Manufacturing and Characterization of Hybrid Bulk Voxelated Biomaterials Printed by Digital Anatomy 3D Printing

Heo, Hyeonu; Jin, Yuqi; Yang, Deng‐Tao; Wier, Christopher G.; Minard, Aaron; Dahotre, Narendra B.; Neogi, Arup

doi:10.3390/polym13010123

Cited by 17 publications

(13 citation statements)

References 33 publications

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“…Emerging technologies utilizing material jetting, instead of material extrusion, may provide for more realistic and mechanically-validated materials. 25 Additionally, this study focused on the bony and cartilage tissues, without the complexity of spanning muscular and ligamentous tissues, which may contribute to postoperative morphological changes. However, this study compares the same models prior and following the surgical procedure, thus allowing a direct comparison between the techniques that would be difficult to mimic, even in an animal model.…”

Section: Discussionmentioning

confidence: 99%

Comparison of Acetabular Morphology Changes After Pediatric Pelvic Osteotomies Using Patient-Specific 3-D Models

Baird¹,

Caffrey²,

Bomar³

et al. 2022

Journal of the Pediatric Orthopaedic Society of North America

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Background: Surgical management to improve hip joint morphology in immature patients with acetabular dysplasia includes Pemberton, Dega, San Diego, and Salter acetabular osteotomies. This study evaluates acetabular morphology between these osteotomies using patient-specific 3-D printing technology. Methods: Preoperative computed tomography scans (CTs) from patients with acetabular dysplasia were rendered into 3-D printable formats. Quadruplicate pelvis models for each patient received Pemberton, Dega, San Diego, and Salter osteotomies. CTs were obtained of each model before and after osteotomy. Acetabular volume and regional coverage angles were computed and compared before and after each osteotomy. Results: Fourteen hips (14 patients) were included; 1 male, 13 female; age 5.4±1.3 years (3.9-7.5 years). Acetabular volume decreased following each osteotomy (Pemberton by 14%, Dega by 19%, San Diego by 19%, and Salter by 6%), with smaller volume reduction for Salter than the others (p<0.05). Volume change was similar between Pemberton, Dega, and San Diego (p=0.32). Pemberton increased coverage in Superior and Anterior regions, Dega increased coverage in Superior, Superior-Anterior, and Anterior regions, San Diego increased coverage in Posterior, Superior-Posterior, and Superior regions, and Salter increased coverage in Superior region (p<0.05). Conclusions: Acetabular volume changes found in this study support the convention that redirectional osteotomies such as Salter are more volume neutral than incomplete osteotomies such as Pemberton, Dega, and San Diego. However, even the Salter decreased acetabular volume. This study re-demonstrated that each osteotomy studied changes acetabular coverage in different regions. Based on this, a surgeon’s osteotomy decision should be based on the dysplastic acetabulum morphology.

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Section: Discussionmentioning

confidence: 99%

Comparison of Acetabular Morphology Changes After Pediatric Pelvic Osteotomies Using Patient-Specific 3-D Models

Baird¹,

Caffrey²,

Bomar³

et al. 2022

Journal of the Pediatric Orthopaedic Society of North America

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“…solution-soluble material utilized when printing small features. The GelMatrix material is softer and easier to remove; it allows to realize a small diameter structure previously unattainable by 3D printing and gives enough support during the printing process (8).…”

Section: D Surgical Guide Printingmentioning

confidence: 99%

A 3D-printed surgical guide for ischemic scar targeting and ablation

Candelari¹,

Cappello²,

Pannone³

et al. 2022

Front. Cardiovasc. Med.

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Background3D printing technology development in medical fields allows to create 3D models to assist preoperative planning and support surgical procedures. Cardiac ischemic scar is clinically associated with malignant arrhythmias. Catheter ablation is aimed at eliminating the arrhythmogenic tissue until the sinus rhythm is restored. The scope of this work is to describe the workflow for a 3D surgical guide able to define the ischemic scar and target catheter ablation.Materials and methodsFor the patient-specific 3D surgical guide and 3D heart phantom model realization, both CT scan and cardiac MRI images were processed; this was necessary to extract anatomical structures and pathological information, respectively. Medical images were uploaded and processed in 3D Slicer. For the surgical guide modeling, images from CT scan and MRI were loaded in Meshmixer and merged. For the heart phantom realization, only the CT segmentation was loaded in Meshmixer. The surgical guide was printed in MED625FLX with Polyjet technology. The heart phantom was printed in polylactide with FDM technology.Results3D-printed surgical model was in agreement with prespecified imputed measurements. The phantom fitting test showed high accuracy of the 3D surgical tool compared with the patient-specific reproduced heart. Anatomical references in the surgical guide ensured good stability. Ablation catheter fitting test showed high suitability of the guide for different ablation tools.ConclusionA 3D-printed guide for ventricular tachycardia ablation is feasible and accurate in terms of measurements, stability, and geometrical structure. Concerning clinical use, further clinical investigations are eagerly awaited.

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“…Nevertheless, besides the existing methods of flaw detection, a recently invented technique ( Figure 19 ), effective bulk modulus and effective density elastography (EBME) [ 93 , 94 , 95 , 96 ], provided an alternative method for the detection of discontinuities in AM products by focusing on the local density fraction of the pores instead of seeking each pore. EBME can generate an effective bulk modulus (isotropic incompressible) and perform useful density mapping by measuring the sample’s acoustic impedance using longitudinal pulses in a monostatic set-up without any external stress.…”

Section: Ultrasonic Inspection and Evaluationmentioning

confidence: 99%

A Review of Diagnostics Methodologies for Metal Additive Manufacturing Processes and Products

et al. 2021

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Additive manufacturing technologies based on metal are evolving into an essential advanced manufacturing tool for constructing prototypes and parts that can lead to complex structures, dissimilar metal-based structures that cannot be constructed using conventional metallurgical techniques. Unlike traditional manufacturing processes, the metal AM processes are unreliable due to variable process parameters and a lack of conventionally acceptable evaluation methods. A thorough understanding of various diagnostic techniques is essential to improve the quality of additively manufactured products and provide reliable feedback on the manufacturing processes for improving the quality of the products. This review summarizes and discusses various ex-situ inspections and in-situ monitoring methods, including electron-based methods, thermal methods, acoustic methods, laser breakdown, and mechanical methods, for metal additive manufacturing.

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Manufacturing and Characterization of Hybrid Bulk Voxelated Biomaterials Printed by Digital Anatomy 3D Printing

Cited by 17 publications

References 33 publications

Comparison of Acetabular Morphology Changes After Pediatric Pelvic Osteotomies Using Patient-Specific 3-D Models

Comparison of Acetabular Morphology Changes After Pediatric Pelvic Osteotomies Using Patient-Specific 3-D Models

A 3D-printed surgical guide for ischemic scar targeting and ablation

A Review of Diagnostics Methodologies for Metal Additive Manufacturing Processes and Products

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