A medical fully closed pathological sampling device is disclosed, which addresses the problems existing in the prior art that the size of a sample obtained is too small, which is not conducive to pathological analysis, there is lack of effective closing measures, and environmental pollution and health threats are presented. The device includes an outer sealed cylinder provided with a closable opening at the front end, wherein a middle cutoff cylinder is movably inserted inside the outer sealed cylinder; an inner sampling cylinder is telescopically inserted at the opening located at the front end of the middle cutoff cylinder, and a sampling knife is provided at the front end of the inner sampling cylinder; the front end of a handle inserting rod provided on a sampling operation handle extends into a closable insertion port located at the rear end of the outer sealed cylinder, and the front end of the handle inserting rod is connected to the middle cutoff cylinder and the inner sampling cylinder within the outer sealed cylinder. The device is reasonable in design and compact in structure, and can obtain large-size histological samples, reduce damage to the appearance of cadavers, avoid secondary pollution of the obtained samples to the environment, and effectively reduce the health threat to an anatomy operator and a sample sender.

A reusable core biopsy device having a disposable needle assembly to trap and a reusable drive assembly to selectively drive the disposable needle assembly. The disposable needle assembly includes a contamination collection member defining a fluidically-sealed contamination collection chamber to receive and collect contamination during the extraction of the organic tissue sample. The reusable drive assembly includes a locking mechanism to maintain reusable drive assembly in a locked state. An activation member is to place the reusable drive assembly in an unlocked state, to thereby drive, in sequence, the inner needle member and the outer cannula member forward to extract the organic tissue sample.

An improved flexible endoscopic instrument to precisely and efficiently obtains samples of flat polyps and multiple polyps from a patient by debriding one or more polyps and retrieving the debrided polyps without having to alternate between using a separate cutting tool and a separate sample retrieving tool and may be used with an endoscope. In one aspect, the cutting tool is coupled to a flexible torque coil or torque rope that is configured to transfer rotational energy from a powered actuator through the length of the endoscope onto the cutting tool.

A surgical rongeur includes a lower shaft that defines a floor including a trap door, the lower shaft terminates in a static footplate. An upper shaft is slidably coupled to a top surface of the lower shaft, the upper shaft terminates in a cutting blade. An elongated member is slidably coupled along the floor of the lower shaft and terminates in a sliding footplate. A primary trigger is coupled to the upper shaft, where actuation of the primary trigger is configured to alternately move the cutting blade between an open position and a closed position. A secondary trigger is coupled to the elongated member, where actuation of the secondary trigger, while the cutting blade is in the closed position, is configured to retract the sliding footplate from the static footplate into one of a plurality of positions.

A biopsy device includes a device housing, a linear motor, and a controller circuit. The controller circuit has a processor circuit, a first feedback circuit, and a second feedback circuit. The first feedback circuit and the second feedback circuit operate simultaneously. The processor circuit executes program instructions to control an axial advancement of the distal end of the linear motor shaft in accordance with a linear motor shaft advancement profile based on first control signals received from at least one drive characteristic sensor of the first feedback circuit, and executes program instructions to keep the distal end of the linear motor shaft at a constant axial position, as offset by the position indicated by the linear motor shaft advancement profile, based on second control signals received from the housing position detector of the second feedback circuit so as to compensate for user movement of the device housing.

The present invention comprises methods and devices comprising a scraping element used to contact circumferentially and longitudinally the surface walls of the uterine cavity to provide for broad contact of the intended surface with the device, resulting in attainment of a sufficient volume and comprehensive tissue sample for analysis as an endometrial biopsy or screening uterine cancer. The device may provide for a reservoir for the obtained sample to be contained when removing from the uterine cavity, cervical canal, and vagina. The device may be comprised of a detachable means or be of a material that allows the user to cut the sampling head of the device for placement in collection means to maximize the amount of tissue or cells being sent to the laboratory for analysis.

A telescoping assembly such as an endobronchial ultrasound needle (EBUS) assembly includes a motor coupled to a biopsy needle within a telescoping housing to rotate (such as to oscillate) the needle during tissue harvest to improve harvesting.

Methods and apparatus are provided to facilitate the minimally invasive removal of tissue biopsies and to facilitate the direct approach to anesthetizing the chest wall, in accordance with embodiments of the present invention. A pull-type cutting device 1 comprises two coaxially nested tubes, each extending from a proximal end 21 to a distal end 22. The first tube 61 defines a guide wire lumen 23 for slidingly receiving a guide wire. The second tube 63 extends over the first tube 60 and coupled thereto at the distal end 22 defining an expandable portion 13 adjacent the distal end 22. The second tube 63 defines an inflation lumen 25 extending from the shaft proximal end 21 to the expandable portion 13. The inflation lumen 25 communicates inflation fluid from the proximal end 21 to the expandable portion 13 so as to inflate and deploy the expandable portion 13. Disposed adjacent the shaft distal end 22 is a cutting head 10 comprising the expandable portion 13 having a cutting portion 11 distal from the shaft distal end 22.

A biopsy tool includes an elongated flexible body defining a distal end and a distal biopsy member disposed at the distal end of the elongated flexible body. The biopsy member incorporates a sensor assembly configured to enable detection of a location of the sensor assembly within a patient's airways. The biopsy member has a tissue-receiving portion defining a window and including first and second longitudinally-extending faces disposed on either side of the window. The faces are angled inwardly and towards one another to define an acute interior angle therebetween. Each face defines a sharpened cutting edge. The sharpened cutting edges are disposed on either side of the window. The faces are positioned such that the sharpened cutting edges increasingly approximate one another in the proximal-to-distal direction and culminate at an apex point.

A device may comprise a work element, an outer tube co-axially disposed around a portion of the work element and a collar assembly. The work element may be configured to rotate and define proximal and distal ends, and may comprise a body portion, one or more articulable beak(s) configured to cut tissue, and a beak actuation portion. The collar assembly may be coupled to the work element away from the articulable beak(s), and may comprise a distal collar element coupled to the body portion, a middle collar element coupled to the outer tube and a proximal collar element coupled to the beak actuation portion. The distal collar element may comprise a first peripheral surface that extends around the distal collar element and that faces the proximal end and the middle collar element may comprise a second peripheral surface that that extends around the middle collar element, faces the distal end and at least partially contacts the first peripheral surface. The first and second peripheral surfaces each may comprise a smooth undulating surface that comprises a plurality of peaks and valleys. The distal, middle and proximal collar elements may be configured to control opening, closing, extending and retracting the articulable beak(s) by rotating in synchronicity, rotating differentially and/or moving toward the distal or proximal ends.