Neurosurgical education [Neurosurgery Wiki]

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====== Neurosurgical education ======

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Neurosurgical [[education]] is a highly specialized, rigorous process designed to train surgeons in the complex [[skill]]s needed for [[neurosurgery]], focusing on both clinical and technical [[expertise]]. The training pathway typically includes:

1. **[[Undergraduate Medical Education]]** – Aspiring neurosurgeons complete a medical degree (MD or equivalent), which generally spans 4–6 years and includes foundational coursework in anatomy, physiology, and pathology.

2. **[[Neurosurgical Residency]]** – Post-medical school, neurosurgical [[trainee]]s enter a residency program that can last between 5 and 7 years, depending on the country. Residency combines hands-on surgical training with didactics, covering topics such as neuroanatomy, neuropathology, and neuroimaging. During this time, residents perform various neurosurgical procedures under supervision and gradually progress to independent practice.

3. **[[Fellowship]]s** – After residency, many neurosurgeons pursue fellowships to gain advanced expertise in subspecialties such as spine surgery, pediatric neurosurgery, functional neurosurgery, cerebrovascular surgery, and neuro-oncology. Fellowships typically last 1–2 years and allow for focused, in-depth training.

4. **Continuous Professional Development (CPD)** – Given the rapid advancement of neurosurgical techniques and technology, neurosurgeons engage in ongoing education, including attending [[conference]]s, [[workshop]]s, and [[course]]s to stay current on best practices and innovations.

5. **Global Neurosurgical Education Initiatives** – Organizations like the World Federation of Neurosurgical Societies (WFNS), World Health Organization (WHO), and various neurosurgical associations support global initiatives to enhance neurosurgical training, particularly in low- and middle-income countries (LMICs). These include:
   - **[[Online]] and [[virtual]] [[learning]] [[platform]]s** to provide accessible training materials and live demonstrations.
   - **Mentorship and exchange programs** where surgeons from high-resource settings provide training to surgeons in LMICs.
   - **WFNS Global Neurosurgery Committee** programs to support neurosurgical education and training in underserved regions through advocacy, resource distribution, and policy development.

These combined efforts aim to ensure that neurosurgical training is accessible, up-to-date, and globally standardized, ultimately improving patient outcomes across diverse healthcare systems.
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The [[education]] and [[training]] needed to become a [[neurosurgeon]] consist of a long and demanding [[program]] that consists of acquiring a solid theoretical [[background]] and clinical and surgical [[experience]]. [[Resident]]s in neurosurgery have to spend a lot of time in the [[operating room]] to become familiar with surgical [[anatomy]] and [[technique]]s and to develop practical [[skill]]s
((Yaşargil MG. A legacy of microneurosurgery: memoirs, lessons, and axioms. Neurosurgery. (1999) 45(5):1025–92. 10.1097/00006123-199911000-00014))
((Yadav YR, Parihar V, Ratre S, Kher Y, Iqbal M. Microneurosurgical skills training. J Neurol Surg A Cent Eur Neurosurg. (2016) 77(2):146–54. 10.1055/s-0034-1376190))
((Belykh E, Onaka NR, Abramov IT, Yağmurlu K, Byvaltsev VA, Spetzler RF, et al. Systematic review of factors influencing surgical performance: practical recommendations for microsurgical procedures in neurosurgery. World Neurosurg. (2018) 112:e182–207. 10.1016/j.wneu.2018.01.005)).
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Halstedian surgical [[training]] refers to the [[surgical training]] method developed by William Halsted, an American surgeon who is considered one of the founders of modern surgery. The Halstedian approach to surgical training was developed in the late 1800s and early 1900s and was characterized by a rigorous and systematic approach to surgical [[education]].

The [[Halstedian model]] of surgical training emphasizes a "see one, do one, teach one" approach. This means that surgical [[trainee]]s are expected to observe a [[procedure]] being performed, then practice the procedure under [[supervision]], and eventually teach the procedure to other [[trainee]]s.

In addition, the Halstedian model places a strong emphasis on the importance of surgical [[anatomy]], meticulous technique, and careful attention to detail. Surgeons are trained to approach surgical procedures in a stepwise, methodical manner, with a focus on minimizing tissue trauma and achieving the best possible outcomes for the patient.

While the Halstedian approach to surgical training has been widely influential, it has also been criticized for being overly focused on technical [[proficiency]] at the expense of other important aspects of surgical practice, such as communication skills and patient-centered care. In recent years, there has been a movement towards more holistic approaches to surgical [[education]] that take into account the many different skills and competencies required to be a successful surgeon.
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The purpose of neurosurgical education is to teach the clinical knowledge and surgical skills necessary to become a [[neurosurgeon]]. Another goal is to inculcate the principles of the scientific method. 

Despite the advent of [[evidence based medicine]], clinical [[pearls]], verbal and published, remain a popular and important part of medical [[education]].

However, increasing expectations about attending involvement during surgery, duty hour requirements, and new curricular mandates have put programs under stress to ensure adequate training, in less time, in an environment of limited resident independence. More recently, the Accreditation Council for Graduate Medical Education has developed a new tracking process based on "milestones" or defined educational outcomes. At the same time, our healthcare system is undergoing a rapid socioeconomic transition in organization and payment models, which traditionally has not been a focus of formal teaching. A 2008 survey conducted by the Council of State Neurosurgical Societies found that graduating residents felt inadequately prepared in areas like contract negotiation, practice evaluation, and management
((Kim DH, Dacey RG, Zipfel GJ, Berger MS, McDermott M, Barbaro NM, Shapiro SA,
Solomon RA, Harbaugh R, Day AL. Neurosurgical Education in a Changing Healthcare 
and Regulatory Environment: A Consensus Statement from 6 Programs. Neurosurgery. 
2017 Apr 1;80(4S):S75-S82. doi: 10.1093/neuros/nyw146. PubMed PMID: 28204661.
)).

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Surgical [[education]] is moving rapidly to the use of [[simulation]] for technical [[training]] of residents and maintenance or upgrading of surgical skills in clinical practice. To optimize the learning exercise, it is essential that both visual and haptic cues are presented to best present a real-world experience. Many systems attempt to achieve this goal through a total virtual interface.

Bova et al., approach has been to create a mixed-reality system consisting of a physical and a virtual component. A physical model of the head or spine is created with a 3-dimensional printer using deidentified patient data. The model is linked to a virtual radiographic system or an image guidance platform. A variety of surgical challenges can be presented in which the trainee must use the same anatomic and radiographic references required during actual surgical procedures.

Using the aforementioned techniques, they have created [[simulator]]s for ventriculostomy, percutaneous stereotactic lesion procedure for trigeminal neuralgia, and spinal instrumentation. The design and implementation of these platforms are presented.

The system has provided the residents an opportunity to understand and appreciate the complex 3-dimensional anatomy of the 3 neurosurgical procedures simulated. The systems have also provided an opportunity to break procedures down into critical segments, allowing the user to concentrate on specific areas of deficiency
((Bova FJ, Rajon DA, Friedman WA, Murad GJ, Hoh DJ, Jacob RP, Lampotang S,
Lizdas DE, Lombard G, Lister JR. Mixed-reality simulation for neurosurgical
procedures. Neurosurgery. 2013 Oct;73 Suppl 1:138-45. doi:
10.1227/NEU.0000000000000113. PubMed PMID: 24051877.
)).

see [[Neurosurgical Training]].
====Medical education====

see [[Competency based medical education]]

see [[Continuing medical education]]


===== Neurosurgery Education and Research Virtual Group =====

Koller et al. reviewed [[virtual]] [[research]] initiatives for early [[trainee]]s in [[neurosurgery]] and describe the effort to expand access to [[resource]]s and shared objective [[mentorship]] (SOM) via the novel Neurosurgery Education and Research Virtual Group (NERVE).

Methods: A systematic review of neurosurgical programming delivered via a virtual platform was conducted using PubMed, Embase, and Scopus databases. Identified articles were screened. Those meeting pre-specified inclusion criteria were reviewed in full and examined for relevant data. Data analysis was performed using Microsoft Excel, and means and standard deviations were calculated. A descriptive analysis of NERVE characteristics was also performed.

Results: Of the 2,438 identified articles, ten were included. The most common (70%) implementation style was a [[webinar]]-based lecture series. The least common (10%) was a longitudinal curricular interest group. Of the total NERVE cohort, 90% were first-generation medical students and 82% attended institutions without home programs. Survey results indicated 73.8% had contributed to at least two research projects throughout the year.

There is a scarcity of [[virtual]] neurosurgical resources which facilitate SOM opportunities for trainees. In a systematic review, NERVE is the only multi-institutional virtual initiative aimed at increasing access to neurosurgical education and research opportunities for the purpose of SOM among early trainees from disadvantaged backgrounds. This highlights the group's niche and potential impact on increasing diversity in neurosurgery, improving trainees' career development, and facilitating future resident research productivity
((Koller GM, Reardon T, Kortz MW, Shlobin NA, Guadix SW, McCray E, Radwanski RE, Snyder HM, DiGiorgio AM, Hersh DS, Pannullo SC. Shared Objective Mentorship via Virtual Research and Education Initiatives for Medical Students and Residents in Neurosurgery: A Systematic Review and Methodological Discussion of the NERVE Experience. World Neurosurg. 2023 Jan 13:S1878-8750(23)00050-5. doi: 10.1016/j.wneu.2023.01.035. Epub ahead of print. PMID: 36646418.)).

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