TY - JOUR
T1 - Post-traumatic zygomatic osteotomy and orbital floor reconstruction
AU - Peel, Sean
AU - Eggbeer, Dominic
AU - Sugar, Adrian
AU - Llewelyn, Peter
N1 - Publisher Copyright:
© Emerald Group Publishing Limited.
PY - 2016/10/17
Y1 - 2016/10/17
N2 - Purpose - Post-traumatic zygomatic osteotomy, fracture reduction, and orbital floor reconstruction pose many challenges for achieving a predictable, accurate, safe, and aesthetically pleasing result. This paper aims to describe the successful application of computer-aided design (CAD) and additive manufacturing (AM) to every stage of the process - from planning to surgery. Design/methodology/approach - A multi-disciplinary team was used - comprising surgeons, prosthetists, technicians, and designers. The patient's computed tomography scan data were segmented for bone and exported to a CAD software package. Medical models were fabricated using AM; for diagnosis, patient communication, and device verification. The surgical approach was modelled in the virtual environment and a custom surgical cutting guide, custom bone-repositioning guide, custom zygomatic implant, and custom orbital floor implant were each designed, prototyped, iterated, and validated using polymer AM prior to final fabrication using metal AM. Findings - Post-operative clinical outcomes were as planned. The patient's facial symmetry was improved, and their inability to fully close their eyelid was corrected. The length of the operation was reduced relative to the surgical team's previous experiences. Post-operative scan analysis indicated a maximum deviation from the planned location for the largest piece of mobilised bone of 3.65 mm. As a result, the orbital floor implant which was fixed to this bone demonstrated a maximum deviation of 4.44 mm from the plan. Originality/value - This represents the first application of CAD and AM to every stage of the process for this procedure - from diagnosis, to planning, and to surgery.
AB - Purpose - Post-traumatic zygomatic osteotomy, fracture reduction, and orbital floor reconstruction pose many challenges for achieving a predictable, accurate, safe, and aesthetically pleasing result. This paper aims to describe the successful application of computer-aided design (CAD) and additive manufacturing (AM) to every stage of the process - from planning to surgery. Design/methodology/approach - A multi-disciplinary team was used - comprising surgeons, prosthetists, technicians, and designers. The patient's computed tomography scan data were segmented for bone and exported to a CAD software package. Medical models were fabricated using AM; for diagnosis, patient communication, and device verification. The surgical approach was modelled in the virtual environment and a custom surgical cutting guide, custom bone-repositioning guide, custom zygomatic implant, and custom orbital floor implant were each designed, prototyped, iterated, and validated using polymer AM prior to final fabrication using metal AM. Findings - Post-operative clinical outcomes were as planned. The patient's facial symmetry was improved, and their inability to fully close their eyelid was corrected. The length of the operation was reduced relative to the surgical team's previous experiences. Post-operative scan analysis indicated a maximum deviation from the planned location for the largest piece of mobilised bone of 3.65 mm. As a result, the orbital floor implant which was fixed to this bone demonstrated a maximum deviation of 4.44 mm from the plan. Originality/value - This represents the first application of CAD and AM to every stage of the process for this procedure - from diagnosis, to planning, and to surgery.
KW - Additive manufacturing
KW - Computer-aided design
KW - Implants
KW - Medical
KW - Surgery
KW - Surgical guides
UR - http://www.scopus.com/inward/record.url?scp=84992187716&partnerID=8YFLogxK
U2 - 10.1108/RPJ-03-2015-0037
DO - 10.1108/RPJ-03-2015-0037
M3 - Article
AN - SCOPUS:84992187716
SN - 1355-2546
VL - 22
SP - 878
EP - 886
JO - Rapid Prototyping Journal
JF - Rapid Prototyping Journal
IS - 6
ER -