release of lysozyme, lactoferrin, and other tear proteins into the aqueous layer of the tear film. The methods may further comprise obtaining feedback relating to the efficacy of the delivered electrical stimulation by measuring impedance or an electromyogram (EMG) signal.

Devices, systems, and methods for specializing, monitoring, and/or evaluating therapeutic nasal neuromodulation are disclosed herein. A targeted neuromodulation system configured in accordance with embodiments of the present technology can include, for example, an evaluation/modulation assembly at a distal portion of a shaft and including a plurality of electrodes. The electrodes are configured to emit stimulating energy at frequencies for identifying and locating target neural structures and detect the resultant bioelectric properties of the tissue. The system can also include a console that maps locations of the target neural structures. The evaluation/modulation assembly can then apply therapeutic neuromodulation energy in a highly tailored neuromodulation pattern based on the mapped locations of the target neural structures. Accordingly, the system provides therapeutic neuromodulation to highly specific target structures while avoiding non-target structures to reduce collateral effects.

Various methods and devices for treatment or assessment of structures or nerves accessible via the nasal cavity utilizing electrical stimulation or signal recording are provided. Devices can include one or more electrodes to provide electrical stimulation or signal recording. Electrodes can be disposed upon an inflatable balloon or a flat-surfaced tool or a precision tip.

One aspect of the present disclosure relates to a system for treating a medical condition in a patient. The system can include a neurostimulator that is in electrical communication with a remote transducer. The neurostimulator can be sized and dimensioned for injection or insertion into a pterygopalatine fossa (PPF) of a patient. The remote transducer, when activated and brought into close proximity to the patient's head, can cause the neurostimulator to deliver an electrical signal to a target neural structure located within the PPF to treat the medical condition.

The invention provides a device for treating at least one of rhinitis, congestion, and/or rhinorrhea to thereby reduce or eliminate symptoms associated therewith, including, but not limited to, coughing, sneezing, nasal or throat irritation and itching, and difficulty sleeping. The device includes an elongate body, a retractable and expandable multi-segment end effector, and handle, that, as a whole, provide a high level of precise control and feedback to an operator during a procedure. The elongate body includes an electrode array provided along a length thereof configured to deliver energy to specific target sites within the nasal passage and nasal cavity in conjunction with neuromodulation provided by the multi-segment end effector.

The present disclosure is directed to a system and method for selectively and reversibly modulating targeted neural and non-neural tissue of a nervous system for the treatment of pain. An electrical stimulation is delivered to the treatment site that selectively and reversibly modulates the targeted neutral- and non-neural tissue of the nervous structure, inhibiting the perception of pain while preserving other sensory and motor function, and proprioception.

Described here are devices, systems, and methods for treating one or more conditions, such as allergic rhinitis, non-allergic rhinitis, nasal congestion, ocular allergy, and/or symptoms associated with these conditions, by providing stimulation to nasal or sinus tissue. In some variations, the handheld devices may have a stimulator body and a stimulator probe having one or more nasal insertion prongs, and the nasal insertion prongs may be configured to deliver an electrical stimulus to the tissue.

Described here are devices and methods for increasing ocular mucin and other tear protein release using intranasally delivered electrical stimulation. Generally, the devices may deliver electrical stimulation to the nasal mucosa. Intranasal stimulation may trigger degranulation of conjunctival goblet cells, which in turn releases secretory mucins into the tear fluid. The intranasal stimulation may also trigger release of lysozyme, lactoferrin, and other tear proteins into the aqueous layer of the tear film. The methods may further comprise obtaining feedback relating to the efficacy of the delivered electrical stimulation by measuring impedance or an electromyogram (EMG) signal.

One aspect of the present disclosure relates to a system for treating a medical condition in a patient. The system can include a neurostimulator that is in electrical communication with a remote transducer. The neurostimulator can be sized and dimensioned for injection or insertion into a pterygopalatine fossa (PPF) of a patient. The remote transducer, when activated and brought into close proximity to the patient's head, can cause the neurostimulator to deliver an electrical signal to a target neural structure located within the PPF to treat the medical condition.