Construction of an MRI-safe tachycardia lead

We claim: 1. A medical device lead, comprising: a lead body including a tubular member having a proximal end, a distal end, and a conductor lumen extending therebetween, the tubular member made of an electrically insulative material; an electrical conductor extending within the conductor lumen from the proximal end of the tubular member toward the distal end of the tubular member; a tubular conductive element disposed over the tubular member of the lead body between the proximal and distal ends thereof, the tubular conductive element including a first segment, a second segment extending distally from the first segment, and a third segment extending distally from the second segment, each of the segments having one or more kerfs formed radially therethrough in a predetermined configuration so as to affect an electrical impedance of the respective segment, wherein the one or more kerfs in each of the first and second segments are configured so that the first and second segments have a higher electrical impedance than the third segment, so that the first and second segments of the tubular conductive element are operable to inhibit induced currents in the tubular conductive element in the presence of an external source of electromagnetic energy, and wherein the electrical conductor is mechanically and electrically coupled to the tubular conductive element; and a layer of insulative material disposed over the first and second segments of the tubular conductive element, wherein an outer surface of the third segment of the tubular conductive element is uninsulated so that the third segment can be operable as a shocking electrode. 2. The medical device lead of claim 1 , wherein the electrical conductor is mechanically and electrically coupled to the tubular conductive element at a connection location disposed at a transition between the first and second segments of the tubular conductive element. 3. The medical device lead of claim 2 , wherein the kerfs in the first and second segments are formed in a helical pattern along a length thereof. 4. The medical device lead of claim 3 , wherein the kerfs in the first segment have a constant pitch along the length of the first segment. 5. The medical device lead of claim 3 , wherein the kerfs in the second segment have a constant pitch along the length of the second segment. 6. The medical device lead of claim 3 , wherein the kerfs in one or both of the first and second segments have a pitch that varies along the length of the respective segment. 7. The medical device lead of claim 6 , wherein the pitch of the kerfs in one or both of the first and second segments decrease with distance from the connection location. 8. The medical device lead of claim 1 , wherein the kerfs in the third segment include a series of kerfs each extending partially circumferentially about the tubular conductive element and distributed along the length of the third segment, wherein each kerf in the third segment is circumferentially offset from adjacent kerfs so as to cause electrical current to assume a non-linear flow path through the third segment. 9. The medical device lead of claim 1 , wherein the first, second, and third segments are formed from a single tube of conductive material. 10. The medical device lead of claim 1 , wherein one or more of the first, second and third segments are formed from separate tubes of conductive material and subsequently joined together by a weld joint. 11. A filtered electrode component for an implantable medical device lead, the filtered electrode component comprising a tubular conductive element including a first segment, a second segment extending distally from the first segment, and a third segment extending distally from the second segment, each of the segments having one or more kerfs formed radially therethrough in a predetermined configuration so as to affect an electrical impedance of the respective segment, wherein the one or more kerfs in each of the first and second segments are configured so that the first and second segments have a higher electrical impedance than the third segment, and wherein the tubular conductive element is configured to be mechanically and electrically coupled to an electrical conductor. 12. The filtered electrode component of claim 11 , wherein the kerfs in the first and second segments are formed in a helical pattern along a length thereof. 13. The filtered electrode component of claim 12 , wherein the kerfs in one or both of the first and second segments has a constant pitch along the length of the respective segment. 14. The filtered electrode component of claim 12 , wherein the kerfs in one or both of the first and second segments have a pitch that varies along the length of the respective segment. 15. The filtered electrode component of claim 14 , wherein the pitch of the kerfs in one or both of the first and second segments decreases with distance from the other of the first and second segments. 16. The filtered electrode component of claim 11 , wherein the kerfs in the third segment include a series of kerfs each extending partially circumferentially about the tubular conductive element and distributed along the length of the third segment, wherein each kerf in the third segment is circumferentially offset from adjacent kerfs so as to cause electrical current to assume a non-linear flow path through the third segment.