Company Filing History:
Years Active: 2013-2017
Title: Deanna Hirzel: Innovator in Medical Technology
Introduction
Deanna Hirzel is a prominent inventor based in Chelsea, MI (US). She has made significant contributions to the field of medical technology, holding a total of 3 patents. Her innovative work focuses on enhancing surgical procedures through advanced medical devices.
Latest Patents
One of her latest patents is a medical manipulator system. This system features an operating unit that includes a grip handle and a composite input unit. It also has a working unit that is detachably mounted on the operating unit, which includes an end effector. The controller of this system is designed to manage the operating unit, determining the start and end of surgical cases while tracking the usage count of the working unit. If the usage count exceeds a preset limit, the working unit is disabled to ensure safety.
Another notable patent is a suturing and ligating method. In this method, a suture strand is wound around a gripper a predetermined number of times by turning a proximal end portion of a curved needle using a rolling mechanism. The gripper then secures the portion of the suture strand that has not been inserted into the tissue. By moving the distal-end working unit and the gripper relatively to each other, a knot is formed across the incision, enhancing the efficiency of suturing procedures.
Career Highlights
Throughout her career, Deanna has worked with reputable companies such as Karl Storz & Co. KG and Terumo Kabushiki Kaisha. Her experience in these organizations has contributed to her expertise in medical device innovation.
Collaborations
Deanna has collaborated with notable professionals in her field, including Shigeru Omori and Pari Shimoyama. These collaborations have further enriched her work and expanded her impact in medical technology.
Conclusion
Deanna Hirzel is a trailblazer in the medical technology sector, with a focus on improving surgical techniques through her innovative patents. Her contributions continue to shape the future of medical devices and enhance patient care.