A surgical console includes a drive assembly, vacuum interface, fluid transfer device, user interface, and control circuit. The drive assembly is configured to be coupled to an endoscopic tool and to be rotated by a motor. The vacuum interface is configured to apply a vacuum to the endoscopic tool. The fluid transfer device is configured to flow fluid through the endoscopic tool. The user interface is configured to receive a user input indicating at least one of instructions to rotate the endoscopic tool while applying the vacuum, or to flow fluid through the endoscopic tool. The control circuit controls at least one of the drive assembly, the vacuum interface, or the fluid transfer device based on the instructions, and is configured to cause the drive assembly to rotate the endoscopic tool while the vacuum interface applies the vacuum responsive to the user input indicating instructions to rotate the endoscopic tool.

A biopsy device comprises a coring and transport assembly and a distal beak assembly. The distal beak assembly may be coupled to or near a distal end of the coring and transport assembly and may comprise at least one movable cutting element. The distal beak assembly may be configured to rotate about an axis, and assume at least a first open configuration operative to enable the at least one cutting element to core through tissue and a second closed configuration operative to enable the at least one cutting element to move through the tissue and to sever a cored specimen from the tissue.

There is disclosed, among other things, embodiments of a biopsy needle for taking a full core sample through soft tissue. In the illustrated embodiments, the needle includes a single monolithic tubular member having a notch cut part-way through a distal portion of the tubular member to form an arch-shaped finger. At least a portion of the finger is bent toward the notch and into the lumen of the tubular member. Methods for using these embodiments are also described.

A biopsy device for acquiring a tissue sample is disclosed. The biopsy device comprises a partoff mechanism which can have at least a tab and an actuator. The actuator can be used to control the angle of the tab and thus partoff a tissue sample. The tab may be on a cutter tube, which may have a sharp distal end which may core the samples from the mass of tissue. Multiple tissue samples may be collected.

An embodiment of the claimed invention is directed to a method that greatly streamlines and reduces costs for tissue preparation, preservation, long-term storage and sample retrieval for molecular analysis using a method based on dried blood spot (DBS) technology. In this method, a small needle punch sample of freshly excised tissue will be homogenized in stabilizing reagent and inserted into a device containing absorbent material and drying agent. This device is suitable for long-term sample storage at ambient temperature and allows for easy removal of sections for biomarker analysis.

The present invention provides a system and method for collection, storage and processing of tissues and cells. The system includes a collection container with chambers for storing and processing tissues, which are controllably separated and maintain a physiologic environment for the tissues. The system also includes a fluidic device for isolating target cells of interest. The method includes receiving the tissue into a collection chamber, transferring the tissue to a processing chamber, dissociating the tissue into single cells, and passing the single cells to a device for isolating one or more target cells.

Disclosed is a biopsy device having a tip member with a rearward facing cutting portion for use in a biopsy procedure. The biopsy procedure involves introducing and manoeuvring the device into the tissue of a subject and obtaining a biopsy sample. The biopsy device has an elongate flexible rod member having a proximal end and a distal end that define a first longitudinal axis, and a tip member having a proximal end and a distal end that define a second longitudinal axis. The tip member is located at or towards the distal end of the elongate member and positioned or positionable so that the longitudinal axis of the tip member is angularly offset with respect to the longitudinal axis of the elongate member. The distal end of the tip member is configured to penetrate tissue and the proximal end of the tip member has a cutting portion for cutting tissue.

The present technology generally relates to a tissue sample coring system. Select embodiments of a tissue sample core extractor include a drill head, a drill bit, a tube, and a pump. The drill bit may have a hollow coring head configured to separate a core from a tissue sample and retain the core therein. The drill bit may include a central passageway fluidly coupling the hollow coring head to a port extending radially from the central passageway through the drill bit, where the tube is aligned with the port and movable to selectively abut the drill bit to create a fluid seal between the tube and the port such that the pump can cause a fluid to flow through the tube, pressurize the central passageway, and eject the core. The tissue sample core extractor may further include a trigger configured to move the tube and/or cycle the pump.

A core biopsy system includes a core biopsy needle device having a curvable core biopsy needle which is positionable within and movable with respect to a coaxial needle guide. Systems and methods for obtaining biopsy samples from multiple locations with a single insertion of a needle of the biopsy needle device include controlling rotation and displacement of the core biopsy needle. Additional features and methods of the invention include tracking and planning of the obtaining of biopsy samples.

A method for removing tissues may comprise disposing a tissue resection device at a target tissue site, causing the tissue resection device to resect a core of tissue from the target tissue site, removing the core of tissue from the body, wherein the removing the core of tissue from the body creates a core cavity at the target tissue site. A tracking apparatus may be configured to determine a position of a portion of the tissue resection device in three dimensional space.