Combined motor drive and automated longitudinal position translator for ultrasonic imaging system

A vascular imaging system with an automated longitudinal position translator includes a drive unit with a single motor to provide for rotational and longitudinal translation of a drive-cable and distally mounted transducer within a catheter assembly. The drive unit includes a main body casing and a pullback carriage on which the main body casing slidingly engages. The drive-cable is mechanically coupled to the motor, and an outer sheath of the catheter assembly is fixed to the pullback carriage via a rigid pullback arm. The imaging system can be made to operate in an automated longitudinal translation mode, wherein the main body casing of the drive unit is made to uniformly and longitudinally move relative to the pullback carriage by the drive unit motor, thus causing coincident longitudinal movement of the drive-cable (and distally located transducer) relative to the outer guide sheath of the catheter assembly.

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What is claimed is:

1. A motor drive assembly, comprising:

a main body adapted for attachment to a catheter assembly;

a motor means housed in, and secured to, the main body;

a drive shaft means for rotating an operative element disposed in the catheter assembly, the drive shaft means having a first end rotationally coupled to the motor means and a second end adapted for rotationally coupling to the operative element;

a pullback carriage means for slidingly engaging the main body;

a drive train means rotatably attached to the main body and engagable to the pullback carriage means for causing movement of the pullback carriage means relative to the main body when the drive train means is rotated; and

a gear means for communicating with the drive shaft means and drive train means, such that rotation of the drive shaft means causes corresponding rotation of the drive train means.

2. The motor drive assembly of claim 1, further comprising a pullback arm means attachable at one end to the pullback carriage means and at the other end to an outer sheath of the catheter assembly, such that, when the drive shaft means iscoupled to the operative element, movement of the main body relative to the pullback carriage means causes coincidental movement of the operative element relative to the outer sheath.

3. The motor drive assembly of claim 1, further comprising a base plate means attachable to the pullback carriage means.

4. The motor drive assembly of claim 1, wherein the main body comprises a pair of guide rail means, and the pullback carriage means comprises a pair of collar means, each collar means for slidingly engaging a respective guide rail means.

5. The motor drive assembly of claim 1, wherein the drive train means comprises:

a drive screw means rotatably mounted to the main body for rotational communication with the gear means, and

a threaded collar means pivotally mounted to the pullback carriage means and engagable with the drive screw means for causing translational movement of the main body relative to the pullback carriage means.

6. The motor drive assembly of claim 5, wherein the pullback carriage means comprises a latch means for alternately engaging or disengaging the pullback carriage means to or from the threaded collar means.

7. The motor drive assembly of claim 5, further comprising a disengage means attached to the main body for disengaging the threaded collar means from the drive screw means when the main body moves to a predetermined position relative to thepullback carriage means.

8. The motor drive assembly of claim 1, wherein the gear means comprises a reduction gear means, such that rotation of the drive shaft means at a first angular velocity causes corresponding rotation of the drive train means at a second angularvelocity, the second angular velocity being substantially less than the first angular velocity.

9. The motor drive assembly of claim 1, further comprising a motion indicator means attached to the main body for sending a signal to an external controller when the main body moves away from a start position relative to the pullback carriagemeans.

10. An imaging system, comprising:

a) a catheter assembly comprising an outer sheath and an operative element disposed therein;

b) a motor drive assembly means including:

i) a main body adapted for attachment to the catheter assembly;

ii) a motor means housed in and secured to the main body;

iii) a drive shaft means for rotationally coupling the motor means to the operative element;

iv) a pullback carriage means for slidingly engaging the main body;

v) a drive train means rotatably attached to the main body and engagable to the pullback carriage means for causing movement of the pullback carriage means relative to the main body when the drive train means is rotated; and

vi) a gear means for communicating rotationally with the respective drive shaft means and drive train means, such that rotation of the drive shaft means causes corresponding rotation of the drive train means; and

c) a pullback arm means for causing coincidental movement of the operative element relative to the outer sheath upon movement of the main body relative to the pullback carriage means when the drive shaft means is coupled to the operative element.

11. The imaging system of claim 10, further comprising a base plate means attachable to the pullback carriage means.

12. The imaging system of claim 10, wherein the main body comprises a pair of guide rail means, and the pullback carriage means comprises a pair of collar means, each collar means for slidingly engaging a respective guide rail means.

13. The imaging system of claim 10, wherein the drive train means comprises a drive screw means rotatably mounted to the main body for communicating rotationally with the gear means, and a threaded collar means pivotally mounted to the pullbackcarriage means and engagable with the drive screw means for causing translational movement of the main body relative to the pullback carriage means.

14. The imaging system of claim 13, wherein the pullback carriage means comprises a latch means for alternately engaging or disengaging the pullback carriage means to or from the threaded collar means.

15. The imaging system of claim 14, further comprising a disengage means attached to the main body for disengaging the threaded collar means from the drive screw means when the main body moves to a predetermined position relative to the pullbackcarriage means.

16. The imaging system of claim 10, wherein the gear means comprises a reduction gear means, such that rotation of the drive shaft means at a first angular velocity causes corresponding rotation of the drive train means at a second angularvelocity, the second angular velocity being substantially less than the first angular velocity.

17. A motor drive assembly, comprising:

a main body means for attaching to a catheter assembly;

a pullback carriage means for slidingly engaging the main body means;

a motor means housed in the main body means for rotationally coupling to a drive shaft means;

a drive train means for rotationally coupling the main body means to the drive shaft means, the drive train means being engagable to the pullback carriage means for causing movement of the pullback carriage means relative to the main body meanswhen the drive shaft means is rotated.

18. The motor drive assembly of claim 17, further comprising a gear reduction means for communicating rotationally with the respective drive shaft means and drive train means, such that rotation of the drive shaft means causes correspondingrotation of the drive train means at a substantially slower angular velocity.