Medical implant system for securing bone fragments

What is claimed is: 1. A medical implant system for securing bone fragments in position, said implant system comprising: a bone plate including a groove; a dynamic connector positioned within said groove of said bone plate, said dynamic connector including: a tip end having a through-hole; a tension spring having an end coupled to said tip end; and a head coupled to an opposing end of said tension spring; and an elongate flexible member extending through said through-hole of said tip end and secured to said head. 2. The medical implant system according to claim 1 , said tension spring being integrally coupled with at least one of said elongate body and said head. 3. The medical implant system according to claim 2 , said tension spring being positioned entirely within said groove of said bone plate. 4. The medical implant system according to claim 3 , said tension spring being a spiral tension spring. 5. The medical implant system according to claim 1 , said head including a groove extending parallel to a longitudinal axis of said bone plate when positioned in said groove of said bone plate and transverse to a longitudinal axis of said elongate body of said dynamic connector. 6. The medical implant system according to claim 5 , said head having at least one through-bore extending through an end wall and transverse to said groove in said head. 7. The medical implant system according to claim 6 , said at least one through-bore transecting said groove in said head. 8. The medical implant system according to claim 7 , said head including a portion abutting a side edge of said bone plate. 9. The medical implant system according to claim 1 , said dynamic connector is formed at least in part from a resilient biocompatible material. 10. The medical implant system according to claim 9 , said resilient biocompatible material being one of a polymer material, a composite material and a metal. 11. The medical implant system according to claim 10 , wherein said metal is one of titanium, stainless steel, cobalt chrome, cobalt-chromium-molybdenum, and titanium-aluminum-niobium. 12. The medical implant according to claim 10 , said polymer material being a polyaryletherketone (PAEK). 13. The medical implant according to claim 12 , said PAEK being polyetheretherketone (PEEK). 14. The medical implant system according to claim 1 , said flexible member being one of a cerclage cable, a wire, a suture and a self-locking adjustable loop construct. 15. A medical implant system, comprising: a bone plate having a groove; a dynamic connector positioned within said groove of said bone plate, said dynamic connector including: a head having an attachment structure; an elongate body coupled with said head, said elongate body having a tip end and a resilient portion allowing stretching of said elongate body in a longitudinal direction; and a flexible, elongate member coupled with said attachment structure of said head and said tip end of said elongate body. 16. The medical implant system according to claim 15 , said resilient portion being a tension spring. 17. The medical implant system according to claim 16 , said bone plate including a plurality of grooves and a corresponding plurality of dynamic connectors positioned within said grooves. 18. The medical implant system according to claim 15 , said elongate body being integrally formed with said head. 19. A method for securing bone fragments in position, the method comprising the steps of: providing a bone plate including a groove; positioning a dynamic connector within said groove of said bone plate; positioning a flexible elongate member through a through-hole in a tip end of an elongate body of said dynamic connector; positioning said bone plate in a predetermined position over the bone fragments; extending said elongate flexible member around the bone and securing said elongate flexible member to an opposite end of said dynamic connector such that tension is applied to said elongate flexible member; tensioning said elongate flexible member by way of a tension spring of said dynamic connector; and securing said elongate flexible member to a head of said dynamic connector. 20. The method according to claim 19 , further comprising the step of preloading said tension spring prior to said tensioning step. 21. The method according to claim 19 , said tension spring being integrally formed with at least one of said elongate body and said head of said dynamic connector.