Electrical surgical instrument with differential rate of closing motion speed

What is claimed is: 1. A surgical instrument, comprising: a stapling end effector having two opposing tissue-compressing surfaces defining a closure distance therebetween, wherein at least one of the tissue-compressing surfaces is movable with respect to the other of the tissue-compressing surfaces to apply a compressive force to tissue therebetween; and a handle connected to the stapling end effector and comprising: a power source; a staple-firing assembly operatively connected to the stapling end effector and, when actuated, causing the stapling end effector to staple tissue disposed between the two opposing tissue-compressing surfaces; a closure assembly comprising: an electric motor powered by the power source and comprising a drive axle configured to rotate; a rotating nut mechanically connected to the drive axle to rotate about a drive-part axis and comprising a drive pin; a drive part: comprising a body defining a multi-pitch thread mechanically connected to the drive pin of the rotating nut, the body moved by the motor in one of a direction away from the stapling end effector and towards the stapling end effector along the drive-part axis dependent upon a direction of rotation of the rotating nut; comprising a detection mechanism configured to detect a position of the drive-part along the drive-part axis; selectively moved by the motor along the drive-part axis; and operatively connected to the stapling end effector such that, when the motor is being supplied with power, the drive part advances the movable tissue-compressing surface towards the opposing tissue-compressing surface at a differential rate of speed dependent upon a position of the drive pin within the multi-pitch thread; a force detection component configured to detect the compressive force that is applied to the tissue and exhibit at least one of a mechanical and electrical change associated with the detected compressive force, the at least one change influencing a surgical procedure on the compressed tissue; and a controller operatively connected to the staple-firing assembly and the detection mechanism, the controller configured to prevent actuation of the staple-firing assembly unless the drive part is at a position corresponding to a closure distance within a pre-defined firing range, wherein the power source, the motor, and the controller are entirely contained within the handle. 2. The surgical instrument according to claim 1 , wherein a position of the drive part along the drive-part axis corresponds to a closure distance between the two opposing tissue-compressing surfaces. 3. The surgical instrument according to claim 1 , wherein the two opposing tissue-compressing surfaces comprise an anvil and a staple cartridge, and the anvil is movable with respect to the staple cartridge. 4. The surgical instrument according to claim 1 , wherein: the drive part comprises a longitudinal cylindrical body having an exterior surface with the multi-pitch thread; and the rotating nut comprises a hollow body: shaped to matingly receive at least a portion of the drive part; and having an internal surface with the drive pin onto which the multi-pitch thread of the drive part is threaded such that, when the motor is supplied with power, the hollow body rotates to move the drive part along the drive-part axis. 5. The surgical instrument according to claim 4 , wherein: the longitudinal cylindrical body of the drive part has a proximal end and a distal end; and the thread pitch of the multi-pitch thread increases from the proximal end to the distal end of the longitudinal cylindrical body. 6. The surgical instrument according to claim 5 , wherein the increase in the thread pitch causes a rate of speed of the movement of the drive part along the drive-part axis to decrease as the drive part advances the movable tissue-compressing surface towards the opposing tissue-compressing surface. 7. The surgical instrument according to claim 1 , wherein the controller is operatively connected to the motor, the controller configured to cause the motor to change a rate of speed of the movement of the drive part along the drive-part axis dependent upon the detected position of the drive part. 8. The surgical instrument according to claim 7 , wherein the detection mechanism is comprised of at least one limit switch configured to detect when the drive part is at a predetermined position. 9. The surgical instrument according to claim 1 , wherein: the electric motor of the closure assembly is a first electric motor; and the handle further comprises a firing assembly that is separate from the closure assembly and comprises a second electric motor. 10. A surgical instrument, comprising: a stapling end effector having two opposing tissue-compressing surfaces defining a closure distance therebetween, wherein at least one of the tissue-compressing surfaces is movable with respect to the other of the tissue-compressing surfaces to apply a compressive force to tissue therebetween; and a handle connected to the stapling end effector and comprising: a power source; and a staple-firing assembly operatively connected to the stapling end effector and, when actuated, causing the stapling end effector to staple tissue disposed between the two opposing tissue-compressing surfaces; a closure assembly comprising: an electric motor powered by the power source and comprising a drive axle configured to rotate; a hollow rotating body mechanically connected to the drive axle to rotate about a drive-part axis and comprising an internal surface with a protruding drive pin; a longitudinal cylindrical drive part: comprising a detection mechanism configured to detect a position of the drive-part along the drive-part axis; moved by the motor along the drive-part axis; comprising multi-pitch exterior thread mechanically connected to the drive pin of the rotating body, the hollow rotating body shaped to matingly receive at least a portion of the drive part therein; and operatively connected to the stapling end effector such that, when the motor is supplied with power, the drive part advances the movable tissue-compressing surface towards the opposing tissue-compressing surface at a differential rate of speed dependent upon a position of the drive pin within the multi-pitch thread; and a mechanical force detection component configured to receive the compressive force that is applied to the tissue and exhibit at least one of a mechanical and electrical change associated with the received compressive force, the at least one change influencing a surgical procedure on the compressed tissue; and a controller operatively connected to the staple-firing assembly and the detection mechanism, the controller configured to prevent actuation of the staple-firing assembly unless the drive part is at a position corresponding to a closure distance within a pre-defined firing range, wherein the power source, the motor, and the controller are entirely contained within the handle. 11. The surgical instrument according to claim 10 , wherein a position of the drive part along the drive-part axis corresponds to a closure distance between the two opposing tissue-compressing surfaces. 12. The surgical instrument according to claim 10 , wherein the two opposing tissue-compressing surfaces comprise an anvil and a staple cartridge, and the anvil is movable with respect to the staple cartridge. 13. The surgical instrument according to claim 10 , wherein: the longitudinal cylindrical drive part has a proximal end and a distal end; and the thread pitch of the multi-pitch thread increases from the proximal end to the distal