E Scott Conner

Title: E Scott Conner: Innovator in Spinal Implant Technology

Introduction

E Scott Conner is a notable inventor based in Santa Barbara, CA (US). He has made significant contributions to the field of spinal implants, focusing on methods that enhance the stability of the spine. His innovative work has the potential to improve the quality of life for many individuals suffering from spinal issues.

Latest Patents

E Scott Conner holds a patent for "Spinal implants and methods of providing dynamic stability to the spine." This patent describes various implants designed to repair annular defects in intervertebral discs while providing dynamic stability in the vicinity of the repaired disc. The implants feature head and tail portions, with the head portion often enlarged relative to the tail. These designs aim to support adjacent vertebrae and resist collapse of the intervertebral disc. The head portions serve a spacer function, maintaining separation between adjacent vertebrae. Additionally, a tapered portion of some implants engages the end plates of adjacent vertebrae to counteract forces that may displace the implant from the intervertebral space. The tail portion may include a tail flange, which can be similar in diameter to the head portion, helping to resist forces that push the implant deeper into the intervertebral space.

Career Highlights

E Scott Conner is associated with Magellan Spine Technologies, Inc., where he continues to develop innovative solutions in spinal health. His work is characterized by a commitment to advancing medical technology and improving patient outcomes.

Collaborations

One of his notable collaborators is Jeffrey J Valko, with whom he has worked on various projects related to spinal implants and technologies.

Conclusion

E Scott Conner's contributions to spinal implant technology exemplify the impact of innovation in the medical field. His patented designs and ongoing work at Magellan Spine Technologies, Inc. highlight his dedication to enhancing spinal health and stability.