Sternal Fixation with Synthes® Titanium Sternal Fixation System Using Preoperative 3-Dimensional Planning and a Patient-Specific Surgical Guide: A Pilot Study
A B S T R A C T
Sternal refixation or reconstruction of a median sternotomy can be indicated after treatment of deep sternal wound infection or bony non-union. Synthes® Titanium Sternal Fixation System is routinely used for sternal refixation. To perform a stable reconstruction, the titanium plates need to be bent to the anatomical shape of the sternum and adjacent ribs. The procedure offers good results, but can be, especially in the case of a complex non-union or a complex anatomy, time-consuming. Based on pre-operative CT-scan a 3D model of the sternum was printed (Materialise, Belgium). The operation was simulated using 3D software (Materialise, Belgium) and the two parts were aligned. The titanium plates were bent to fit the anatomical shape of the 3D model pre-operatively. During surgery the plates were fitted and if necessary additional bending was performed. Case 1: Total pre-operative bending time for the relatively simple anatomic shape and mal-union was 53 minutes. Total operative time was 1 hour 19 minutes. Case 2: Total pre-operative bending time for a complicated non-union and anatomy was 1 hour 21 minutes. Total operative time was 1 hour 43 minutes. Because of pre-operative bending, total operative time could be reduced by approximately 40-45%. Additional bending was rarely necessary. This case series demonstrates that the use of 3-dimensional planned patient-specific guides and preoperative preparations can help reduce operating time with satisfactory preliminary results.
Keywords
Sternal refixation, 3D printing, 3-dimensional planning, sternal non-union, thoracic surgery
Introduction
A secondary sternal fixation or reconstruction of a medial sternotomy can be indicated after median sternotomy infection or bony non-union. Although rare, they go accompanied with significant morbidity [1]. In our center we routinely use Synthes® Titanium Sternal Fixation System for a secondary sternal reconstruction after bony non-union or after healing of median sternotomy infection. The procedure offers good results, but can be, especially in the case of a complex non-union, or a complex anatomy, time-consuming [1]. To perform a good reconstruction the titanium plates, need to be bent to the anatomical shape of the sternum and adjacent ribs, to ensure stable refixation, this part of the perioperative procedure is very time-consuming. Working with Materialise (Leuven, Belgium), we developed a technique using 3-dimensional planning and patient specific surgical 3D-printed guide to simplify and quicken the procedure.
Using preoperative 3-dimensional planning and patient-specific surgical guides to aid in surgical procedures isn’t something new, it has been in use since a few years, mostly used in orthopaedic procedures [2, 3]. We describe how we perform a secondary sternal refixation after non-union of a medial sternotomy using a preprinted 3D model of the patient’s sternum to achieve reduction in operating time. We were able to reduce operating time by almost fifty percent. We could bend the titanium fixation plates in almost perfect anatomical shape before the procedure itself took place. We describe two patients where we were able to use this technique. Three-dimensional planning based on computed tomography images of the mal-united and non-united sternum enabled us to produce a patient-specific 3D printed sternum and enabled us to custom pre-bend the titanium plates. This article will describe how we do it.
Methods
Two patients were included with indication for sternal refixation or reconstruction following sternal dehiscence after cardiac surgery. All patients undergo a high-density computed tomography (CT) of the chest to achieve optimal image quality. Then, pre-operatively, the procedure was simulated through software (Materialise, Belgium), including emulated reduction of both sternal halves into anatomical position. The resulting 3-dimensional image was then used to print the patient specific anatomical model. On this real-life representable sternal model, the titanium sternal plates were bent, in anatomical position, removing the necessity for bending them perioperatively. The actual perioperative procedure remained unchanged. Reuse of the old incision, removing of the old stainless-steel wires, if in situ, debridement of the sternal edges, obtainment of hemostasis. Mobilizing of the pectoralis major muscles to expose the ribs, and reduction of the sternal halves. After reduction the plates are fitted in place and fixated on the sternum, rarely additional bending is necessary, and if needed, the additional bend is minimal.
Results
Case 1
Total bending time for a relatively simple anatomic shape and mal-union was 53 minutes (Figure 1). Total operative time was 1 hour 19 minutes.
Case 2
Total bending time for a complex non-union and anatomy was 1 hour 21 minutes (Figure 2). Total operative time was 1 hour 43 minutes. One year follow-up yielded good clinical and cosmetic results.
Discussion
Both cases have shown a reduction in operative time, in our center, as in previous experience without the pre-bent titanium plates, more than double the amount of time would have been spent in the described cases. Attention to the exact same reduction as performed during the emulation of the procedure is critical to achieve good reduction of the sternal halves, without the exact same reduction, there could be more time needed to adjust the titanium plates, eliminating some advantage of using the preprinted model. A possible reduction in length of stay or reduced use of analgesia when using the preoperative 3-dimensional planning and patient-specific surgical guide is out of scope of this pilot project and is subject to more research.
Conclusion
This pilot study demonstrates that 3-dimensional planned patient-specific guides and preoperative preparations can help reduce operating time with satisfactory preliminary results.
Ethics Approval and Consent to Participate
Consent acquired and ethical committee not applicable.
Consent for Publication
Consent for publication was obtained.
Availability of Data and Material
Available.
Competing Interests
None.
Funding
The funding was obtained from Research Grant Sint Antonius Hospital Nieuwegein.
Author Contributions
F. W. N. Haenen: author, design; R. J. Vos: co-author, pre-operative support; E. J. Daeter: supervisor, surgeon, design.
Acknowledgement
Materialise, Leuven, Belgium.
Article Info
Article Type
Research ArticlePublication history
Received:
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Copyright
© 2023 Filip W. N. Haenen. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Hosting by Science Repository.
DOI: 10.31487/j.SCR.2021.08.15
Author Info
Filip W. N. Haenen
R.J. Vos
E.J. Daeter
Corresponding Author
Filip W. N. HaenenDepartment of Cardiac and Thoracic Surgery, Sint Antonius Hospital, Nieuwegein, The Netherlands
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