Biopsy probe mechanism having multiple echogenic features

What is claimed is: 1. A method of operating a biopsy probe mechanism, comprising: providing an elongate sample receiving member having a proximal end, a distal end, a longitudinal axis, and having a sample receiving notch, the sample receiving notch being located proximal to the distal end; providing a cutting cannula arranged coaxially with the elongate sample receiving member, the elongate sample receiving member and the cutting cannula being movable relative to one another along the longitudinal axis; establishing a first echogenic feature on the elongate sample receiving member; establishing a second echogenic feature on the cutting cannula, the elongate sample receiving member and the cutting cannula having a first position in which the first echogenic feature is in longitudinal alignment with the second echogenic feature, and wherein the first echogenic feature and the second echogenic feature are out of longitudinal alignment when the elongate sample receiving member and the cutting cannula are moved relative to one another from the first position; establishing a third echogenic feature on the elongate sample receiving member, with one of the first echogenic feature and the third echogenic feature being located distal to the sample receiving notch and the other of the first echogenic feature and the third echogenic feature being located proximal to the sample receiving notch; and establishing a fourth echogenic feature on the cutting cannula at a location spaced apart from the second echogenic feature, the third echogenic feature being in longitudinal alignment with the fourth echogenic feature when the elongate sample receiving member and the cutting cannula are in the first position, and wherein the third echogenic feature and the fourth echogenic feature are out of longitudinal alignment when the elongate sample receiving member and the cutting cannula are moved relative to one another from the first position. 2. The method of claim 1 , wherein the sample receiving notch in the elongate sample receiving member is closed by the cutting cannula when the first echogenic feature and the second echogenic feature are in longitudinal alignment, and wherein when the sample receiving notch is opened the first echogenic feature and the second echogenic feature are out of longitudinal alignment. 3. The method of claim 1 , wherein each echogenic feature includes at least one circumferential echogenic band. 4. The method of claim 1 , wherein each echogenic feature has at least one of a roughened surface, an embedded material, a machined pattern, and a particulate coating for providing a distinct echogenic reflection from surrounding areas during ultrasound imaging. 5. The method of claim 1 , wherein the elongate sample receiving member and the cutting cannula are incorporated into a disposable device. 6. The method of claim 1 , comprising integrating the biopsy probe mechanism into a biopsy apparatus having a driver for driving the biopsy probe mechanism. 7. A method of providing a biopsy apparatus for use in conjunction with an ultrasound device, comprising: providing a driver assembly; and providing a biopsy probe mechanism coupled to the driver assembly, the driver assembly providing operative control over the biopsy probe mechanism, the biopsy probe mechanism including: an elongate sample receiving member having a proximal end, a distal end, and a sample receiving notch located proximal to the distal end, the elongate sample receiving member having a longitudinal axis and a cutting cannula arranged coaxially with the elongate sample receiving member, and including a first echogenic feature established on the elongate sample receiving member and a second echogenic feature established on the cutting cannula, and the elongate sample receiving member and the cutting cannula having a first position in which the first echogenic feature is in longitudinal alignment with the second echogenic feature to facilitate creation of a single echogenic reflection, and when the elongate sample receiving member and the cutting cannula are moved relative to one another from the first position, the first echogenic feature and the second echogenic feature are out of longitudinal alignment to facilitate creation of separate individual echogenic reflections with respect to the first echogenic feature and the second echogenic feature, the elongate sample receiving member having a third echogenic feature, with one of the first echogenic feature and the third echogenic feature being located distal to the sample receiving notch and the other of the first echogenic feature and the third echogenic feature being located proximal to the sample receiving notch, and wherein the cutting cannula has a fourth echogenic feature spaced apart from the second echogenic feature, such that when the elongate sample receiving member and the cutting cannula are in the first position, the third echogenic feature is in longitudinal alignment with the fourth echogenic feature to facilitate creation of a single echogenic reflection, and when the elongate sample receiving member and the cutting cannula are not in the first position, the third echogenic feature is out of longitudinal alignment with the fourth echogenic feature to facilitate creation of separate individual echogenic reflections with respect to the third echogenic feature and the fourth echogenic feature. 8. The biopsy apparatus of claim 7 , wherein each echogenic feature includes at least one circumferential echogenic band. 9. The biopsy apparatus of claim 7 , wherein each echogenic feature is formed as at least one of a roughened surface, an embedded material, a machined pattern and a particulate coating for providing a distinct echogenic reflection from surrounding areas during ultrasound imaging. 10. The biopsy apparatus of claim 7 , wherein the elongate sample receiving member has a sample receiving notch that is closed by the cutting cannula when in the first position. 11. A method of providing a biopsy probe mechanism, comprising: providing an elongate sample receiving member having a proximal end, a distal end, a longitudinal axis, and having a sample receiving notch, the sample receiving notch being located proximal to the distal end; coaxially arranging a cutting cannula with the elongate sample receiving member, the elongate sample receiving member and the cutting cannula being movable relative to one another along the longitudinal axis; establishing a first echogenic feature on the elongate sample receiving member; establishing a second echogenic feature on the cutting cannula; establishing a third echogenic feature on the elongate sample receiving member spaced apart from the first echogenic feature, with one of the first echogenic feature and the third echogenic feature being located distal to the sample receiving notch and the other of the first echogenic feature and the third echogenic feature being located proximal to the sample receiving notch; establishing a fourth echogenic feature on the cutting cannula at a location spaced apart from the second echogenic feature; and defining a first position of the elongate sample receiving member and the cutting cannula in which the first echogenic feature is in longitudinal alignment with the second echogenic feature, and in which the third echogenic feature is in longitudinal alignment with the fourth echogenic feature, and when the elongate sample receiving member and the cutting cannula are moved relative to one another from the first position, the first echogenic feature and the second echogenic feature are out of longitudinal alignment, and the third echogenic feature and the fourth echogenic feature are out