A submucosa treating apparatus according to an exemplary embodiment of the present invention includes: a probe that is capable of approaching mucosa of a treatment field; an electrode that is provided in the probe, and applies an electrical signal to blood vessels of submucosa; and a guide where the probe is movably accommodated, and a guide where the probe is movably accommodated, and guiding a position of the electrode with respect to the mucosa.

Disclosed are devices, systems and methods for non-invasive neuromodulation system for treating inherited or acquired retinal, choroidal and optic nerve disorders caused by acute or chronic dysregulated reduced ocular blood flow (OBF) and/or energy failure by up regulation of trigemino-vascular system (TVS), trigeminal autonomic brain reflexes (TABRs) and pancreatic trigemino-vagal reflex (TVR) through stimulation of ophthalmic nerve (V1), more specifically but not limited to SP, and CGRP containing unmyelinated C nerve fibers. The invention, in some embodiments thereof, relates to the methods for enhancing SP and CGRP expression in neurovascular tissue of the retina and choroid. The invention, in some embodiments thereof, relates to SP/CGRP mediated pathways, including those involved in vasodilatation, augmentation of OBF, RPE proliferation, prevention of apoptosis, suppressing neuroinflammation, promoting migration and differentiation of vascular endothelial cells as well as mobilization of endogenous mesenchymal stem cells (EMSCs) from the bone marrow to the circulation to accelerate tissue repair. The site of stimulation of V1 nerve includes but not limited to; nasal vestibule nasal bridge, forehead, and upper eyelids. Additionally or alternatively, the subject's sympathetic nervous system (SNS) is down regulated by sympatholytic agents specifically antioxidants. The subject's TVS and autonomic nervous system (ANS) are modulated in a manner that is effective to treat the subject for retinal, choroidal and/or optic nerve disorders. In some embodiments, the devices are handheld, portable with nose supported, having one or more intra-nasal or extra-nasal application heads. The signal can include vibration, chemical, ultrasonic, optical, electrical, hybrid electro-optical or combination of two or more of these types of stimuli. The invention, in some embodiments thereof, relates to a method for decreasing vascular resistance, enhancing vasodilatation in ophthalmic artery and its branches by the release of Vasoactive intestinal peptide (VIP),substance P and CGRP thereof increasing OBF to the retina, choroid and optic nerve in subject's with acute or chronic dysregulated, reduced OBF. The invention, in some embodiments thereof, is also related to the methods for improving delivery of oxygen, glucose, vitamin A, humoral mediators, growth factors, stem cells and pharmacological agents to the targeted tissues of the retina, choroid and optic nerve. The invention, in some embodiments thereof, relates to the methods for improving pancreatic insulin secretion, thereof to enhance glucose uptake by PRs and other retinal cells. Additionally or alternatively, the inve

Methods and systems for improving headache pain by using feedback mechanisms are provided.

A handheld stimulator device is described that can deliver a stimulus to tissue of a user. For example, the stimulator device can include a stimulator probe including an electrode and a deformable element configured to assist with allowing stimulus delivery by the electrode. The handheld stimulator device can also include a stimulator body configured to releasably couple to the stimulator probe. The stimulator body can include a power source and at least one contact pin positioned along the stimulator body to, during coupling of the stimulator body to the stimulator probe, form an initial contact configuration with the deformable element in an original state and cause the deformable element to transition into a deformed state. The formation of the initial contact configuration and the deformable element in the deformed state can allow delivery of a stimulus by the stimulator probe.

Described here are devices, systems, and methods for treating one or more conditions (such as dry eye) or improving ocular health by providing stimulation to nasal or sinus tissue. Generally, the devices may be handheld or implantable. In some variations, the handheld devices may have a stimulator body and a stimulator probe having one or more nasal insertion prongs. When the devices and systems are used to treat dry eye, nasal or sinus tissue may be stimulated to increase tear production, reduce the symptoms of dry eye, and/or improve ocular surface health.

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 herein are polymer formulations for facilitating electrical stimulation of nasal or sinus tissue. The polymer formulations may be hydrogels that are prepared by a UV cross-linking process. The hydrogels may be included as a component of nasal stimulator devices that electrically stimulate the lacrimal gland to improve tear production and treat dry eye. Additionally, devices and methods for manufacturing the nasal stimulators, including shaping of the hydrogel, are described herein.

Described here are devices, systems, and methods for treating one or more conditions (such as dry eye) or improving ocular health by providing stimulation to nasal or sinus tissue. Generally, the devices may be handheld or implantable. In some variations, the handheld devices may have a stimulator body and a stimulator probe having one or more nasal insertion prongs. When the devices and systems are used to treat dry eye, nasal or sinus tissue may be stimulated to increase tear production, reduce the symptoms of dry eye, and/or improve ocular surface health.

Described herein are devices and methods of use thereof for treating dry eye, tired eye, or other forms of ocular discomfort such as from contact lenses. The methods generally include applying spatially and/or temporally patterned stimulation to one or more anatomical structures located in an ocular or nasal region. The electrical stimulation may elicit a reflex that activates the lacrimal gland or may directly activate the lacrimal gland or nerves innervating the lacrimal gland to produce tears. The devices may be implantable or handheld, and may be configured to deliver the spatially and/or temporally patterned stimulation patterns described.

The invention generally relates to systems and methods for therapeutically modulating nerves in or associated with a nasal region of a patient for the treatment of a rhinosinusitis condition.