ADJUSTMENT OF A MOTOR CONTROL COMMAND SIGNAL TO ADAPT TO SYSTEM CHANGES

Organization Name

Cilag GmbH International

Inventor(s)

Frederick E. Shelton, Iv of Hillsboro OH (US)

Shane R. Adams of Lebanon OH (US)

Kevin M. Fiebig of Cincinnati OH (US)

Raymond E. Parfett of Loveland OH (US)

Curtis A. Maples of Cincinnati OH (US)

Nicholas J. Ross of Franklin OH (US)

Taylor W. Aronhalt of Loveland OH (US)

ADJUSTMENT OF A MOTOR CONTROL COMMAND SIGNAL TO ADAPT TO SYSTEM CHANGES - A simplified explanation of the abstract

This abstract first appeared for US patent application 17957984 titled 'ADJUSTMENT OF A MOTOR CONTROL COMMAND SIGNAL TO ADAPT TO SYSTEM CHANGES

Simplified Explanation

The surgical stapling system described in the patent application includes various components such as an anvil, a blade, a motor and gear assembly, a motor power supply, and a motor controller. The system is designed to control the motor based on data received from different conditions and interactions during the surgical procedure.

• The system includes an anvil, blade, motor and gear assembly, motor power supply, and motor controller.
• The motor control signal is adjusted based on data received from different conditions and interactions during the surgical procedure.
• The motor control signal is pulse-width modulated (PWM) and the frequency is adjusted based on data related to the interaction between the blade and tissue clamped by the anvil.

Potential Applications

This technology can be applied in various surgical procedures where precise control of the motor is required, such as in minimally invasive surgeries, robotic surgeries, and other medical interventions.

Problems Solved

This technology helps in improving the accuracy and efficiency of surgical stapling procedures by adjusting the motor control signal based on real-time data and interactions during the surgery. It also helps in reducing the risk of errors and complications during the procedure.

Benefits

- Enhanced precision and control during surgical stapling procedures - Reduced risk of errors and complications - Improved efficiency and outcomes in surgical interventions

Potential Commercial Applications

The technology can be utilized by medical device companies, hospitals, surgical centers, and healthcare providers offering surgical services. It can be integrated into existing surgical stapling systems or developed as a standalone device for specific surgical applications.

Possible Prior Art

One possible prior art for this technology could be existing surgical stapling systems that use motor control for driving the stapling mechanism. These systems may not have the advanced features and capabilities described in the patent application, such as adjusting the motor control signal based on real-time data and interactions during the surgery.

Unanswered Questions

How does this technology compare to existing surgical stapling systems in terms of performance and reliability?

The article does not provide a direct comparison between this technology and existing surgical stapling systems. Further research and testing would be needed to evaluate the performance and reliability of this technology in comparison to existing systems.

What are the potential limitations or challenges in implementing this technology in different surgical settings?

The article does not address any potential limitations or challenges in implementing this technology in various surgical settings. Factors such as compatibility with different surgical instruments, training requirements for healthcare professionals, and cost implications would need to be considered for successful adoption of this technology.

Original Abstract Submitted

A surgical stapling system includes an anvil, a blade, a motor and gear assembly, a motor power supply, and a motor controller. A method of controlling the motor includes receiving first and second data indicative of operations of the motor under first and second conditions, respectively, and adjusting a motor control signal based on a difference between the first and second data. Another method includes receiving initial manufacture motor and gear assembly data from a manufacture and operational data during an initial use of the system, and adjusting parameters of the control signal based on a difference between the manufacture data and the operational data. Another method includes controlling a pulse-width modulated (PWM) motor control signal, receiving data regarding an interaction between the blade and a tissue clamped by the anvil, and adjusting a frequency of the PWM signal based on the data related to the interaction.