Company Filing History:
3 out of 167 
1 out of 31 Years Active: 2003-2006
Title: Ewin Michael Kiser: Innovator in Cardiology Technology
Introduction
Ewin Michael Kiser is a notable inventor based in Katy, TX (US), recognized for his contributions to cardiology technology. He holds a total of 4 patents, showcasing his innovative approach to improving real-time data access during cardiology procedures. His work has significantly impacted the way medical professionals interact with data during critical procedures.
Latest Patents
Kiser's latest patents include a "Distributed multi-user replication-based system for real-time data access during cardiology procedures." This system allows for simultaneous data display from a cardiology procedure across multiple devices and locations. It utilizes various replication topologies to ensure that a cardiology study can be accessed in real-time, whether locally or remotely.
Another significant patent is the "Distributed real-time catalog-based annotation and documentation system for cardiology procedures." This system enables users to display and manipulate data from cardiology procedures on multiple devices. It allows for annotations to be made at various locations, ensuring that all modifications are communicated back to the acquisition station for comprehensive access.
Career Highlights
Throughout his career, Kiser has worked with prominent companies such as GE Medical Systems Information Technologies GmbH and GE Medical Systems. His experience in these organizations has contributed to his expertise in developing innovative solutions for the medical field.
Collaborations
Kiser has collaborated with various professionals in the industry, including his coworker Stephen T. Stoycos. Their joint efforts have further advanced the development of technologies that enhance cardiology procedures.
Conclusion
Ewin Michael Kiser's contributions to cardiology technology through his patents and career experiences highlight his commitment to innovation in the medical field. His work continues to influence how data is accessed and utilized during critical medical procedures.