Design of a synthetic simulator for pediatric lumbar spine pathologies.

OBJECT Simulation has become an important tool in neurosurgical education as part of the complex process of improving residents' technical expertise while preserving patient safety. Although different simulators have already been designed for a variety of neurosurgical procedures, spine simulators are still in their infancy and, at present, there is no available simulator for lumbar spine pathologies in pediatric neurosurgery. In this paper the authors describe the peculiarities and challenges involved in developing a synthetic simulator for pediatric lumbar spine pathologies, including tethered spinal cord syndrome and open neural tube defects. METHODS The Department of Neurosurgery of the University of Illinois at Peoria, in a joint program with the Mechanical Engineering Department of Bradley University, designed and developed a general synthetic model for simulating pediatric neurosurgical interventions on the lumbar spine. The model was designed to be composed of several sequential layers, so that each layer might closely mimic the tensile properties of the natural tissues under simulation. Additionally, a system for pressure monitoring was developed to enable precise measurements of the degree of manipulation of the spinal cord. RESULTS The designed prototype successfully simulated several scenarios commonly found in pediatric neurosurgery, such as tethered spinal cord, retethered spinal cord, and fatty terminal filum, as well as meningocele, myelomeningocele, and lipomyelomeningocele. Additionally, the formulated grading system was able to account for several variables involved in the qualitative evaluation of the technical performance during the training sessions and, in association with an expert qualitative analysis of the recorded sessions, proved to be a useful feedback tool for the trainees. CONCLUSIONS Designing and building a synthetic simulator for pediatric lumbar spine pathologies poses a wide variety of unique challenges. According to the authors' experience, a modular system composed of separable layers that can be independently replaced significantly enhances the applicability of such a model, enabling its individualization to distinctive but interrelated pathologies. Moreover, the design of a system for pressure monitoring (as well as a general score that may be able to account for the overall technical quality of the trainee's performance) may further enhance the educational applications of a simulator of this kind so that it can be further incorporated into the neurosurgical residency curriculum for training and evaluation purposes.

[1]  D. M. Okada,et al.  Surgical simulator for temporal bone dissection training. , 2010, Brazilian journal of otorhinolaryngology.

[2]  V Ferrari,et al.  How to build patient‐specific synthetic abdominal anatomies. An innovative approach from physical toward hybrid surgical simulators , 2011, The international journal of medical robotics + computer assisted surgery : MRCAS.

[3]  Fedde Scheele,et al.  Validation of a new box trainer-related tracking device: the TrEndo , 2012, Surgical Endoscopy.

[4]  Raphael P. Rush,et al.  CT-based Patient-specific Simulation Software for Pedicle Screw Insertion , 2009, Journal of spinal disorders & techniques.

[5]  K. Kahol,et al.  The effect of call on neurosurgery residents' skills: implications for policy regarding resident call periods. , 2012, Journal of neurosurgery.

[6]  Georg Bretthauer,et al.  A Prospective Randomized Study to Test the Transfer of Basic Psychomotor Skills From Virtual Reality to Physical Reality in a Comparable Training Setting , 2005, Annals of surgery.

[7]  Robert M Sweet,et al.  Surgical simulation: a urological perspective. , 2008, The Journal of urology.

[8]  Jun-Jie Jing,et al.  Virtual reality surgical anatomy of the sphenoid sinus and adjacent structures by the transnasal approach. , 2012, Journal of cranio-maxillo-facial surgery : official publication of the European Association for Cranio-Maxillo-Facial Surgery.

[9]  Jose J. González Sánchez,et al.  New stereoscopic virtual reality system application to cranial nerve microvascular decompression , 2010, Acta Neurochirurgica.

[10]  P A Wieringa,et al.  Evaluation of the Mediseus® Epidural Simulator , 2012, Anaesthesia and intensive care.

[11]  Antonio Bernardo,et al.  A Three-dimensional Interactive Virtual Dissection Model to Simulate Transpetrous Surgical Avenues , 2003, Neurosurgery.

[12]  T. Pohlemann,et al.  Initial Experience Using a Pelvic Emergency Simulator to Train Reduction in Blood Loss , 2012, Clinical orthopaedics and related research.

[13]  Y. Fujii,et al.  Interactive virtual simulation using a 3D computer graphics model for microvascular decompression surgery. , 2012, Journal of neurosurgery.

[14]  Rajesh Aggarwal,et al.  Construction of an evidence-based, graduated training curriculum for D-box, a webcam-based laparoscopic basic skills trainer box. , 2012, American journal of surgery.

[15]  E. Perkins,et al.  A NOVEL SIMULATION MODEL FOR MINIMALLY INVASIVE SPINE SURGERY , 2009, Neurosurgery.

[16]  M. Apuzzo,et al.  Man, mind, and machine: the past and future of virtual reality simulation in neurologic surgery. , 2011, World neurosurgery.

[17]  N. John,et al.  Web-based surgical simulation for ventricular catheterization. , 2000, Neurosurgery.

[18]  M. Lyra,et al.  Neuroendoscopic Training: Presentation of a New Real Simulator , 2010, Minimally invasive neurosurgery : MIN.

[19]  T. Menovsky A human skull cast model for training of intracranial microneurosurgical skills , 2000, Microsurgery.

[20]  Peter Jaye,et al.  Development and implementation of centralized simulation training: evaluation of feasibility, acceptability and construct validity , 2013, BJU international.

[21]  João Flávio Nogueira,et al.  Building a Real Endoscopic Sinus and Skull-Base Surgery Simulator , 2008, Otolaryngology--head and neck surgery : official journal of American Academy of Otolaryngology-Head and Neck Surgery.

[22]  Sethuraman Panchanathan,et al.  Effect of fatigue on psychomotor and cognitive skills. , 2008, American journal of surgery.

[23]  E. Fosse,et al.  Unsupervised Virtual Reality Training May Not Increase Laparoscopic Suturing Skills , 2011, Surgical laparoscopy, endoscopy & percutaneous techniques.

[24]  S. Browd,et al.  A new fiber-mediated carbon dioxide laser facilitates pediatric spinal cord detethering. Technical note. , 2009, Journal of neurosurgery. Pediatrics.

[25]  Helmut Ringl,et al.  Degrees of Reality: Airway Anatomy of High-fidelity Human Patient Simulators and Airway Trainers , 2012, Anesthesiology.

[26]  Fady T. Charbel,et al.  Virtual reality training in neurosurgery: Review of current status and future applications , 2011, Surgical neurology international.

[27]  Charles R Doarn,et al.  The role of haptic feedback in laparoscopic training using the LapMentor II. , 2010, Journal of endourology.

[28]  V. Naik,et al.  A randomized evaluation of simulation training on performance of vascular anastomosis on a high-fidelity in vivo model: the role of deliberate practice. , 2011, The Journal of thoracic and cardiovascular surgery.

[29]  M. Downes,et al.  Simulation in Neurosurgery: A Review of Computer-Based Simulation Environments and Their Surgical Applications , 2010, Neurosurgery.

[30]  N. Tofil,et al.  Pediatric intensive care simulation course: a new paradigm in teaching. , 2011, Journal of graduate medical education.

[31]  Roger Kneebone,et al.  Simulators and the simulation environment: getting the balance right in simulation-based surgical education. , 2012, International journal of surgery.

[32]  Guang-Zhong Yang,et al.  The natural orifice simulated surgical environment (NOSsE): exploring the challenges of NOTES without the animal model. , 2009, Journal of laparoendoscopic & advanced surgical techniques. Part A.

[33]  A. A. Mehl,et al.  A model for foramen ovale puncture training: Technical note , 2006, Acta Neurochirurgica.

[34]  C. Cao,et al.  Effect of haptic feedback in laparoscopic surgery skill acquisition , 2012, Surgical Endoscopy.

[35]  E G Shifrin,et al.  Laparoscopic assisted aortic surgery. A review. , 2006, The Journal of cardiovascular surgery.

[36]  Coskun Bayrak,et al.  Mixed reality simulation of rasping procedure in artificial cervical disc replacement (ACDR) surgery , 2010, BMC Bioinformatics.

[37]  S. Botden,et al.  Augmented versus Virtual Reality Laparoscopic Simulation: What Is the Difference? , 2007, World journal of surgery.

[38]  Mayank Jain,et al.  Hernia endotrainer: results of training on self-designed hernia trainer box. , 2009, Journal of laparoendoscopic & advanced surgical techniques. Part A.

[39]  Betty Chou,et al.  Simulators and virtual reality in surgical education. , 2006, Obstetrics and gynecology clinics of North America.

[40]  J B Ra,et al.  Spine needle biopsy simulator using visual and force feedback. , 2002, Computer aided surgery : official journal of the International Society for Computer Aided Surgery.

[41]  I. A. Jones,et al.  A virtual reality surgery simulation of cutting and retraction in neurosurgery with force-feedback , 2006, Comput. Methods Programs Biomed..

[42]  Lucian Panait,et al.  The role of haptic feedback in laparoscopic simulation training. , 2009, The Journal of surgical research.

[43]  Teodor Grantcharov,et al.  Ex Vivo Technical Skills Training Transfers to the Operating Room and Enhances Cognitive Learning: A Randomized Controlled Trial , 2011, Annals of surgery.

[44]  A. Friedman,et al.  Skull base training and education using an artificial skull model created by selective laser sintering , 2010, Acta Neurochirurgica.

[45]  R. Aggarwal,et al.  Simulation‐based training and learning curves in laparoscopic Roux‐en‐Y gastric bypass , 2012, The British journal of surgery.

[46]  H Labelle,et al.  Preoperative Planning Simulator for Spinal Deformity Surgeries , 2008, Spine.

[47]  P. Suk,et al.  Porcine model of ruptured abdominal aortic aneurysm repair. , 2012, European journal of vascular and endovascular surgery : the official journal of the European Society for Vascular Surgery.

[48]  F. Charbel,et al.  VIRTUAL REALITY IN NEUROSURGICAL EDUCATION: PART‐TASK VENTRICULOSTOMY SIMULATION WITH DYNAMIC VISUAL AND HAPTIC FEEDBACK , 2007, Neurosurgery.

[49]  A. Darzi,et al.  Innovation in surgical education--a driver for change. , 2011, The surgeon : journal of the Royal Colleges of Surgeons of Edinburgh and Ireland.

[50]  A. G. Gallagher,et al.  Attempted establishment of proficiency levels for laparoscopic performance on a national scale using simulation: the results from the 2004 SAGES Minimally Invasive Surgical Trainer—Virtual Reality (MIST-VR) learning center study , 2006, Surgical Endoscopy.

[51]  Fady T Charbel,et al.  Accuracy of ventriculostomy catheter placement using a head- and hand-tracked high-resolution virtual reality simulator with haptic feedback. , 2007, Journal of neurosurgery.

[52]  Edward Leung,et al.  Homemade laparoscopic simulators for surgical trainees , 2011, The clinical teacher.

[53]  Sergio Cavalheiro,et al.  Quality assessment of a new surgical simulator for neuroendoscopic training. , 2011, Neurosurgical focus.

[54]  Dan Morris,et al.  Providing metrics and performance feedback in a surgical simulator , 2008, Computer aided surgery : official journal of the International Society for Computer Aided Surgery.

[55]  G. Ouaknine,et al.  New trend in neuroscience: low-power laser effect on peripheral and central nervous system (basic science, preclinical and clinical studies). , 1992, Neurological research.

[56]  Raymond Sawaya,et al.  A National Fundamentals Curriculum for Neurosurgery PGY1 Residents: The 2010 Society of Neurological Surgeons Boot Camp Courses , 2012, Neurosurgery.