Research Article
BibTex RIS Cite

Surgery Dissector: Surgical Device Production With 3D Print Technology

Year 2019, Volume: 1 Issue: 1, 5 - 8, 17.06.2019

Abstract

Three dimensional (3D) print technology usage is becoming more popular in medicine and surgical sciences. There is a couple of study about using 3D print technology for surgical device production and neurosurgery in the literature. In order to adjust dissector measurements to use during the surgical operation, from patient’s CT and MRS outputs, spinal canal diameters, nerve root attached foramen diameters and disc gap wideness of the patient were measured. With these measurements, surgery dissector modelling was done by using Solidworks 3D CAD program in Dokuz Eylul University, Department of Biomechanics. Polylacticacid (PLA) filament was used in the devices during print process. In our study, surgical dissectors’ sterilization was done with vapor in 1200C and used in an operation for lumbar narrow canal diagnosed patient whose measurements were checked before the surgery. There isn’t any intraoperative complication observed during 3D printed surgery dissector usage. Although it seems that single using 3D printed surgery dissector is a disadvantage, it costs cheaper than existing surgery dissectors. In this article, we share our experiment about surgery’s one of the most important device named “surgery dissector” production with 3D print technology and it’s usage.

References

  • 1. Cohen J. Understanding, avoiding, and managing dermal filler complications. Dermatol Surg 2008;34(Suppl 1):S92.
  • 2. Kaya I., Aydın H.E., Cingoz I.D. Nöroşirürji’de 3 Boyutlu Baskılar ve Baskılama. Türk Nöroşir Derg 28(3):1-5, 2018
  • 3. Karlin L, Weinstock P, Hedequist D, Prabhu SP: The surgical treatment of spinal deformity in children with myelomeningocele: The role of personalized three-dimensional printed models. J Pediatr Orthop B 26(4):375- 382, 2017
  • 4. Kondo K, Nemoto M, Masuda H, Okonogi S, Nomoto J, Harada N, et al: Anatomical reproducibility of a head model molded by a three-dimensional printer. Neurol Med Chir 55:592–598, 2015
  • 5. Zein N, et al. 3-dimentional (3D) print of liver for preoperative planning in live donor liver transplantation. Liver Transpl 2013;19:1304.
  • 6. Klein G, Lu Y, Wang M. 3D printing and neurosurgerydready for prime time? World Neurosurg 2013;80:233.
  • 7. Giovinco N, et al. A novel combination of printed 3- dimensional anatomic templates and computer-assisted surgical simulation for virtual preoperative planning in Charcot foot reconstruction. J Foot Ankle Surg 2012;51:387.
  • 8. Kondor S, et al. On demand additive manufacturing of a basic surgical kit. J Med Devices J Med Devices 2013;7:030916.
  • 9. Rankin TM, Giovinco NA, Cucher DJ, Watts G, printing surgical instruments: are we there yet? J Surg Res. 2014;189:193-197.
  • 10. Meseguer-Olmo L, et al. In-vivo behavior of Si- hydroxyapatite/polycaprolactone/DMB scaffolds fabricated by 3D printing. J Biomed Mater Res A 2013;101:2038.
  • 11. Athanasiou K, Niederauer G, Agrawal C. Sterilization, toxicity,biocompatibility and clinical applications of polylactic acid/ polyglycolic acid copolymers. Biomaterials 1996;17:93.

3 Boyutlu Yazıcı Teknolojisi İle Cerrahi Alet Üretimi; Mikro Disektör

Year 2019, Volume: 1 Issue: 1, 5 - 8, 17.06.2019

Abstract

Üç boyutlu (3B) baskı teknolojisi kullanımı tıp ve cerrahi bilimlerinde daha popüler hale geliyor. Literatürde cerrahi cihaz üretimi ve nöroşirürji için 3D baskı teknolojisinin kullanımı hakkında birkaç çalışma vardır. Cerrahi operasyon sırasında kullanılacak disektör ölçümlerini ayarlamak için hastanın BT ve MRS çıkışlarından spinal kanal çapları, sinir köküne bağlı foramen çapları ve hastanın disk genişliği genişliği ölçüldü. Bu ölçümlerle Dokuz Eylül Üniversitesi Biyomekanik Anabilim Dalı Solidworks 3D CAD programı kullanılarak cerrahi disektör modellemesi yapıldı. Baskı işlemi sırasında cihazlarda polilaktik asit (PLA) filament kullanılmıştır. Çalışmamızda cerrahi disektörlerin sterilizasyonu 1200C'de buharla yapıldı ve ameliyattan önce ölçümleri kontrol edilen lomber dar kanal tanılı hasta operasyonunda kullanıldı. 3D baskılı cerrahi disektör kullanımı sırasında gözlenen herhangi bir intraoperatif komplikasyon yoktur. 3D baskılı cerrahi disektörü kullanma tekinin bir dezavantaj olduğu görülmesine rağmen, mevcut cerrahi disektörlerden daha ucuzdur. Bu makalede, ameliyatın “ameliyat disektörü” adı verilen en önemli cihazlardan biri olan deneyimle ilgili deneyimlerimizi 3D baskı teknolojisi ve kullanımı ile paylaşıyoruz.

References

  • 1. Cohen J. Understanding, avoiding, and managing dermal filler complications. Dermatol Surg 2008;34(Suppl 1):S92.
  • 2. Kaya I., Aydın H.E., Cingoz I.D. Nöroşirürji’de 3 Boyutlu Baskılar ve Baskılama. Türk Nöroşir Derg 28(3):1-5, 2018
  • 3. Karlin L, Weinstock P, Hedequist D, Prabhu SP: The surgical treatment of spinal deformity in children with myelomeningocele: The role of personalized three-dimensional printed models. J Pediatr Orthop B 26(4):375- 382, 2017
  • 4. Kondo K, Nemoto M, Masuda H, Okonogi S, Nomoto J, Harada N, et al: Anatomical reproducibility of a head model molded by a three-dimensional printer. Neurol Med Chir 55:592–598, 2015
  • 5. Zein N, et al. 3-dimentional (3D) print of liver for preoperative planning in live donor liver transplantation. Liver Transpl 2013;19:1304.
  • 6. Klein G, Lu Y, Wang M. 3D printing and neurosurgerydready for prime time? World Neurosurg 2013;80:233.
  • 7. Giovinco N, et al. A novel combination of printed 3- dimensional anatomic templates and computer-assisted surgical simulation for virtual preoperative planning in Charcot foot reconstruction. J Foot Ankle Surg 2012;51:387.
  • 8. Kondor S, et al. On demand additive manufacturing of a basic surgical kit. J Med Devices J Med Devices 2013;7:030916.
  • 9. Rankin TM, Giovinco NA, Cucher DJ, Watts G, printing surgical instruments: are we there yet? J Surg Res. 2014;189:193-197.
  • 10. Meseguer-Olmo L, et al. In-vivo behavior of Si- hydroxyapatite/polycaprolactone/DMB scaffolds fabricated by 3D printing. J Biomed Mater Res A 2013;101:2038.
  • 11. Athanasiou K, Niederauer G, Agrawal C. Sterilization, toxicity,biocompatibility and clinical applications of polylactic acid/ polyglycolic acid copolymers. Biomaterials 1996;17:93.
There are 11 citations in total.

Details

Primary Language English
Subjects Surgery
Journal Section Research Articles
Authors

İlker Deniz Cingöz This is me 0000-0002-0452-7606

Şafak Özyörük This is me 0000-0003-4297-3508

Buğra Hüsemoğlu This is me 0000-0003-1979-160X

Meryem Cansu Şahin This is me 0000-0002-5743-3734

Publication Date June 17, 2019
Published in Issue Year 2019 Volume: 1 Issue: 1

Cite

APA Cingöz, İ. D., Özyörük, Ş., Hüsemoğlu, B., Şahin, M. C. (2019). Surgery Dissector: Surgical Device Production With 3D Print Technology. Journal of Medical Innovation and Technology, 1(1), 5-8.
AMA Cingöz İD, Özyörük Ş, Hüsemoğlu B, Şahin MC. Surgery Dissector: Surgical Device Production With 3D Print Technology. Journal of Medical Innovation and Technology. June 2019;1(1):5-8.
Chicago Cingöz, İlker Deniz, Şafak Özyörük, Buğra Hüsemoğlu, and Meryem Cansu Şahin. “Surgery Dissector: Surgical Device Production With 3D Print Technology”. Journal of Medical Innovation and Technology 1, no. 1 (June 2019): 5-8.
EndNote Cingöz İD, Özyörük Ş, Hüsemoğlu B, Şahin MC (June 1, 2019) Surgery Dissector: Surgical Device Production With 3D Print Technology. Journal of Medical Innovation and Technology 1 1 5–8.
IEEE İ. D. Cingöz, Ş. Özyörük, B. Hüsemoğlu, and M. C. Şahin, “Surgery Dissector: Surgical Device Production With 3D Print Technology”, Journal of Medical Innovation and Technology, vol. 1, no. 1, pp. 5–8, 2019.
ISNAD Cingöz, İlker Deniz et al. “Surgery Dissector: Surgical Device Production With 3D Print Technology”. Journal of Medical Innovation and Technology 1/1 (June 2019), 5-8.
JAMA Cingöz İD, Özyörük Ş, Hüsemoğlu B, Şahin MC. Surgery Dissector: Surgical Device Production With 3D Print Technology. Journal of Medical Innovation and Technology. 2019;1:5–8.
MLA Cingöz, İlker Deniz et al. “Surgery Dissector: Surgical Device Production With 3D Print Technology”. Journal of Medical Innovation and Technology, vol. 1, no. 1, 2019, pp. 5-8.
Vancouver Cingöz İD, Özyörük Ş, Hüsemoğlu B, Şahin MC. Surgery Dissector: Surgical Device Production With 3D Print Technology. Journal of Medical Innovation and Technology. 2019;1(1):5-8.