Mechanical and medical imaging properties of 3D‐printed materials as tissue equivalent materials

Ma, Depeng; Gao, Ronghui; Li, Minghui; Qiu, Jianfeng

doi:10.1002/acm2.13495

Cited by 14 publications

(12 citation statements)

References 33 publications

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“…28 Previous studies have characterized 3D print materials using kilovoltage CT similar to the methods in this work. [7][8][9][11][12][13]15,16,19,21 However, the work presented herein builds upon past efforts in multiple ways. This work focuses on readily and commercially available filaments, most of which have not yet been characterized.…”

Section: Discussionmentioning

confidence: 99%

“…In radiotherapy, additive manufacturing has already been used to create compensators, phantoms, shielding, and other innovative solutions to improve standard practices 5,23 . In phantom production, the need to become more tissue equivalent is being explored and this examination of commercially available materials will allow for radiological properties to be replicated more thoroughly 21 . The replication of tissues for use in dosimetry has been successfully used in rapid prototyping within radiotherapy 26 .…”

Section: Discussionmentioning

confidence: 99%

“…12,13,19 The growing literature on this subject will help to find more applications and wider utility for 3D printing in radiology and radiation oncology. However, there is wide variability in printing techniques, measurement approaches, filament compositions (by manufacturer and by specific filament batch), as well as how printed components will be used (radiography/mammography, 10,14,[16][17][18]20,21 kilovoltage CT of various energies, 8,9,11,12,15,19,21,22 megavoltage applications such as MVCT or radiotherapy dosimetry, 6,7,12,13 or for exogenous components (e.g., bolus, orthopedic implants, brachytherapy applicators, etc.). 2,3 This work seeks to comprehensively evaluate commercially available 3D printing filaments with nonstandard composition for use in reproducing Hounsfield units (HUs) at various peak kilovoltage (kVp) spanning the range of all expected human tissues (from lung to dense bone) as well as even higher-density/higher-Z metallic implants.…”

Section: Introductionmentioning

confidence: 99%

“…The growing literature on this subject will help to find more applications and wider utility for 3D printing in radiology and radiation oncology. However, there is wide variability in printing techniques, measurement approaches, filament compositions (by manufacturer and by specific filament batch), as well as how printed components will be used (radiography/mammography, 10,14,16–18,20,21 kilovoltage CT of various energies, 8,9,11,12,15,19,21,22 megavoltage applications such as MVCT or radiotherapy dosimetry, 6,7,12,13 or for exogenous components (e.g., bolus, orthopedic implants, brachytherapy applicators, etc.) 2,3 .…”

Section: Introductionmentioning

confidence: 99%

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Methodology for computed tomography characterization of commercially available 3D printing materials for use in radiology/radiation oncology

Kozee

Weygand

Andreozzi

et al. 2023

J Applied Clin Med Phys

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3D printing in medical physics provides opportunities for creating patientspecific treatment devices and in-house fabrication of imaging/dosimetry phantoms. This study characterizes several commercial fused deposition 3D printing materials with some containing nonstandard compositions. It is important to explore their similarities to human tissues and other materials encountered in patients. Uniform cylinders with infill from 50 to 100% at six evenly distributed intervals were printed using 13 different filaments. A novel approach rotating infill angle 10 o between each layer avoids unwanted patterns. Five materials contained high-Z/metallic components. A clinical CT scanner with a range of tube potentials (70, 80, 100, 120, 140 kVp) was used. Density and average Hounsfield unit (HU) were measured.A commercial GAMMEX phantom mimicking various human tissues provides a comparison. Utility of the lookup tables produced is demonstrated. A methodology for calibrating print materials/parameters for a desired HU is presented. Density and HU were determined for all materials as a function of tube voltage (kVp) and infill percentage. The range of HU (−732.0-10047.4 HU) and physical densities (0.36-3.52 g/cm 3 ) encompassed most tissues/materials encountered in radiology/radiotherapy applications with many overlapping those of human tissues. Printing filaments doped with high-Z materials demonstrated increased attenuation due to the photoelectric effect with decreased kVp, as found in certain endogenous materials (e.g., bone). HU was faithfully reproduced (within one standard deviation) in a 3D-printed mimic of a commercial anthropomorphic phantom section. Characterization of commercially available 3D print materials facilitates custom object fabrication for use in radiology and radiation oncology, including human tissue and common exogenous implant mimics. This allows for cost reduction and increased flexibility to fabricate novel phantoms or patient-specific devices imaging and dosimetry purposes. A formalism for calibrating to specific CT scanner, printer, and filament type/batch is presented. Utility is demonstrated by printing a commercial anthropomorphic phantom copy. Jasmine A. Graham and Gage Redler contributed equally to this work.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Methodology for computed tomography characterization of commercially available 3D printing materials for use in radiology/radiation oncology

Kozee

Weygand

Andreozzi

et al. 2023

J Applied Clin Med Phys

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“…3D printing can quickly fabricate various structures with little waste of material. Coupled with the gradual reduction of the cost and personalized customization, 3D printing has become widely used in many fields, especially in medical fields, such as tissue engineering ( Ma et al, 2022 ). Thus, 3D bioprinting came into being.…”

Section: Introductionmentioning

confidence: 99%

An Overview of Extracellular Matrix-Based Bioinks for 3D Bioprinting

Wang

Zhou

et al. 2022

Front. Bioeng. Biotechnol.

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As a microenvironment where cells reside, the extracellular matrix (ECM) has a complex network structure and appropriate mechanical properties to provide structural and biochemical support for the surrounding cells. In tissue engineering, the ECM and its derivatives can mitigate foreign body responses by presenting ECM molecules at the interface between materials and tissues. With the widespread application of three-dimensional (3D) bioprinting, the use of the ECM and its derivative bioinks for 3D bioprinting to replicate biomimetic and complex tissue structures has become an innovative and successful strategy in medical fields. In this review, we summarize the significance and recent progress of ECM-based biomaterials in 3D bioprinting. Then, we discuss the most relevant applications of ECM-based biomaterials in 3D bioprinting, such as tissue regeneration and cancer research. Furthermore, we present the status of ECM-based biomaterials in current research and discuss future development prospects.

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Mechanical and medical imaging properties of 3D‐printed materials as tissue equivalent materials

Gao²,

et al. 2021

J Applied Clin Med Phys

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Three materials of polylactic acid (PLA), polyamide 12 (PA12), and light curing resin (LCR) were used to construct phantom using 3D printing technology. The mechanical and medical imaging properties of the three materials, such as elastic modulus, density, effective atomic number, X‐ray attenuation coefficient, computed tomography (CT) number, and acoustic properties, were investigated. The results showed that the elastic modulus for PLA was 1.98 × 103 MPa, for PA12 was 848 MPa, for LCR was 1.18×103 MPa, and that of three materials was close to some bones. In the range of 40∼120 kV, the X‐ray attenuation coefficient of three materials decreased with increasing tube voltage. The CT number for PLA, PA12, and LCR was 144, −88, and 312 Hounsfield units at 120 kV tube voltage, respectively. The density and the effective atomic number product (ρ*Zeff) were computed from three materials and decreased in the order of LCR, PLA, and PA12. The acoustic properties of materials were also studied. The speeds of sound of three materials were similar with those of some soft tissues.

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Mechanical and medical imaging properties of 3D‐printed materials as tissue equivalent materials

Cited by 14 publications

References 33 publications

Methodology for computed tomography characterization of commercially available 3D printing materials for use in radiology/radiation oncology

Methodology for computed tomography characterization of commercially available 3D printing materials for use in radiology/radiation oncology

An Overview of Extracellular Matrix-Based Bioinks for 3D Bioprinting

Mechanical and medical imaging properties of 3D‐printed materials as tissue equivalent materials

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