Medical researchers and orthopedic surgeons in Taiwan at Kaohsiung Veterans General Hospital continue to explore better ways to heal bones and manage defects, with their findings outlined in the recently published ‘Anatomic three-dimensional model-assisted surgical planning for treatment of pediatric hip dislocation due to osteomyelitis.’
While bone defects are already a challenge to manage, obviously the problem is compounded in children, with smaller bones being even more difficult to repair in surgery. Currently, there are few options for a good device meant for small bone repair during pediatric osteotomies—making it difficult for surgeons around the world to correct both subluxated hip joints and deformed femurs in children.
The authors (and surgeons) performed corrective surgery on a four-year-old boy with a post-osteomyelitis deformity. In preparing for the surgery, they relied on a 3D printed model of the bone for studying the condition, surgery and preparing the site for the appropriate implant. Because this type of surgery requires ‘meticulous planning,’ the doctors required both 2D and 3D assistance, in the respective forms of axial images and 3D virtual models of patient anatomies.
As the surgeons examined the patient and reviewed the CT, they noticed a genu valgus deformity (more commonly known as a ‘knock-knee’ condition). Another corrective surgery was scheduled, with 3D CT imaging examined for bone tissue analysis. The surgeons realized, however, that the procedure would be more successful overall with a life-size 3D model. They were able to outline a patient-specific plan, also bringing in additional assistance from an orthopedic consulting firm focused around 3D orthopedics and ‘patient-specific instrumentation.’
What was also very valuable to the surgery—and the outcome for the little boy involved—was that the surgeons could use the model to practice on, exercising ‘simulations of possible osteotomy options.’
“After a few osteotomy options had been analyzed, one osteotomy cut was made vertically to the femoral shaft on the subtrochanteric area, and another was made on the middle third of the femur to correct the bowing deformity of the midshaft,” stated the researchers. “Correction of femoral rotation can result in either joint translation in the coronal and axial planes or difficulty with fixation, both of which could be prevented with the help of the 3D model in the present case.”
The results of the surgeries were successful, with the patient able to stretch and begin other mobilization activity after four months.
“The result of our case suggests that the use of 3D printing models improves the postoperative performance as shown by both physical function and radiological evidence,” stated the authors in the concluding discussion.
“The use of a 3D-printed patient-specific guide is a safe, modern, affordable, and promising method that offers advantages including a shorter surgical time, optimally positioned implant placement, acceptable alignment, and a probable lower rate of complications. The utilization of 3D-printed models for skeletal deformity surgery, especially complex and difficult pediatric surgery, provides superior precision and foreseeably better outcomes. We strongly believe that with the promotion of 3D printing methodology, models for preoperative planning may soon become the gold standard for pediatric deformity correction surgery.”
3D printing continues to make impacts in the area of healing bones, regeneration and planning for complex surgeries with a range of medical devices and models. What do you think of this news? Let us know your thoughts! Join the discussion of this and other 3D printing topics at 3DPrintBoard.com.