A biopsy system includes a biopsy device, a control module, and a tissue transport tube. The biopsy device includes a probe, a needle, a cutter, and a transport valve. The needle extends distally from the probe. The cutter is movable relative to the needle and defines a cutter lumen. The holster is configured to couple to the probe. The transport valve is in communication with the cutter lumen. The control module is in communication with the biopsy device and includes a sample management assembly configured to receive one or more tissue samples severed by the cutter. The transport tube extends between the sample management assembly and the biopsy device. The transport tube is in communication with the transport valve such that the transport tube is configured to receive the one or more tissue samples severed by the cutter.

An actuator device comprises first, second and third actuators operatively connected to a biopsy needle arrangement comprising a needle inside a sheath. The needle arrangement has a closed state and an open state, a tip portion abutting a needle sheath in the closed state, and the tip portion extending from the distal end of the needle sheath in the open state. The first actuator pushes the needle distally in a sliding direction x relative to the needle sheath a first distance, d1, at which the needle arrangement is in its open state. The second actuator pushes the needle sheath distally in the sliding direction x relative to the needle a second distance, d2. The third actuator pushes the needle sheath distally in the sliding direction x relative to the needle a third distance, d3, where d3 is smaller than d2, at which the needle arrangement is in its closed state.

A marker delivery device includes a housing, a flexible push rod, and a wheel. The push rod includes a first transverse dive surface and a deployer tip. The deployer tip is configured to receive a biopsy site marker. The wheel includes a second transverse drive surface. The first transverse drive surface is configured to be driven by the second transverse drive surface to translate the push rod distally.

A biopsy arrangement for taking a biopsy in a human or animal tissue, said biopsy arrangement comprising: —a needle arrangement (3) comprising an elongated inner needle part (5) and an elongated outer needle part (7), which outer needle part (7) is a hollow member in which the inner needle part (5) fits coaxially, wherein the two needle parts can be provided in at least two different positions in relation to each other; —an activator (11) which is arranged in the biopsy arrangement (1) such that it can be moved within the biopsy arrangement, said activator (11) comprising: —a first activating part (13) which is configured to control a needle locking device (21) provided in the biopsy arrangement (1) to lock or not lock the inner needle part (5) and the outer needle part (7) to each other; and —a second activating part (15) which is configured to control a needle translation device (31) provided in the biopsy arrangement (1) to change a position of the inner (5) and outer needle parts (7) in relation to each other, said needle translation device (31) being connected to at least one of the inner or outer needle parts (5, 7), whereby a movement of the activator (11) within the biopsy arrangement (1) can affect a position of both the first and the second activating parts (13, 15) whereby both the needle locking device (21) and the needle translation device (31) can be controlled.

Medical instrument for taking a tissue sample in the body, the instrument includes an inner tube and an outer tube mounted axially slideable over the inner tube. The inner tube possesses a distal end with a cutting spiral and a proximal end to turn the spiral in the tissue to be sampled. The outer tube possesses a distal end with a cutting edge to cut loose the tissue in the spiral by sliding the outer tube over the spiral. Both tubes over at least an overlapping axial length of 30 cm are executed flexibly bendable because over said length the tubes are provided with one or more grooves which extend through the wall of the tubes and which open upon torsion in one direction.

A tissue cutting device that is especially suited for neurosurgical applications is disclosed and described, as well as alternative systems for tissue preservation and transport. The cutting device includes an outer cannula in which a reciprocating inner cannula is disposed. A tissue collector is also provided and is in fluid communication with the lumen of the inner cannula. A temperature control sleeve may be disposed around the tissue collector to control the temperature of the tissue samples. A preservation system may be supplied that is configured to deliver fluids to tissue samples in the tissue collector. A fluid supply sleeve may be disposed about the outer cannula and is selectively positionable along the length of the outer cannula.

An integrated ablation needle (100), comprising a cannula (10) and an electrode needle (20) that is movably and penetratingly installed within the cannula (10); the electrode needle (20) comprises a needle tip (21) located at the far end and a needle rod (23) connected to the near end of the needle tip (21); at least a portion that is near to the needle tip (21) of the needle rod (23) is provided with a sampling groove (231); and the far end of the cannula (10) is provided with a cutting edge (11). The cannula (10) moves along the axial direction relative to the needle rod (23) so as to expose or cover the sampling groove; when the sampling groove (231) is exposed, a tissue portion around the needle rod (23) enters the sampling groove (231); and when the sampling groove (231) is covered, the cutting edge (11) cuts off tissue inside and outside of the sampling groove (231), such that the tissue within the sampling groove (231) is acquired as a biopsy sample. Further provided is an ablation system (1000) comprising an integrated ablation needle (100). The integrated ablation needle (100) and the ablation system (1000) integrate ablation and biopsy functions on the same ablation needle (100), without needing to independently execute a biopsy step, thus avoiding repeated puncturing, reducing damage to the human body, and reducing operation time.

A biopsy system for harvesting larger volumes of tissue as compared to standard core biopsy needles. The system has a needle with a lumen, an aperture disposed at the distal end of the needle and connected to the lumen, and a cutting mechanism adapted to cut tissue. When the needle is rotated after it is inserted into a target tissue, the cutting mechanism cuts from the tissue and directs the cut tissue portions into the lumen. Multi-bioimpedance measurements are used to guide a needle and direct the application of electricity for cauterizing 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.

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.