Abstract: An apparatus may include a sensing circuit and a processor. The sensing circuit is configured to generate a sensed physiological signal, wherein the physiological signal includes respiration information of a subject. The processor includes an end expiratory volume (EEV) module configured to determine a value of EEV of the subject using the sensed physiological signal, and a lung hyperinflation detection module configured to generate an indication of lung hyperinflation of the subject according to the value of EEV and provide the indication to at least one of a user or process.

Abstract: A system may include a port, at least one sensing circuit, and at least one processor. The port is configured to receive an indication of dosing of medication to treat a pulmonary condition of a heart failure (HF) subject and the at least one sensing circuit configured to sense at least one physiological signal, wherein the physiological signal includes physiological information of the HF subject. The at least one processor includes a parameter module configured to extract values of at least one physiological parameter indicative of health status of the HF subject, and a trending module configured to trend extracted values of the at least one physiological parameter and detect an effect of the dosing of the medication on the HF subject using the trending of the extracted values of the at least one physiological parameter.

Abstract: Exemplary embodiments of devices and methods for treating a lung including, for example, treatments for chronic obstructive pulmonary disease are disclosed. A device may include a plurality of media and a deployment member. The media may be configured for deployment into one or more airways of a lung. The deployment member may be configured for insertion into or proximate the one or more airways of the lung. Also, the deployment member may be configured to deploy the plurality of media substantially simultaneously. Further, the plurality of media may be configured to be retained within the one or more airways of the lung.

Abstract: A method for treating a lung may include forming a channel between a first airway and a second airway through a tissue of the lung to allow air trapped within the first airway to flow through the channel and the second airway, and inserting a support member into the channel.

Abstract: A lung device for restoring lung elasticity includes fixation members and a connecting member. The fixation member includes a first radially expandable fixation member and a second radially expandable fixation member. The first radially expandable fixation member defines a first profile in an expanded state and a lumen. The second radially expandable fixation member defines a second profile in an expanded state and a lumen. The connecting member extends between and connects the first and second fixation members. The lung elasticity restoring device is capable of reversibly extendable between an inspiration configuration and an expiration configuration, may be extendable to the inspiration configuration, and biased to the expiration configuration by the connecting member.

Abstract: An example of a system may include a lead including a distal electrode portion. The distal electrode portion may be configured to at least partially encircle a sympathetic chain in a lumbar region or thoracic region. The distal electrode portion may include at least one electrode oriented toward the sympathetic chain when the distal electrode portion at least partially encircles the sympathetic chain. The distal portion may include at least one anchoring site configured for use to mechanically secure the distal electrode portion to tissue proximate to the sympathetic chain. The lead may have a strain relief proximate to the distal electrode portion.

Abstract: Systems and methods for non-invasive management of head pain are disclosed. The system includes a headgear configured to be worn on a patient's head. The headgear can include a base and an extension coupled to the base, and a number of therapy devices removably or adjustably attached to the base or the extension. The therapy devices can deliver various modes of therapeutic energy at respective target sites on the head, including neuromodulation of peripheral pain pathways and/or the cerebral cortex, and therapy modalities to facilitate or enhance the neuromodulation effects. The system can include a portable device that enables the user to control the therapy devices on the headgear. The user can use the portable device to optionally access a web-based repository to acquire information about headgear usage from other users, and use that information to guide the programming of the therapy devices.

Abstract: The present disclosure relates to methods, devices, kits and systems for enhancing the efficacy and longevity of denervation procedures.

Abstract: The present disclosure relates to the field of tissue mapping and ablation. Specifically, the present disclosure relates to expandable medical devices for identifying and treating local anatomical abnormalities within a body lumen. More specifically, the present disclosure relates to systems and methods of focal treatment for overactive bladders.

Abstract: The present disclosure relates to the field of tissue mapping and ablation. Specifically, the present disclosure relates to expandable medical devices for identifying and treating local anatomical abnormalities within a body lumen. More specifically, the present disclosure relates to systems and methods of focal treatment for overactive bladders.

Abstract: A medical device may include a stimulation member configured to apply a stimulus to a nerve that is configured to control a contraction of an airway distal to the nerve, and a measurement member configured to measure an effect of the stimulus on the airway. The medical device also may include an energy delivery element configured to deliver energy to tissue defining the airway to reduce an effect of the stimulus on the airway. The energy delivery element may be disposed at or distally of the stimulation member.

Abstract: A gas exchange system may include an elongate member including a liquid circuit and configured to be inserted into a body lumen, and a gas exchanger in fluid communication with the elongate member. A gas transfer fluid may be disposed within the liquid circuit of the elongate member. The gas transfer fluid may be configured to absorb carbon dioxide from a body fluid disposed in the body lumen, and subsequently release the carbon dioxide in the gas exchanger.

Abstract: An apparatus for positioning a device relative to tissue may include an emitter and a detector coupled to the device. The emitter may emit energy onto the tissue. The detector may detect energy reflected from the tissue. The detector may also generate a detector output signal indicative of a characteristic of the reflected energy. The apparatus may also include a processor that receives the detector output signal from the detector. The processor may determine whether there has been relative movement between the device and the tissue based on the detector output signal. The processor may also generate a processor output signal based on the relative movement. The apparatus may also include an actuator assembly engaging the device. The actuator assembly may receive the processor output signal from the processor. The actuator assembly may also move the device based on the processor output signal.

Abstract: A method of treating an airway of a lung may include inserting a medical device into the airway, and delivering an agent from the medical device to a nerve disposed within or adjacent the airway to damage the nerve sufficient to reduce an ability of the nerve to send nerve signals.

Abstract: In one embodiment, a device for delivering energy to tissue within a patient may include an elongate member having a proximal end and a distal end, an expandable energy delivery assembly extending from the distal end of the elongate member, wherein the expandable energy delivery assembly includes a plurality of legs, wherein at least one of the legs includes an electrode and defines a passageway adjacent to the electrode, and wherein the passageway is configured to receive a fluid.

Abstract: Methods and devices for treating a lung are disclosed. The method may include deploying a catheter into a blood vessel directing blood towards a portion of the lung, and discharging a media into the blood vessel through the catheter, the media may be configured to at least partially block the flow of blood within the portion of the lung.

Abstract: A medical device may include a pump configured to dispense an agent for treating a condition of a lung. The pump may be configured to be implanted subcutaneously into a patient. The medical device may also include a treatment device coupled to the pump and configured to deliver the agent to the lung.

Abstract: A method for treating a lung may include forming a channel between a first airway and a second airway through a tissue of the lung to allow air trapped within the first airway to flow through the channel and the second airway, and inserting a support member into the channel.

Abstract: A medical device including an elongate member having a proximal end configured to be electrically coupled to an energy source, and a distal member disposed at a distal end of the elongate member. The distal member may include a plurality of contact elements configured to deliver stimulating energy to innervated tissue, detect a response from the innervated tissue to the stimulating energy, and deliver therapeutic energy to the innervated tissue based on the response from the innervated tissue.

Abstract: A method of monitoring a lung condition of a patient may include automatically receiving a diagnostic signal from one or more sensors delivered adjacent to or within a lung of the patient. The one or more sensors may be active to conduct diagnostic monitoring of the lung. The method also may include calculating a diagnostic value based on the diagnostic signal, and determining, based on the diagnostic value, a change in the lung condition.