The feasibility of producing patient-specific acrylic cranioplasty implants with a low-cost 3D printer

Tan, Eddie Tung Wee; Ling, Ji Min; Dinesh, Shree Kumar

doi:10.3171/2015.5.jns15119

Cited by 99 publications

(73 citation statements)

References 58 publications

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“…2 The advent of computer-assisted design and 3D printing technology has allowed the production of increasingly popular customized, prefabricated implants. 4,12 Although precise, the use of this technology has not been widely adopted due to limited access to expensive commercial and industrial 3D printers 31 or expensive commercial customized implants. The addition of increasingly affordable or open-source 3D technology and software makes it possible for neurosurgeons to create in-office, patient-tailored implants.…”

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confidence: 99%

Cranioplasty with a low-cost customized polymethylmethacrylate implant using a desktop 3D printer

Morales-Gómez¹,

Garcia-Estrada²,

Leos-Bortoni³

et al. 2019

Journal of Neurosurgery

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OBJECTIVE Cranioplasty implants should be widely available, low in cost, and customized or easy to mold during surgery. Although autologous bone remains the first choice for repair, it cannot always be used due to infection, fragmentation, bone resorption, or other causes, which led to use of synthetic alternatives. The most frequently used allogenic material for cranial reconstructions with long-term results is polymethylmethacrylate (PMMA). Three-dimensional printing technology has allowed the production of increasingly popular customized, prefabricated implants. The authors describe their method and experience with a customized PMMA prosthesis using a precise and reliable low-cost implant that can be customized at any institution with open-source or low-cost software and desktop 3D printers. METHODS A review of 22 consecutive patients undergoing CT-based, low-cost, customized PMMA cranioplasty over a 1-year period at a university teaching hospital was performed. Preoperative data included patient sex and age; CT modeling parameters, including the surface area of the implant (defect); reason for craniectomy; date(s) of injury and/or resections; the complexity of the defect; and associated comorbidities. Postoperative data included morbiditiy and complications, such as implant exposure, infection, hematoma, seroma, implant failure, and seizures; the cost of the implant; and cosmetic outcome. RESULTS Indications for the primary craniectomy were traumatic brain injury (16, 73%), tumor resection (3, 14%), infection (1, 4%), and vascular (2, 9%). The median interval between previous surgery and PMMA cranioplasty was 12 months. The operation time ranged from 90 to 150 minutes (mean 126 minutes). The average cranial defect measured 65.16 cm (range 29.31-131.06 cm). During the recovery period, there was no sign of infection, implant rejection, or wound dehiscence, and none of the implants had to be removed over a follow-up ranging from 1 to 6 months. The aesthetic appearance of all patients was significantly improved, and the implant fit was excellent. CONCLUSIONS The use of a customized PMMA was associated with excellent patient, family, and surgeon satisfaction at follow-up at a fraction of the cost associated with commercially available implants. This technique could be an attractive option to all patients undergoing cranioplasty.

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confidence: 99%

Cranioplasty with a low-cost customized polymethylmethacrylate implant using a desktop 3D printer

Morales-Gómez¹,

Garcia-Estrada²,

Leos-Bortoni³

et al. 2019

Journal of Neurosurgery

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“…Compared with metal prostheses (Aragon and Perez 2016;Fraldi et al 2010;Simal et al 2016;Wang et al 2016), PEEK exhibits excellent biocompatibility, the Young's modulus and yield strength of which match those of cortical bone. Such advantages make PEEK a better candidate for spinal fusion cage and cranioplasty implants (Garcia-Gonzalez et al 2015;Tan et al 2016;Tanida et al 2016). This is the first study wherein PEEK was fabricating rib prosthesis.…”

Section: Discussionmentioning

confidence: 99%

Custom design and biomechanical analysis of 3D-printed PEEK rib prostheses

Kang

Wang

Yang

et al. 2018

Biomech Model Mechanobiol

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A tumour resection normally involves a large tissue resection and bone replacement. Polyether ether ketone (PEEK) has become a suitable candidate for use in various prostheses owing to its lightness in weight, modulus close to that of natural bone, and good biocompatibility, among other factors. This study proposes a new design method for a rib prosthesis using the centroid trajectory of the natural replaced rib, where the strength can be adjusted by monitoring the cross-sectional area, shape, and properties. A custom-designed rib prosthesis was manufactured using fused deposition modelling (FDM) manufacturing technology, and the mechanical behaviour was found to be close to that of a natural rib. A finite element analysis of the designed rib was carried out under similar loading conditions to those used in mechanical testing. The results indicate that the centroid trajectory derived from a natural rib diaphysis can provide reliable guidance for the design of a rib prosthesis. Such methodology not only offers considerable design freedom in terms of shape and required strength, but also benefits the quality of the surface finishing for samples manufactured using the FDM technique. FDM-printed PEEK rib prostheses have been successfully implanted, and good clinical performances have been achieved.

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“…To avoid the problems associated with intraoperative PMMA casting, preoperatively designed patient speci ic implants were introduced. With the aid of 3D design and printing technology, the size and shape of the defect determined from imaging data can be transferred into a planning software to produce a patient-tailored implant [10,11]. We used CT scan images for computer aided design, which allowed a smooth surface rendering of 3D cranium model.…”

Section: Discussionmentioning

confidence: 99%

Cranioplasty with preoperatively customized Polymethyl-methacrylate by using 3-Dimensional Printed Polyethylene Terephthalate Glycol Mold

Sürme¹,

Hergunsel²,

Akgun³

et al. 2018

J Neurosci Neurol Disord

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The feasibility of producing patient-specific acrylic cranioplasty implants with a low-cost 3D printer

Cited by 99 publications

References 58 publications

Cranioplasty with a low-cost customized polymethylmethacrylate implant using a desktop 3D printer

Cranioplasty with a low-cost customized polymethylmethacrylate implant using a desktop 3D printer

Custom design and biomechanical analysis of 3D-printed PEEK rib prostheses

Cranioplasty with preoperatively customized Polymethyl-methacrylate by using 3-Dimensional Printed Polyethylene Terephthalate Glycol Mold

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