Described herein are devices and methods for applying a tension force to various tissues. The devices may be delivered in minimally invasive fashion and used to manipulate tissues in the nose, ear, and throat. Force may be maintained by the devices for a time period that allows shaping, compression, or approximation of tissues.

A system for visualizing an anatomical target includes an imaging device (105) configured to collect real-time images of an anatomical target. A three-dimensional model (136) is generated from pre- or intra-operative images and includes images of structures below a surface of the anatomical target not visible in the images from the scope. An image processing module (148) is configured to generate an overlay (107) registered to the real-time images and to indicate the structures below the surface and a depth of the structures below the surface. A display device (118) is configured to concurrently display the real-time images and the overlay.

A medical device includes an elongate device and one or more processors coupled to the elongate device. The elongate device includes a steerable distal end and a shape sensor located along a length of the elongate device. While the elongate device is being traversed through one or more passageways of a patient, the one or more processors are configured to, based on information from a sensor, monitor an insertion motion of the elongate device, detect a data collection event, and capture, in response to detecting the data collection event, a plurality of points along the length of the elongate device using the shape sensor. The data collection event is at least partially based on a change in direction of the insertion motion of the elongate device.

The present disclosure includes catheter systems and methods for treatment of occlusions, including coronary artery chronic total occlusions. The catheter system comprises a catheter coupled to a control system with a distal end inserted into a patient and proximal to a location within a blood vessel with an occlusion. The catheter comprises a flexible outer sheath surrounding a housing with a plurality of lumens to perform various functions to penetrate occlusions.

Systems, methods, and instruments for tracking localized movement of an anatomic structure at a surgical site are provided that can, for example, detect and identify movement of the anatomic structure not otherwise tracked by a global navigation system. One embodiment can include a cannula with a localized navigation sensor coupled to a distal end thereof. The cannula can be coupled to a robot arm and the localized navigation sensor can detect movement of an anatomic structure relative to the cannula. The localized navigation sensor can include one or more tines that selectively extend from the cannula to contact the anatomic structure. A controller can receive data from the localized navigation sensor and a global navigation system, and determine if movement detected by the localized navigation sensor is tracked by the global navigation system. Systems, methods, and instruments of the present disclosure can be used independently of a global navigation system.

Systems and methods for estimating instrument location are described. The methods and systems can obtain a first motion estimate based on robotic data and a second motion estimate based on position sensor data. The methods and systems can determine a motion estimate disparity based on a comparison of the first and second motion estimates. Based on the motion estimate disparity, the methods and systems can update a weighting factor for a location derivable from the robotic data or a weighting factor for a location derivable from the position sensor data. Based on the updated weighting factor, the methods and systems can determine a location/position estimate for the instrument. The methods and systems can provide increased accuracy for a position estimate in cases where the instrument experiences buckling or hysteresis.

The disclosed technology relates to closed-loop medical imaging for a medical environment. Various embodiments provide for a surgical camera, such as an endoscopic camera, comprising one or more image sensors. The image sensors may be configured to capture multispectral image data including one or more images of biological tissue (e.g., surfaces), and may be specifically configured to capture imagery within a surgical environment. For some embodiments, different biological tissues may be visible when illuminated by different wavelengths of a multispectral light source. The wavelength setting for the multispectral light source may be determined based upon a first wavelength setting associated with a first set of multispectral image data and a second wavelength setting associated with a second set of multispectral image data.

An ablation device includes a first jaw, a second jaw including an ablation unit including a protrusion for ablating a tissue and being rotatable with respect to the first jaw under the first jaw, and a signal unit configured to provide a signal to the tissue and receive a reflected signal and disposed on the second jaw, in which the signal unit moves in a longitudinal direction of the ablation unit, the first jaw does not overlap the signal unit in a vertical direction, and the second jaw overlaps the signal unit in the vertical direction.

A system and method for compensation of angular distortions in a system utilizing light emitters and light sensors disposed on non-parallel jaws may include determining a first point at a first side of a region of interest and a second point at a second side of the region of interest, determining a linear curve including the first and second points, and utilizing the linear curve to remove the angular distortion from the region of interest between the first and second points, A system and method for compensation of angular distortions may alternatively include modeling a non-pulsatile illumination pattern according to the intensities of individual emitters, comparing the pattern according to the model against a non-pulsatile illumination pattern detected using the light sensors, and varying the intensities of the individual emitters based on the comparison until angular distortion has been removed.

Certain aspects relate to systems and techniques for luminal network navigation. Some aspects relate to incorporating respiratory frequency and/or magnitude into a navigation system to implement patient safety measures. Some aspects relate to identifying, and compensating for, motion caused by patient respiration in order to provide a more accurate identification of the position of an instrument within a luminal network.