Excisional coring devices and methods for image guided hard and soft tissue biopsy

The invention claimed is: 1. A biopsy device, comprising: an outer-most tube; a first beak and a second beak, disposed at least partially within the outer-most tube, and configured to selectively assume an open or a closed configuration, each of the first and second beaks comprising: a living hinge, and at least one tendon that is radially separated from the living hinge; a living hinge actuating tube coupled to the living hinge of the first beak and to the living hinge of the second beak; a tendon actuating tube coupled to the at least one tendon of the first beak and to the at least one tendon of the second beak, at least a portion of the living hinge actuating tube being co-axially disposed and configured for relative axial movement with at least a portion of the tendon actuating tube; and a cam assembly, the cam assembly comprising a rotating barrel cam comprising separate and differently-shaped first, second and third tracks configured as endless loops around the barrel cam, a first cam follower disposed in the first track and coupled to the outer-most tube, a second cam follower disposed in the second track and coupled to the living hinge actuating tube and a third cam follower disposed in the third track and coupled to the tendon actuating tube, wherein a travel of the first, second and third cam followers within respective first, second and third tracks of the rotating cam controls an operation of the outer tube and of the first and second beaks during a penetration phase of the biopsy device in tissue, a coring phase in which the first and second beaks core through tissue and a part-off phase in which the first and second beaks sever the cored tissue to enable the severed cored tissue to be transported proximally away from the tissue. 2. The biopsy of claim 1 , wherein the living hinge actuating tube and the tendon actuating tube are further configured such that the cam assembly further controls flush fluid delivery and evacuation, within the biopsy device, to and from the first and second beaks. 3. The biopsy device of claim 1 , wherein the living hinge actuating tube comprises a plurality of first flush vanes and the tendon actuating tube comprises a plurality of second flush vanes. 4. The biopsy device of claim 3 , wherein a first amount of flush fluid is delivered to an internal tissue transport lumen of the biopsy device when the first and second flush vanes do not intersect or line up with one another and wherein a second amount of flush fluid that is larger than the first amount of flush fluid is delivered to the internal tissue transport lumen when the first and second flush vanes intersect or at least partially line up with one another. 5. The biopsy device of claim 4 , wherein the plurality of first flush vanes and the plurality of second flush vanes are configured to selectively create a vortex of flush fluid within the internal transport lumen of the biopsy device. 6. The biopsy device of claim 3 , wherein a first amount of flush fluid is delivered to an internal tissue transport lumen of the biopsy device when the first and second beaks are in the open configuration and wherein a second amount of flush fluid that is larger than the first amount of flush fluid is delivered to the internal tissue transport lumen when the first and second beaks are in the closed configuration. 7. The biopsy device of claim 1 , wherein the living hinge actuating tube and the tendon actuating tube are further configured such that the cam assembly further controls vacuum inlet pathways within the biopsy device. 8. The biopsy device of claim 1 , wherein the first and second beaks are formed of a single continuous tube of material comprising through cuts configured to define the first and second beaks. 9. The biopsy device of claim 1 , wherein the cam assembly controls relative axial movement of the outer tube, of the living hinge actuating tube and of the tendon actuating tube during the penetration, coring and part-off phases. 10. The biopsy device of claim 1 , wherein the first and second beaks are asymmetrical in shape such that, under rotation, the first and second beaks present alternating reflective surfaces that differentially reflect ultrasound illumination and create a visible beacon of reflected ultrasound illumination. 11. The biopsy device of claim 1 , wherein the first and second beaks, in the closed configuration, are configured to enable blunt dissection through tissue. 12. The biopsy device of claim 1 , wherein the barrel cam is further configured to control an amount of the first and second beaks that is exposed outside of the outer-most tube. 13. The biopsy device of claim 1 , wherein the barrel cam is further configured to at least partially retract the first and second beaks within the outer-most tube as the first and second beaks are moved to the open configuration. 14. The biopsy device of claim 1 , wherein the barrel cam is further configured to overdrive the first and second beaks in the closed configuration during the part-off phase. 15. The biopsy device of claim 1 , wherein the barrel cam is further configured to control an amount of opening and closing of the first and second beaks. 16. The biopsy device of claim 1 , wherein the barrel cam is further configured to extend the first and second beaks further out of the outer-most tube during the penetration phase.