Latest Knee Replacement Surgery Techniques News

How are robots improving knee replacements in Perth?

As technology continues to advance, robots are increasingly being used in the field of orthopaedic surgery. One area where this is particularly evident is in knee replacement surgery. Dr Daniel Meykort, a specialist knee replacement surgeon in Perth is utilizing robotic technology to improve the accuracy and precision of knee replacements, ultimately leading to better outcomes for patients.

What is robotic-assisted knee replacement?

Robotic-assisted knee replacement involves using a specialized robotic arm to assist the surgeon in performing the procedure. This technology allows for precise and accurate placement of the knee implant, as well as real-time feedback during surgery.

Knee replacement technology news Perth Australia.

Knee replacement technology news Perth Australia.

What are benefits of robotic-assisted knee replacement?

  1. Increased precision: With robotic-assisted knee replacement, the surgeon can plan and execute the surgery with a higher level of accuracy. This can lead to better alignment and fit of the implant, which can result in improved function and longevity of the new knee.
  2. Customized approach: Using 3D imaging technology, surgeons can create a personalized surgical plan for each patient. This allows for a more tailored approach, taking into account factors such as the patient’s unique anatomy and any existing conditions.
  3. Real-time feedback: The robotic arm provides real-time feedback during surgery, allowing the surgeon to make adjustments as needed and ensure optimal placement of the implant.
  4. Faster recovery: Due to the precision and minimally invasive nature of robotic-assisted knee replacement, patients may experience a faster recovery time compared to traditional surgery.

What is the future of robotic-assisted knee replacement?

As technology continues to advance, robotic-assisted knee replacement will likely become even more advanced and widely used. Some potential developments in this field include:

  • Artificial intelligence: With the use of artificial intelligence, robotic systems may learn and adapt to each patient, further improving the accuracy and effectiveness of knee replacement surgery.
  • Virtual reality: Surgeons may be able to use virtual reality technology to simulate the surgery before it even takes place, allowing for more precise planning and potentially reducing surgical time.
  • Minimally invasive options: As robotics technology continues to improve, there may be more options for minimally invasive knee replacement surgery, resulting in even faster recovery times and less scarring.


Robotic-assisted knee replacement is an exciting development in the field of medicine, particularly for those experiencing knee pain and mobility issues. With its potential to improve accuracy, personalize surgical plans, and provide real-time feedback, this technology has the potential to greatly benefit patients undergoing knee replacement surgery. As technology continues to advance, it will be interesting to see how robotic-assisted knee replacement evolves and improves in the future. So, we can say that robots are improving knee replacements in Perth and around the world. Overall, this is a promising development for those in need of knee surgery and highlights the importance of utilizing technology to improve medical procedures. Let’s look forward to continued advancements in this field and the potential for even better outcomes for patients undergoing knee replacement surgery. So, if you are considering knee surgery, ask Dr Daniel Meykort about robotic-assisted options and how they can benefit you. With the help of robots, knee replacements are becoming more precise, personalized, and efficient, making the recovery process smoother and leading to better long-term results for patients. Don’t wait any longer to seek relief from knee pain – ask about robotic-assisted knee replacement today! Keep an eye on this space for more updates and advancements in this exciting field.