Three-dimensional printing of a complex CHD to plan surgical repair

Khaled Hadeed; Yves Dulac; Philippe Acar

doi:10.1017/S1047951116000755

Abstract

We used three-dimensional printing technology to create an anatomical three-dimensional model of a very rare and complex cyanotic CHD in a newborn, consisting of double-outlet left ventricle, ventricular septal defect, and pulmonary stenosis. This case demonstrates how this new innovative technology allows better understanding of the anatomy in complex CHDs and permits to better plan the surgical repair.

References

1. Costello, JP, Olivieri, LJ, Krieger, A, et al. Utilizing three-dimensional printing technology to assess the feasibility of high-fidelity synthetic ventricular septal defect models for simulation in medical education. World J Pediatr Congenit Heart Surg 2014; 5: 421–426.Google Scholar

2. Dankowski, R, Baszko, A, Sutherland, M, et al. 3D heart model printing for preparation of percutaneous structural interventions: description of the technology and case report. Kardiol Pol 2014; 72: 546–551.Google Scholar

3. Olivieri, L, Krieger, A, Chen, MY, Kim, P, Kanter, JP. 3D heart model guides complex stent angioplasty of pulmonary venous baffle obstruction in a mustard repair of D-TGA. Int J Cardiol 2014; 172: e297–e298.Google Scholar

4. Olivieri, LJ, Krieger, A, Loke, YH, et al. Three-dimensional printing of intracardiac defects from three-dimensional echocardiographic images: feasibility and relative accuracy. J Am Soc Echocardiogr 2015; 28: 392–397.Google Scholar

5. Samuel, BP, Pinto, C, Pietila, T, Vettukattil, JJ. Ultrasound-derived three-dimensional printing in congenital heart disease. J Digit Imaging 2015; 28: 459–461.Google Scholar

6. Van Praagh, R, Weinberg, PM, Srebro, JP. Double-outlet left ventricle. In: Adams FH, Emmanouilides GC, Reimenschneider TA, (eds). Moss’ Heart Disease in Infants, Children, and Adolescents. Williams & Wilkins, Baltimore, 1989: 461–485.Google Scholar

7. Bharati, S, Lev, M, Stewart, R, McAllister, HA, Kirklin, JW. The morphologic spectrum of double outlet left ventricle and its surgical significance. Circulation 1978; 58: 558–565.Google Scholar

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Chepelev, Leonid Wake, Nicole Ryan, Justin Althobaity, Waleed Gupta, Ashish Arribas, Elsa Santiago, Lumarie Ballard, David H Wang, Kenneth C Weadock, William Ionita, Ciprian N Mitsouras, Dimitrios Morris, Jonathan Matsumoto, Jane Christensen, Andy Liacouras, Peter Rybicki, Frank J and Sheikh, Adnan 2018. Radiological Society of North America (RSNA) 3D printing Special Interest Group (SIG): guidelines for medical 3D printing and appropriateness for clinical scenarios. 3D Printing in Medicine, Vol. 4, Issue. 1,

Lau, Ivan and Sun, Zhonghua 2018. Three‐dimensional printing in congenital heart disease: A systematic review. Journal of Medical Radiation Sciences, Vol. 65, Issue. 3, p. 226.

Wang, Judy Coles-Black, Jasamine Matalanis, George and Chuen, Jason 2018. Innovations in cardiac surgery: techniques and applications of 3D printing. Journal of 3D Printing in Medicine, Vol. 2, Issue. 4, p. 179.

El Sabbagh, Abdallah Eleid, Mackram F. Al-Hijji, Mohammed Anavekar, Nandan S. Holmes, David R. Nkomo, Vuyisile T. Oderich, Gustavo S. Cassivi, Stephen D. Said, Sameh M. Rihal, Charanjit S. Matsumoto, Jane M. and Foley, Thomas A. 2018. The Various Applications of 3D Printing in Cardiovascular Diseases. Current Cardiology Reports, Vol. 20, Issue. 6,

Hadeed, Khaled Acar, Philippe Dulac, Yves Cuttone, Fabio Alacoque, Xavier and Karsenty, Clément 2018. Cardiac 3D printing for better understanding of congenital heart disease. Archives of Cardiovascular Diseases, Vol. 111, Issue. 1, p. 1.

Anwar, Shafkat Singh, Gautam K. Miller, Jacob Sharma, Monica Manning, Peter Billadello, Joseph J. Eghtesady, Pirooz and Woodard, Pamela K. 2018. 3D Printing is a Transformative Technology in Congenital Heart Disease. JACC: Basic to Translational Science, Vol. 3, Issue. 2, p. 294.

Boll, Liliana Fortini Cavalheiro Rodrigues, Guilherme Oberto Rodrigues, Clarissa Garcia Bertollo, Felipe Luiz Irigoyen, Maria Claudia and Goldmeier, Silvia 2019. Using a 3D printer in cardiac valve surgery: a systematic review. Revista da Associação Médica Brasileira, Vol. 65, Issue. 6, p. 818.

Rooney, Michael K. Rosenberg, David M. Braunstein, Steve Cunha, Adam Damato, Antonio L. Ehler, Eric Pawlicki, Todd Robar, James Tatebe, Ken and Golden, Daniel W. 2020. Three‐dimensional printing in radiation oncology: A systematic review of the literature. Journal of Applied Clinical Medical Physics, Vol. 21, Issue. 8, p. 15.

Valverde, Israel 2020. 3-Dimensional Modeling in Cardiovascular Disease. p. 123.

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Francoisse, Caitlin A. Sescleifer, Anne M. King, Wilson T. and Lin, Alexander Y. 2021. Three-dimensional printing in medicine: a systematic review of pediatric applications. Pediatric Research, Vol. 89, Issue. 3, p. 415.

Yang, Jian Pan, Xiangbin Pan, Wenzhi Yang, Meng Liu, Jincheng and Tang, Jiayou 2021. Cardiovascular 3D Printing. p. 35.

Patriki, Dimitri and Giannopoulos, Andreas A. 2022. Modelling Congenital Heart Disease. p. 239.

Bulbul, Ziad El Rassi, Issam Hamade, Ramsey Tamim, Hani and Bitar, Fadi 2023. Three-dimensional printing of mitral valve models using echocardiographic data improves the knowledge of cardiology fellow physicians in training. Frontiers in Cardiovascular Medicine, Vol. 10, Issue. ,

Forni, Riccardo Agnarsdóttir, Sólveig Torfason, Bjarni and Gargiulo, Paolo 2023. Handbook of Surgical Planning and 3D Printing. p. 143.

Peek, Jette J Bakhuis, Wouter Sadeghi, Amir H Veen, Kevin M Roest, Arno A W Bruining, Nico van Walsum, Theo Hazekamp, Mark G and Bogers, Ad J J C 2023. Optimized preoperative planning of double outlet right ventricle patients by 3D printing and virtual reality: a pilot study. Interdisciplinary CardioVascular and Thoracic Surgery, Vol. 37, Issue. 2,

Tarca, Adrian Woo, Ngai Bain, Shahira Crouchley, David McNulty, Eamonn and Yim, Deane 2023. 3D Printed Cardiac Models as an Adjunct to Traditional Teaching of Anatomy in Congenital Heart Disease—A Randomised Controlled Study. Heart, Lung and Circulation, Vol. 32, Issue. 12, p. 1443.

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Three-dimensional printing of a complex CHD to plan surgical repair

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