In vivo porcine training model for cranial neurosurgery

Jan Regelsberger; Sven Eicker; Ioannis Siasios; Daniel Hänggi; Matthias Kirsch; Peter Horn; Peter Winkler; Stefano Signoretti; Kostas Fountas; Henry Dufour; Juan A Barcia; Oliver Sakowitz; Thomas Westermaier; Michael Sabel; Oliver Heese

doi:10.1007/s10143-014-0572-4

In vivo porcine training model for cranial neurosurgery

Standard

In vivo porcine training model for cranial neurosurgery. / Regelsberger, Jan; Eicker, Sven; Siasios, Ioannis; Hänggi, Daniel; Kirsch, Matthias; Horn, Peter; Winkler, Peter; Signoretti, Stefano; Fountas, Kostas; Dufour, Henry; Barcia, Juan A; Sakowitz, Oliver; Westermaier, Thomas; Sabel, Michael; Heese, Oliver.

in: NEUROSURG REV, Jahrgang 38, Nr. 1, 01.01.2015, S. 157-63; discussion 163.

Publikationen: SCORING: Beitrag in Fachzeitschrift/Zeitung › SCORING: Zeitschriftenaufsatz › Forschung › Begutachtung

Harvard

Regelsberger, J, Eicker, S, Siasios, I, Hänggi, D, Kirsch, M, Horn, P, Winkler, P, Signoretti, S, Fountas, K, Dufour, H, Barcia, JA, Sakowitz, O, Westermaier, T, Sabel, M & Heese, O 2015, 'In vivo porcine training model for cranial neurosurgery', NEUROSURG REV, Jg. 38, Nr. 1, S. 157-63; discussion 163. https://doi.org/10.1007/s10143-014-0572-4

APA

Regelsberger, J., Eicker, S., Siasios, I., Hänggi, D., Kirsch, M., Horn, P., Winkler, P., Signoretti, S., Fountas, K., Dufour, H., Barcia, J. A., Sakowitz, O., Westermaier, T., Sabel, M., & Heese, O. (2015). In vivo porcine training model for cranial neurosurgery. NEUROSURG REV, 38(1), 157-63; discussion 163. https://doi.org/10.1007/s10143-014-0572-4

Vancouver

Regelsberger J, Eicker S, Siasios I, Hänggi D, Kirsch M, Horn P et al. In vivo porcine training model for cranial neurosurgery. NEUROSURG REV. 2015 Jan 1;38(1):157-63; discussion 163. https://doi.org/10.1007/s10143-014-0572-4

Bibtex

@article{a34916e322e1451d8c87c5be171efd57,

title = "In vivo porcine training model for cranial neurosurgery",

abstract = "Supplemental education is desirable for neurosurgical training, and the use of human cadaver specimen and virtual reality models is routine. An in vivo porcine training model for cranial neurosurgery was introduced in 2005, and our recent experience with this unique model is outlined here. For the first time, porcine anatomy is illustrated with particular respect to neurosurgical procedures. The pros and cons of this model are described. The aim of the course was to set up a laboratory scenery imitating an almost realistic operating room in which anatomy of the brain and neurosurgical techniques in a mentored environment free from time constraints could be trained. Learning objectives of the course were to learn about the microsurgical techniques in cranial neurosurgery and the management of complications. Participants were asked to evaluate the quality and utility of the programme via standardized questionnaires by a grading scale from A (best) to E (worst). In total, 154 residents have been trained on the porcine model to date. None of the participants regarded his own residency programme as structured. The bleeding and complication management (97%), the realistic laboratory set-up (89%) and the working environment (94%) were favoured by the vast majority of trainees and confirmed our previous findings. After finishing the course, the participants graded that their skills in bone drilling, dissecting the brain and preserving cerebral vessels under microscopic magnification had improved to level A and B. In vivo hands-on courses, fully equipped with microsurgical instruments, offer an outstanding training opportunity in which bleeding management on a pulsating, vital brain represents a unique training approach. Our results have shown that education programmes still lack practical training facilities in which in vivo models may act as a complementary approach in surgical training.",

author = "Jan Regelsberger and Sven Eicker and Ioannis Siasios and Daniel H{\"a}nggi and Matthias Kirsch and Peter Horn and Peter Winkler and Stefano Signoretti and Kostas Fountas and Henry Dufour and Barcia, {Juan A} and Oliver Sakowitz and Thomas Westermaier and Michael Sabel and Oliver Heese",

year = "2015",

month = jan,

day = "1",

doi = "10.1007/s10143-014-0572-4",

language = "English",

volume = "38",

pages = "157--63; discussion 163",

journal = "NEUROSURG REV",

issn = "0344-5607",

publisher = "Springer",

number = "1",

}

RIS

TY - JOUR

T1 - In vivo porcine training model for cranial neurosurgery

AU - Regelsberger, Jan

AU - Eicker, Sven

AU - Siasios, Ioannis

AU - Hänggi, Daniel

AU - Kirsch, Matthias

AU - Horn, Peter

AU - Winkler, Peter

AU - Signoretti, Stefano

AU - Fountas, Kostas

AU - Dufour, Henry

AU - Barcia, Juan A

AU - Sakowitz, Oliver

AU - Westermaier, Thomas

AU - Sabel, Michael

AU - Heese, Oliver

PY - 2015/1/1

Y1 - 2015/1/1

N2 - Supplemental education is desirable for neurosurgical training, and the use of human cadaver specimen and virtual reality models is routine. An in vivo porcine training model for cranial neurosurgery was introduced in 2005, and our recent experience with this unique model is outlined here. For the first time, porcine anatomy is illustrated with particular respect to neurosurgical procedures. The pros and cons of this model are described. The aim of the course was to set up a laboratory scenery imitating an almost realistic operating room in which anatomy of the brain and neurosurgical techniques in a mentored environment free from time constraints could be trained. Learning objectives of the course were to learn about the microsurgical techniques in cranial neurosurgery and the management of complications. Participants were asked to evaluate the quality and utility of the programme via standardized questionnaires by a grading scale from A (best) to E (worst). In total, 154 residents have been trained on the porcine model to date. None of the participants regarded his own residency programme as structured. The bleeding and complication management (97%), the realistic laboratory set-up (89%) and the working environment (94%) were favoured by the vast majority of trainees and confirmed our previous findings. After finishing the course, the participants graded that their skills in bone drilling, dissecting the brain and preserving cerebral vessels under microscopic magnification had improved to level A and B. In vivo hands-on courses, fully equipped with microsurgical instruments, offer an outstanding training opportunity in which bleeding management on a pulsating, vital brain represents a unique training approach. Our results have shown that education programmes still lack practical training facilities in which in vivo models may act as a complementary approach in surgical training.

AB - Supplemental education is desirable for neurosurgical training, and the use of human cadaver specimen and virtual reality models is routine. An in vivo porcine training model for cranial neurosurgery was introduced in 2005, and our recent experience with this unique model is outlined here. For the first time, porcine anatomy is illustrated with particular respect to neurosurgical procedures. The pros and cons of this model are described. The aim of the course was to set up a laboratory scenery imitating an almost realistic operating room in which anatomy of the brain and neurosurgical techniques in a mentored environment free from time constraints could be trained. Learning objectives of the course were to learn about the microsurgical techniques in cranial neurosurgery and the management of complications. Participants were asked to evaluate the quality and utility of the programme via standardized questionnaires by a grading scale from A (best) to E (worst). In total, 154 residents have been trained on the porcine model to date. None of the participants regarded his own residency programme as structured. The bleeding and complication management (97%), the realistic laboratory set-up (89%) and the working environment (94%) were favoured by the vast majority of trainees and confirmed our previous findings. After finishing the course, the participants graded that their skills in bone drilling, dissecting the brain and preserving cerebral vessels under microscopic magnification had improved to level A and B. In vivo hands-on courses, fully equipped with microsurgical instruments, offer an outstanding training opportunity in which bleeding management on a pulsating, vital brain represents a unique training approach. Our results have shown that education programmes still lack practical training facilities in which in vivo models may act as a complementary approach in surgical training.

U2 - 10.1007/s10143-014-0572-4

DO - 10.1007/s10143-014-0572-4

M3 - SCORING: Journal article

C2 - 25240530

VL - 38

SP - 157-63; discussion 163

JO - NEUROSURG REV

JF - NEUROSURG REV

SN - 0344-5607

IS - 1

ER -