Surgical access system and related methods

We claim: 1. A retractor assembly for creating an operative corridor to a spinal surgical target site, comprising: a retractor body and a plurality retractor blades extending generally perpendicularly to the retractor body, the retractor body being operable to separate the plurality of retractor blades relative to each to other to retract tissue away from an interior of the retractor blades when the tissue retractor assembly is advanced to the surgical target site and the retractor blades are separated to thereby form an operative corridor to the surgical target site; and a supplemental retractor blade assembly attachable to two of the plurality of retractor blades, the supplemental retractor blade assembly comprising an elongated supplemental retractor blade and a crossbar connector, the crossbar connector extending from a first end to a second end and including an elongated slot, the elongated slot opening in the first end and configured to engage a post extending perpendicularly from each of the two retractor blades. 2. The retractor assembly of claim 1 , wherein said post is on each of said two retractor blades, the posts being configured to be received in the elongated slot through the opening in the first end, the posts further including enlarged ends that are larger than a height of the slot to prevent disengagement of the crossbar connector from the two blades. 3. The retractor assembly of claim 2 , wherein the posts of the two retractor blades can slide along the elongated slot while the supplemental retractor blade is maintained in a fixed position in order to permit opening or closing of the two retractor blades. 4. The retractor assembly of claim 2 , wherein the crossbar connector includes a rear face configured to interlock with a series of grooves on the supplemental retractor blade to maintain a desired depth of the supplemental retractor blade relative to the crossbar connector. 5. The retractor assembly of claim 1 , wherein the supplemental retractor blade includes a handle attached thereto. 6. The retractor assembly of claim 1 , wherein the plurality of retractor blades includes at least three retractor blades, the at least three retractor blades comprising a caudal blade, a cephalad blade, and a center blade, and wherein the crossbar connector engages the caudal blade and the cephalad blade. 7. The retractor assembly of claim 1 , wherein the crossbar connector elongate slot slidably receives the post of each of the two retractor blades to attach the crossbar connector to the two retractor blades of the retractor assembly. 8. The retractor assembly of claim 7 , wherein the crossbar connector further including a rear face configured to engage the supplemental retractor blade. 9. A system for creating an operative corridor to a spinal surgical target site, comprising: a retractor assembly including a retractor body and a plurality retractor blades extending generally perpendicularly to the retractor body, the retractor body being operable to separate the plurality of retractor blades relative to each other to retract tissue away from an interior of the retractor blades when the tissue retractor assembly is advanced to the surgical target site and the retractor blades are separated to thereby form an operative corridor to the surgical target site, wherein at least one of the plurality of blades is an electrode blade configured to couple to an electrode member, the electrode blade having an interior surface that faces towards the operative corridor and an exterior surface, a distal end with a distal end surface, and a proximal end, the electrode blade having an elongate slot extending longitudinally through the electrode blade and opening along the exterior surface; and an electrode member removably couplable with said electrode blade and configured to transmit an electrical stimulation signal to tissue adjacent the distal end of the electrode blade, the electrode member configured to be slideably received along the elongate slot. 10. The system of claim 9 , wherein the electrode member comprises a nonconductive material having a conductive trace extending the length thereof between a proximal exposed area and a distal exposed area. 11. The system of claim 10 , wherein the proximal exposed area is configured to be in electrical communication with a nerve monitoring system. 12. The system of claim 10 , wherein the conductive trace is insulated with a dielectric coating to prevent current shunting along its length between the proximal and distal exposed areas. 13. The system of claim 10 , wherein the electrode blade further comprises an aperture connecting to the elongate slot adjacent the distal end of the electrode blade. 14. The system of claim 13 , wherein the distal exposed area of the elongate electrode is configured to align with the aperture of the electrode blade. 15. A retractor assembly for creating an operative corridor to a spinal surgical target site, comprising: a retractor body and a plurality retractor blades extending generally perpendicularly to the retractor body, the retractor body being operable to separate the plurality of retractor blades relative to each other to retract tissue away from an interior of the retractor blades when the retractor assembly is advanced to the surgical target site and the retractor blades are separated to thereby form an operative corridor to the surgical target site, the retractor body also being operable to splay at least one of the plurality of retractor blades such that a distal end of the retractor blade extends wider than a proximal end of the retractor blade, wherein splaying of the at least one retractor blade is controlled by a rack and pinion gear situated in the retractor body driven by a lead screw. 16. The retractor assembly of claim 15 , wherein the gear provides for continuous splay. 17. The retractor assembly of claim 15 , wherein the retractor assembly includes three blades and two of the three retractor blades are splayable. 18. The retractor assembly of claim 17 , wherein each of the two splayable retractor blades are independently controlled by a dedicated gear mechanism. 19. The retractor assembly of claim 18 , wherein each of the independently controllable gear mechanisms provide for continuous splay. 20. The retractor assembly of claim 19 , wherein each of the independently controllable gear mechanisms is a rack and pinion gear driven by a lead screw.