Kure Clinic


Robotic knee replacement, also known as robot-assisted knee surgery, is a cutting-edge surgical technique that combines the expertise of a skilled surgeon with the precision and control of robotic technology.

key advantages

 Robotic technology allows for precise planning and execution of the knee replacement surgery. The surgeon uses a robotic arm to create a 3D model of the patient’s knee joint, which helps in accurate placement and alignment of the implant components. This precision can lead to better outcomes and improved longevity of the knee replacement.

 Robotic knee replacement enables a personalized approach to surgery. The preoperative planning involves the use of advanced imaging and computer software to create a virtual model of the patient’s knee. This allows the surgeon to tailor the procedure according to the patient’s specific anatomy and condition, resulting in a better fit and alignment of the implant.

Robotic knee replacement can be performed using minimally invasive techniques, which involve smaller incisions compared to traditional open surgery. This can lead to less tissue damage, reduced pain, and faster recovery for the patient.

The precise nature of robotic knee replacement surgery can potentially reduce the risk of complications such as implant misalignment, instability, and premature wear. Accurate positioning of the implant can contribute to better joint function and improved overall satisfaction for the patient.

 With the help of robotic assistance, surgeons can achieve more accurate alignment and balance of the knee joint, which can facilitate a quicker and smoother recovery process. Patients may experience less postoperative pain, shorter hospital stays, and faster return to normal activities and mobility.

 The accurate positioning and alignment of the implant components achieved through robotic surgery may enhance the long-term durability of the knee replacement. This can potentially reduce the need for revision surgeries or implant replacements in the future.

 Due to the improved precision and customized approach, patients who undergo robotic knee replacement surgery may experience better outcomes and increased satisfaction with the results. Restored joint function, reduced pain, and improved quality of life are common benefits reported by patients.

Here's how the procedure typically works:


orthopedic surgeon




 Robotic knee replacement surgery offers a simplified approach to the procedure, making it easier for surgeons to perform the operation with precision.

 The use of a probe allows for accurate registration of the patient’s bone structure, which helps in creating a virtual model and planning the surgery accordingly.

 Robotic technology enables surgeons to assess the surgical workspace more effectively, ensuring that all necessary areas are accessible and accounted for during the procedure.

Robotic systems can quickly generate a 3D model of the patient’s knee joint using CT image data. This provides a detailed visualization for the surgeon to plan the surgery accurately.

The user interface of robotic knee replacement systems is designed with user convenience in mind, making it easier for surgeons to navigate and control the robotic arm during the procedure.

 Robotic systems facilitate efficient 3D modeling and diagnosis, reducing the time required for surgical preparation. This can streamline the overall surgical process.

Robotic knee replacement systems offer various cutting options, allowing surgeons to perform full or partial cutting as needed. The ability to change the cutting order and perform intra-operative gap checks enhances surgical flexibility.

 Robotic systems include real-time monitoring capabilities, emergency stop features, and force freeze options, ensuring the safety of both the patient and the surgical team. Surgeons can manually guide the robotic arm as needed.

Robotic knee replacement surgery involves precise pre-surgical planning and execution, ensuring consistent accuracy in implant placement. Sub-millimeter dimensional accuracy and optimal alignment contribute to better outcomes.

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