3D-Printed head Model [Neurosurgery Wiki]

This page is read only. You can view the source, but not change it. Ask your administrator if you think this is wrong.
====== 3D-Printed head Model ======

{{rss>https://pubmed.ncbi.nlm.nih.gov/rss/search/1TkPOxkdaxtrnox4epUuzVLgX8Z8MGLrPX4bb-5_-G73vvcsaH/?limit=15&utm_campaign=pubmed-2&fc=20250115070531}}
----

----

 

[[Intracranial]] [[surgery]] can be [[complex]] and high [[risk]]. [[Safety]], ethical and financial [[factor]]s make [[training]] in the area challenging. [[Head]] [[model]] 3-dimensional ([[3D]]) [[printing]] is a realistic training alternative to patient and traditional means of [[cadaver]] and [[animal model]] [[simulation]].
----
Computed Tomography (CT), Magnetic Resonance Imaging (MRI), and 3D reconstruction from Digital Subtraction Angiography (DSA) are currently used in clinical consultations for patients diagnosed with intracranial aneurysms; however, they have limitations in helping patients understand the disease and possible treatments. This study investigates the use of a 3D-printed model of the patients' neurosurgical anatomy and vascular pathology as an educational tool in outpatient clinics.

Methods: A 3D-printed model of a middle cerebral artery aneurysm was created for use during patient consultations to discuss microsurgical treatment of unruptured cerebral aneurysms. In total, 38 patients and 5 neurosurgeons were included in the study. After the consultation, the patients and neurosurgeons received a questionnaire to assess the effectiveness of the 3D-printed model as an educational tool.

Results: The 3D model improved the patients' understanding of the diagnosis, the aneurysm's relationship to the parent artery; the treatment process as well as the risks if left untreated. The patients found the 3D model to be an interesting tool (97%). The neurosurgeons were satisfied with the 3D-printed model as a patient encounter tool, they found the model effective during consultation (87%) and better than the conventional education tools used during consultations (97%).

Conclusion: Using a 3D model improves communication, enhances the patient's understanding of the pathology and its treatment and potentially facilitates the informed consent process in patients undergoing intracranial aneurysm surgery
((Joseph FJ, Vanluchene HER, Goldberg J, Bervini D. 3D-printed head model in patient's education for micro-neurosurgical aneurysm clipping procedures. World Neurosurg. 2023 Apr 20:S1878-8750(23)00555-7. doi: 10.1016/j.wneu.2023.04.070. Epub ahead of print. PMID: 37087042.))
----


Maclachlan et al. described important factors relating to the [[3D printing]] of human head models and how such models perform as [[simulator]]s.

Searches were performed in [[PubMed]], The [[Cochrane]] Library, [[Scopus]] and [[Web of Science]]. [[Article]] [[screening]] was conducted independently by three [[reviewer]]s using [[Covidence]] software. Data items were collected under five categories: 'Study information', 'Printers and processes' 'Head model specifics,' 'Simulation and evaluations' and 'Costs and production times'.

Results: Forty articles published over the last 10 years were included in the review. A range of printers, printing methods and substrates were used to create head models and tissue types. Complexity of the models ranged from sections of single tissue type (e.g., bone) to high-fidelity integration of multiple tissue types. Some models incorporated pathology (e.g., tumours, aneurysms) and artificial physiology (e.g., pulsatile circulation). Aneurysm clipping, bone drilling, craniotomy, endonasal surgery and tumour resection were the most commonly practiced procedures. Evaluations completed by those using the models were generally favourable.

Conclusions: This review's findings indicate that those who practice surgery and surgical techniques on 3D printed head models deem them to be valuable assets in cranial surgery training. Understanding how surgical simulation on such models impacts on surgical performance and patient outcomes, whilst considering cost-effectiveness, are important future research endeavours
((Maclachlan LR, Alexander H, Forrestal D, Novak JI, Redmond M. Properties and characteristics of 3-dimensional printed head models used in simulation of neurosurgical procedures: a scoping review. World Neurosurg. 2021 Sep 24:S1878-8750(21)01422-4. doi: 10.1016/j.wneu.2021.09.079. Epub ahead of print. PMID: 34571242.)).
====== 3D-printed skull model for enhancing training in external ventricular drainage within medical education ======

**Type of study:** [[Simulation-based training model development]] and [[preliminary]]y [[evaluation]] study

**Reference:**  
Scheidt K, Kropla F, Winkler D, Möbius R, Vychopen M, Wach J, Güresir E, Grunert R.  
''3D Print Med''. 2025 Apr 3;11(1):16. doi: [[https://doi.org/10.1186/s41205-025-00263-0|10.1186/s41205-025-00263-0]].

===== Critical Review =====

Scheidt et al.'s publication presents a sophisticated [[training phantom]] designed for the simulation of [[external ventricular drainage]] (EVD), a core neurosurgical procedure. Developed collaboratively by clinicians and engineers at the University Hospital of Leipzig, the model aims to bridge the gap between theoretical knowledge and hands-on skill acquisition
((Scheidt K, Kropla F, Winkler D, Möbius R, Vychopen M, Wach J, Güresir E, Grunert R. 3D-printed skull model for enhancing training in external ventricular drainage within medical education. 3D Print Med. 2025 Apr 3;11(1):16. doi: 10.1186/s41205-025-00263-0. PMID: 40178708.)).

The phantom replicates the human skull and ventricular anatomy through three core elements: a 3D-printed [[skull model]] using polyamide (PA12), a [[ventricular system]] printed in flexible Elastic Resin 50A, and [[brain tissue simulation]] using cast gelatin. The use of 3D printing allows for high anatomical fidelity, and the model realistically simulates the sensation of [[trephination]] and [[cerebrospinal fluid]] (CSF) dynamics.

One of the strengths of this model is its modular and reproducible design, which enables iterative improvements and adaptation to different teaching environments. The authors report successful simulation of CSF flow and adequate material performance during cannulation and drilling exercises. The realistic mechanical properties of gelatin at 30g/L as brain tissue mimics are particularly promising for novice training.

However, the study has some limitations. The evaluation was restricted to a subjective Likert-scale assessment by a limited number of neurosurgeons. Quantitative validation of procedural accuracy, skill acquisition, and comparative outcomes against existing EVD [[training]] [[tool]]s is necessary for broader adoption. Moreover, the need for additional material to accommodate chip formation during drilling suggests further optimization is required.

In conclusion, this model represents a substantial step forward in [[neurosurgical simulation]] and training. It offers a cost-effective, reproducible, and anatomically faithful alternative to cadaver-based training. Further studies are warranted to quantify its educational impact and improve its technical design. This work aligns well with modern pedagogical shifts toward [[hands-on learning]] and [[low-risk surgical practice environment]]s.

{{tag>3D-printing external_ventricular_drain neurosurgery simulation_model phantom medical_education surgical_training Leipzig}}

===== 3D-printed head Model in skull base surgery training =====

[[3D-printed head Model in skull base surgery training]].