Three-dimensional printing of anatomically accurate, patient specific intracranial aneurysm models

Anderson, J.; Thompson, Walker L; Alkattan, Abdulaziz Khaled; Diaz, Orlando M.; Klucznik, Richard P.; Zhang, Yi J; Britz, Gavin W.; Grossman, Robert G.; Karmonik, Christof

doi:10.1136/neurintsurg-2015-011686

Cited by 82 publications

(70 citation statements)

References 28 publications

(18 reference statements)

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“…[279111419333637] One study in particular performed a more comprehensive evaluation across 22 patients with unruptured aneurysms, comparing the reproducibility of the length and thickness of the main arteries and the size of the aneurysm between a 3D-CTA and the printed model. [11] In all studies comprising both qualitative and quantitative assessments, significant differences between preoperative imaging and printed models were only observed in a few minute areas, indicating that these models accurately represent patient anatomy.…”

Section: Resultsmentioning

confidence: 99%

3D printing in neurosurgery: A systematic review

et al. 2016

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Background:The recent expansion of three-dimensional (3D) printing technology into the field of neurosurgery has prompted a widespread investigation of its utility. In this article, we review the current body of literature describing rapid prototyping techniques with applications to the practice of neurosurgery.Methods:An extensive and systematic search of the Compendex, Scopus, and PubMed medical databases was conducted using keywords relating to 3D printing and neurosurgery. Results were manually screened for relevance to applications within the field.Results:Of the search results, 36 articles were identified and included in this review. The articles spanned the various subspecialties of the field including cerebrovascular, neuro-oncologic, spinal, functional, and endoscopic neurosurgery.Conclusions:We conclude that 3D printing techniques are practical and anatomically accurate methods of producing patient-specific models for surgical planning, simulation and training, tissue-engineered implants, and secondary devices. Expansion of this technology may, therefore, contribute to advancing the neurosurgical field from several standpoints.

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Section: Resultsmentioning

confidence: 99%

3D printing in neurosurgery: A systematic review

et al. 2016

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“…The fabrication of aneurysm replicas has been described elsewhere [13]. Briefly, digital surface models were created retrospectively from segmented 3D digital subtraction angiography images that were acquired during clinical diagnosis.…”

Section: A Aneurysm Replicas and Experimental Setupmentioning

confidence: 99%

“…The method can be carried out in 2D (single slice), 3D (multiple slices), or 4D (multiple slices + time), where the fourth dimension is time and flow is visualized at different phases in the cardiac cycle. Previous work has shown that pcMRI can be carried out in anatomically accurate, 3D printed aneurysm replicas [12][13]. Herein we present comparisons between the hemodynamics before and after placement of a flow diverter in aneurysm replicas (n=3).…”

Section: Introductionmentioning

confidence: 96%

Quantification of velocity reduction after flow diverter placement in intracranial aneurysm: An ex vivo study with 3D printed replicas

Anderson

Klucznik

Diaz

et al. 2015

2015 37th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)

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Phase contrast MRI (pcMRI) was used to measure flow before and after placement of a flow diverter (n = 3). Decreases from 18% to 31% in flow velocity were seen in the inflow jet of the aneurysms. Flow patterns were also compared. It was observed that the gross aneurysmal flow patterns were maintained after flow diverter placement despite decreased fluid velocities. All measurements were carried out in 3D printed aneurysm replicas.

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“…Some newly developed multimaterial 3D printers can produce models with multiple tissue types. As a result, some of the models produced by rapid prototyping are able to replicate actual patients' anatomical structures with remarkable realism (37,(54)(55)(56)(57).…”

Section: D Rapid Prototypingmentioning

confidence: 99%

“…One study found a strong correlation between 3D-printed models and the actual patients' anatomy (57). Additionally, studies have shown that surgeons using these models find them easy to use and superior to the use of traditional imaging alone (54,58).…”

Section: D Rapid Prototypingmentioning

confidence: 99%

Innovations in surgery simulation: a review of past, current and future techniques

Badash¹,

Burtt²,

Solorzano³

et al. 2016

Ann. Transl. Med.

239

165

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As a result of recent work-hours limitations and concerns for patient safety, innovations in extraclinical surgical simulation have become a desired part of residency education. Current simulation models, including cadaveric, animal, bench-top, virtual reality (VR) and robotic simulators are increasingly used in surgical training programs. Advances in telesurgery, three-dimensional (3D) printing, and the incorporation of patient-specific anatomy are paving the way for simulators to become integral components of medical training in the future.Evidence from the literature highlights the benefits of including simulations in surgical training; skills acquired through simulations translate into improvements in operating room performance. Moreover, simulations are rapidly incorporating new medical technologies and offer increasingly high-fidelity recreations of procedures. As a result, both novice and expert surgeons are able to benefit from their use. As dedicated, structured curricula are developed that incorporate simulations into daily resident training, simulated surgeries will strengthen the surgeon's skill set, decrease hospital costs, and improve patient outcomes.

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Three-dimensional printing of anatomically accurate, patient specific intracranial aneurysm models

Cited by 82 publications

References 28 publications

3D printing in neurosurgery: A systematic review

3D printing in neurosurgery: A systematic review

Quantification of velocity reduction after flow diverter placement in intracranial aneurysm: An ex vivo study with 3D printed replicas

Innovations in surgery simulation: a review of past, current and future techniques

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