Provided herein are methods and a device for collecting biological samples from a subject. In particular, the present disclosure relates to a device designed to specifically capture samples within the target areas of a patient for specific cell collection for particular diagnosis.

A biopsy device includes a probe, a holster, and a probe lock. The probe includes a probe body and a needle extending distally from the probe body. The probe is releasably couplable to the holster. The probe lock includes a lock member configured to move laterally relative to a longitudinal axis defined by the needle to selectively lock the probe to the holster.

A biopsy device includes a cannula and a specimen collector. The cannula has a proximal end and a longitudinal axis. The specimen collector contains the proximal end of the cannula. The specimen collector has a removable sample receiving cartridge that is removable along the longitudinal axis of the cannula to expose the proximal end of the cannula.

Certain aspects relate to biopsy apparatuses, systems and techniques for biopsy using a biopsy pattern. Some aspects relate to moving a distal portion of a medical instrument to one or more sample locations of the biopsy pattern and guiding the instrument to obtain tissue samples from the sample locations within the biopsy pattern. Some aspects relate to obtaining the biopsy pattern and adjusting the sample locations within the biopsy pattern based on various factors such as anatomical features.

A sample container for use in imaging includes a bottom portion and a wall portion extending upwardly from the bottom portion. The lid overlies the cavity when in the closed position, and a plurality of latches are coupled to the lid and extend substantially orthogonally from the lid. A plurality of recesses are coupled to the wall portion, each recess of the plurality of recesses being adapted and configured to receive one of the plurality of latches. A first alignment structure is within the cavity and is adapted and configured to align a sample lengthwise and widthwise within the cavity such that the sample is aligned relative to an imaging system when the sample container is engaged with the imaging system. A second alignment structure is at least partially within the cavity, and is adapted and configured to align the sample height wise within the cavity.

An insertion tool guide for a medical procedure like a biopsy. The tool guide includes (a) a frame configured to be adjoined to a medical image modality and maintain an insertion angle aligned with a plane of view generated by the medical image modality; (b) a guide body having an adjustable channel configured to receive and translate an insertion tool; (c) a main channel defined by the frame configured to allow the guide body and the insertion tool to rotate within a plane of movement; (d) a guide channel formed along one side of the frame configured to allow the guide body to translate along its length; and (e) a peg extending from the guide body and through the guide channel to secure the guide body within the frame. The guide body is configured to rotate about an axis defined by the peg.

A biopsy device includes a disposable elongated probe component having a coaxial arrangement of an elongated tubular section and an elongated tissue cutting member, and having a coaxial arrangement of a first driven gear, a second driven gear, and a third driven gear. The first driven gear is configured to rotate the elongated tubular section. The second driven gear is configured to rotate to longitudinally move the elongated tissue cutting member. The third driven gear is configured to rotate or oscillate the elongated tissue cutting member. A driver component has a coaxial arrangement of a first drive gear, a second drive gear, and a third drive gear. The first drive gear is drivably engaged with the first driven gear. The second drive gear is drivably engaged with the second driven gear. The third drive gear is drivably engaged with the third driven gear.

A system for generating data relating to a tissue core comprises a core needle biopsy module configured to obtain a tissue core from a locus within the body, and a tissue disintegration module operably connected to the core needle biopsy module and configured to receive a tissue core from the core needle biopsy module and convert at least a portion of the tissue core into gaseous tissue molecules. The system also comprises first vacuum pump means configured to convey a tissue core from the needle biopsy module to the tissue disintegration module, and second vacuum pump means configured to convey gaseous tissue molecules from the tissue disintegration module to an analyser module.

The embodiments presented herein present a single needle core biopsy instrument and modification required that convert the single needle core biopsy instrument to a dual needle core biopsy instrument. Depending on the design, the dual needle core biopsy instrument permits the simultaneous extraction of tissue or bone specimens taken at between 0.1 mm and 3 mm apart.

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.