CUSTOMIZED BIOMODEL OF THE CERVICAL SPINE FOR LABORATORY LAMINOPLASTY TRAINING
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2024 |
| Outros Autores: | , , , , , , |
| Tipo de documento: | preprint |
| Idioma: | eng |
| Título da fonte: | SciELO Preprints |
| Texto Completo: | https://preprints.scielo.org/index.php/scielo/preprint/view/9072 |
Resumo: | Background: Additive manufacturing has been developed as a promising innovation for many areas, including medicine. There are many ways to use it in spine surgeries and the use of biomodels in the laboratory to study and training of cervical laminoplasty has not yet been reported in the literature. Objective: To evaluate the use of a biomodel of the cervical spine for surgical training of laminoplasty. Method: This is an experimental study. Were printed 10 identical biomodels of the cervical spine based on CT and MRI scans of a patient diagnosed with spondylotic cervical myelopathy. The additive manufacturing method used was fused deposition modeling and the raw material chosen was polyatic acid. The sample was divided into 2 groups: control (n = 5; the biomodels were submitted to CT scanning) and open-door (n = 5; the biomodels were submitted to open-door laminoplasty and postoperative CT). The area and anteroposterior diameter of the vertebral canal were measured on CT scans. Result: The time for printing each piece was 12 h. During the surgical procedure, the support of the biomodels was sufficient to keep them static. The use of drill was feasible; however, continuous irrigation was mandatory to prevents the heating of the plastic material. The raw material used allowed the CT study of the biomodels. It was observed an increase the dimensions of the vertebral canal in 24,80% (0.62 cm2) in the area and 24,88% (3.12 mm) in the anteroposterior diameter. Conclusion: The cervical spine biomodels can be used for laminoplasty training, even using thermosensitive material such as PLA. The use of continuous irrigation is essential during the use of the drill. |
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CUSTOMIZED BIOMODEL OF THE CERVICAL SPINE FOR LABORATORY LAMINOPLASTY TRAININGBIOMODELO PERSONALIZADO DA COLUNA CERVICAL PARA TREINAMENTO DE LAMINOPLASTIA EM LABORATÓRIOCervicalLaminoplastiaImpressão tridimensionalMielopatia espondilóticaCervicalLaminoplastyThree-dimensional printingSpondylotic myelopathyBackground: Additive manufacturing has been developed as a promising innovation for many areas, including medicine. There are many ways to use it in spine surgeries and the use of biomodels in the laboratory to study and training of cervical laminoplasty has not yet been reported in the literature. Objective: To evaluate the use of a biomodel of the cervical spine for surgical training of laminoplasty. Method: This is an experimental study. Were printed 10 identical biomodels of the cervical spine based on CT and MRI scans of a patient diagnosed with spondylotic cervical myelopathy. The additive manufacturing method used was fused deposition modeling and the raw material chosen was polyatic acid. The sample was divided into 2 groups: control (n = 5; the biomodels were submitted to CT scanning) and open-door (n = 5; the biomodels were submitted to open-door laminoplasty and postoperative CT). The area and anteroposterior diameter of the vertebral canal were measured on CT scans. Result: The time for printing each piece was 12 h. During the surgical procedure, the support of the biomodels was sufficient to keep them static. The use of drill was feasible; however, continuous irrigation was mandatory to prevents the heating of the plastic material. The raw material used allowed the CT study of the biomodels. It was observed an increase the dimensions of the vertebral canal in 24,80% (0.62 cm2) in the area and 24,88% (3.12 mm) in the anteroposterior diameter. Conclusion: The cervical spine biomodels can be used for laminoplasty training, even using thermosensitive material such as PLA. The use of continuous irrigation is essential during the use of the drill.Introdução: A manufatura aditiva tem se desenvolvido como inovação promissora para muitas áreas, incluindo a medicina. Existem muitas maneiras de utilizá-la em operações de coluna, e o uso de biomodelos em laboratório para estudo e treinamento de laminoplastia cervical ainda não foi relatado na literatura. Objetivo: Avaliar a utilização de um biomodelo da coluna cervical para treinamento cirúrgico de laminoplastia. Método: Trata-se de estudo experimental. Foram impressos 10 biomodelos idênticos da coluna cervical baseados em exames de tomografia computadorizada e ressonância magnética de um paciente com diagnóstico de mielopatia cervical espondilótica. O método de manufatura aditiva utilizado foi a modelagem por deposição fundida e a matéria-prima escolhida foi o ácido poliático. A amostra foi distribuída em 2 grupos: controle (n = 5; os biomodelos foram submetidos à tomografia computadorizada) e open-door (n = 5; os biomodelos foram submetidos à laminoplastia open-door e tomografia pós-operatória). A área e o diâmetro anteroposterior do canal vertebral foram medidos na tomografia. Resultado: O tempo de impressão de cada peça foi de 12 h. Durante o procedimento, o suporte utilizado para fixar o biomodelo foi suficiente para mantê-los estáticos. O uso de broca mostrou-se viável; porém, a irrigação contínua foi mandatória para evitar o aquecimento do material plástico. A matéria-prima utilizada permitiu o estudo tomográfico dos biomodelos. Observou-se aumento das dimensões do canal vertebral em 24,80% (0,62 cm2) na área e 24,88% (3,12 mm) no diâmetro anteroposterior. Conclusão: Os biomodelos da coluna cervical podem ser utilizados para o treinamento de laminoplastias, mesmo utilizando material termossensível. O uso de irrigação contínua é essencial durante o uso da broca.SciELO PreprintsSciELO PreprintsSciELO Preprints2024-06-07info:eu-repo/semantics/preprintinfo:eu-repo/semantics/publishedVersionapplication/pdfhttps://preprints.scielo.org/index.php/scielo/preprint/view/907210.1590/SciELOPreprints.9072enghttps://preprints.scielo.org/index.php/scielo/preprint/view/9072/16952Copyright (c) 2024 Francisco Alves de Araújo-Júnior , Jurandir Marcondes Ribas-Filho, Osvaldo Malafaia , Aluízio Augusto Arantes-Júnior , Guilherme Henrique Weiler Ceccato , Pedro Helo dos Santos-Neto , Ricardo Rabello Ferreira , Ramon Bottega https://creativecommons.org/licenses/by/4.0info:eu-repo/semantics/openAccessAraújo-Júnior , Francisco Alves deRibas-Filho, Jurandir MarcondesMalafaia , OsvaldoArantes-Júnior , Aluízio AugustoCeccato , Guilherme Henrique WeilerSantos-Neto , Pedro Helo dosFerreira , Ricardo RabelloBottega , Ramonreponame:SciELO Preprintsinstname:Scientific Electronic Library Online (SCIELO)instacron:SCI2024-06-05T17:07:00Zoai:ops.preprints.scielo.org:preprint/9072Servidor de preprintshttps://preprints.scielo.org/index.php/scieloONGhttps://preprints.scielo.org/index.php/scielo/oaiscielo.submission@scielo.orgopendoar:2024-06-05T17:07SciELO Preprints - Scientific Electronic Library Online (SCIELO)false |
| dc.title.none.fl_str_mv |
CUSTOMIZED BIOMODEL OF THE CERVICAL SPINE FOR LABORATORY LAMINOPLASTY TRAINING BIOMODELO PERSONALIZADO DA COLUNA CERVICAL PARA TREINAMENTO DE LAMINOPLASTIA EM LABORATÓRIO |
| title |
CUSTOMIZED BIOMODEL OF THE CERVICAL SPINE FOR LABORATORY LAMINOPLASTY TRAINING |
| spellingShingle |
CUSTOMIZED BIOMODEL OF THE CERVICAL SPINE FOR LABORATORY LAMINOPLASTY TRAINING Araújo-Júnior , Francisco Alves de Cervical Laminoplastia Impressão tridimensional Mielopatia espondilótica Cervical Laminoplasty Three-dimensional printing Spondylotic myelopathy |
| title_short |
CUSTOMIZED BIOMODEL OF THE CERVICAL SPINE FOR LABORATORY LAMINOPLASTY TRAINING |
| title_full |
CUSTOMIZED BIOMODEL OF THE CERVICAL SPINE FOR LABORATORY LAMINOPLASTY TRAINING |
| title_fullStr |
CUSTOMIZED BIOMODEL OF THE CERVICAL SPINE FOR LABORATORY LAMINOPLASTY TRAINING |
| title_full_unstemmed |
CUSTOMIZED BIOMODEL OF THE CERVICAL SPINE FOR LABORATORY LAMINOPLASTY TRAINING |
| title_sort |
CUSTOMIZED BIOMODEL OF THE CERVICAL SPINE FOR LABORATORY LAMINOPLASTY TRAINING |
| author |
Araújo-Júnior , Francisco Alves de |
| author_facet |
Araújo-Júnior , Francisco Alves de Ribas-Filho, Jurandir Marcondes Malafaia , Osvaldo Arantes-Júnior , Aluízio Augusto Ceccato , Guilherme Henrique Weiler Santos-Neto , Pedro Helo dos Ferreira , Ricardo Rabello Bottega , Ramon |
| author_role |
author |
| author2 |
Ribas-Filho, Jurandir Marcondes Malafaia , Osvaldo Arantes-Júnior , Aluízio Augusto Ceccato , Guilherme Henrique Weiler Santos-Neto , Pedro Helo dos Ferreira , Ricardo Rabello Bottega , Ramon |
| author2_role |
author author author author author author author |
| dc.contributor.author.fl_str_mv |
Araújo-Júnior , Francisco Alves de Ribas-Filho, Jurandir Marcondes Malafaia , Osvaldo Arantes-Júnior , Aluízio Augusto Ceccato , Guilherme Henrique Weiler Santos-Neto , Pedro Helo dos Ferreira , Ricardo Rabello Bottega , Ramon |
| dc.subject.por.fl_str_mv |
Cervical Laminoplastia Impressão tridimensional Mielopatia espondilótica Cervical Laminoplasty Three-dimensional printing Spondylotic myelopathy |
| topic |
Cervical Laminoplastia Impressão tridimensional Mielopatia espondilótica Cervical Laminoplasty Three-dimensional printing Spondylotic myelopathy |
| description |
Background: Additive manufacturing has been developed as a promising innovation for many areas, including medicine. There are many ways to use it in spine surgeries and the use of biomodels in the laboratory to study and training of cervical laminoplasty has not yet been reported in the literature. Objective: To evaluate the use of a biomodel of the cervical spine for surgical training of laminoplasty. Method: This is an experimental study. Were printed 10 identical biomodels of the cervical spine based on CT and MRI scans of a patient diagnosed with spondylotic cervical myelopathy. The additive manufacturing method used was fused deposition modeling and the raw material chosen was polyatic acid. The sample was divided into 2 groups: control (n = 5; the biomodels were submitted to CT scanning) and open-door (n = 5; the biomodels were submitted to open-door laminoplasty and postoperative CT). The area and anteroposterior diameter of the vertebral canal were measured on CT scans. Result: The time for printing each piece was 12 h. During the surgical procedure, the support of the biomodels was sufficient to keep them static. The use of drill was feasible; however, continuous irrigation was mandatory to prevents the heating of the plastic material. The raw material used allowed the CT study of the biomodels. It was observed an increase the dimensions of the vertebral canal in 24,80% (0.62 cm2) in the area and 24,88% (3.12 mm) in the anteroposterior diameter. Conclusion: The cervical spine biomodels can be used for laminoplasty training, even using thermosensitive material such as PLA. The use of continuous irrigation is essential during the use of the drill. |
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2024 |
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2024-06-07 |
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