Search Results - "Paxton, Naomi C"

Navigating the intersection of 3D printing, software regulation and quality control for point-of-care manufacturing of personalized anatomical models by Paxton, Naomi C.

“…3D printing technology has become increasingly popular in healthcare settings, with applications of 3D printed anatomical models ranging from diagnostics and…”
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Correction: Navigating the intersection of 3D printing, software regulation and quality control for point-of-care manufacturing of personalized anatomical models by Paxton, Naomi C.

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Improving Infection Resistance in Tissue Engineered Scaffolds for Tensile Applications Using Vancomycin‐Embedded Melt Electrowritten Scaffolds by Mathew, Asha, Devlin, Brenna L., Singh, Dilpreet, Paxton, Naomi C., Woodruff, Maria A.

“…Abstract It is important to consider mechanical, biological, and antibacterial properties of scaffolds when used for tissue engineering applications. This…”
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Development of Mechanically Enhanced Polycaprolactone Composites by a Functionalized Titanate Nanofiller for Melt Electrowriting in 3D Printing by Pang, Le, Paxton, Naomi C, Ren, Jiongyu, Liu, Fan, Zhan, Haifei, Woodruff, Maria A, Bo, Arixin, Gu, Yuantong

“…Three-dimensional (3D) printing technologies are widely applied in various industries and research fields and are currently the subject of intensive…”
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Laser Sintering Approaches for Bone Tissue Engineering by DiNoro, Jeremy N., Paxton, Naomi C., Skewes, Jacob, Yue, Zhilian, Lewis, Philip M., Thompson, Robert G., Beirne, Stephen, Woodruff, Maria A., Wallace, Gordon G.

“…The adoption of additive manufacturing (AM) techniques into the medical space has revolutionised tissue engineering. Depending upon the tissue type, specific…”
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Technical improvements in preparing 3D printed anatomical models for comminuted fracture preoperative planning by Paxton, Naomi C., Wilkinson, Brandon G., Fitzpatrick, Daniel, Owen, Erin C., Luposchainsky, Simon, Dalton, Paul D.

“…Preoperative planning of comminuted fracture repair using 3D printed anatomical models is enabling surgeons to visualize and simulate the fracture reduction…”
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Polymer 3D printing in perspective: Assessing challenges and opportunities in industrial translation against the metal benchmark by Paxton, Naomi C., Zhao, Jiachen, Sauret, Emilie

“…Additive manufacturing is swiftly transitioning from a prototyping tool to a useful technology for industrial-scale manufacturing. As global industries seek to…”
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Biomedical applications of polyethylene by Paxton, Naomi C., Allenby, Mark C., Lewis, Philip M., Woodruff, Maria A.

“…[Display omitted] •Polyethylene has been used as a gold-standard biomaterial for surgical implants.•Porous high-density polyethylene implants are embedded in…”
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Auxetic tubular scaffolds via melt electrowriting by Paxton, Naomi C., Daley, Ryan, Forrestal, David P., Allenby, Mark C., Woodruff, Maria A.

“…Auxetics are an interesting class of materials that expand in transverse directions when tensile loading is applied. For example, in contrast to conventional…”
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Measuring contact angles on hydrophilic porous scaffolds by implementing a novel raised platform approach: A technical note by Paxton, Naomi C., Woodruff, Maria A.

“…Contact angle (CA) analysis is a widely employed technique to assess the surface properties of solid samples, including in tissue engineering research where…”
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Capturing patient anatomy for designing and manufacturing personalized prostheses by Paxton, Naomi C, Nightingale, Renee C, Woodruff, Maria A

“…[Display omitted] •Prostheses can be personalized using advanced 3D scanning technologies.•3D surface scanning is an emerging trend for capturing patient…”
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Dissolvable 3D printed PVA moulds for melt electrowriting tubular scaffolds with patient-specific geometry by Brooks-Richards, Trent L., Paxton, Naomi C., Allenby, Mark C., Woodruff, Maria A.

“…[Display omitted] Melt electrowriting (MEW) is an additive manufacturing technique capable of fabricating microfibre thermoplastic scaffolds that is growing in…”
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Materials Design Innovations in Optimizing Cellular Behavior on Melt Electrowritten (MEW) Scaffolds by Devlin, Brenna L., Allenby, Mark C., Ren, Jiongyu, Pickering, Edmund, Klein, Travis J., Paxton, Naomi C., Woodruff, Maria A.

“…The field of melt electrowriting (MEW) has seen significant progress, bringing innovative advancements to the fabrication of biomaterial scaffolds, and…”
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Novel resin tissue array system reduces sample preparation time, labour and reagent costs in bone tissue histology by Ren, Jiongyu, Paxton, Naomi C., Hammond, Joshua, Saifzadeh, Siamak, Steck, Roland, Lawrence, Felicity A., Woodruff, Maria A.

“…Resin histology plays an essential role in the analysis of hard tissues, such as bone and teeth, as well as in the context of metallic implant analysis…”
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[n]Cycloparaphenylenes as Compatible Fluorophores for Melt Electrowriting by Hall, Patrick C., Reid, Harrison W., Liashenko, Ievgenii, Tandon, Biranche, O'Neill, Kelly L., Paxton, Naomi C., Lindberg, Gabriella C. J., Jasti, Ramesh, Dalton, Paul D.

“…Fluorescent probes are an indispensable tool in the realm of bioimaging technologies, providing valuable insights into the assessment of biomaterial integrity…”
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Melt Electrowriting of Nylon‐12 Microfibers with an Open‐Source 3D Printer by Reizabal, Ander, Devlin, Brenna L., Paxton, Naomi C., Saiz, Paula G., Liashenko, Ievgenii, Luposchainsky, Simon, Woodruff, Maria A., Lanceros‐Mendez, Senentxu, Dalton, Paul D.

“…This study demonstrates how either a heated flat or cylindrical collector enables defect‐free melt electrowriting (MEW) of complex geometries from high melting…”
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Degradation of Melt Electrowritten PCL Scaffolds Following Melt Processing and Plasma Surface Treatment by Paxton, Naomi C., Ho, Selina W. K., Tuten, Bryan T., Lipton‐Duffin, Josh, Woodruff, Maria A.

“…Melt electrowriting (MEW) has been widely used to process polycaprolactone (PCL) into highly ordered microfiber scaffolds with controllable architecture and…”
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Rheological Characterization of Biomaterials Directs Additive Manufacturing of Strontium‐Substituted Bioactive Glass/Polycaprolactone Microfibers by Paxton, Naomi C., Ren, Jiongyu, Ainsworth, Madison J., Solanki, Anu K., Jones, Julian R., Allenby, Mark C., Stevens, Molly M., Woodruff, Maria A.

“…Additive manufacturing via melt electrowriting (MEW) can create ordered microfiber scaffolds relevant for bone tissue engineering; however, there remain…”
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Design tools for patient specific and highly controlled melt electrowritten scaffolds by Paxton, Naomi C., Lanaro, Matthew, Bo, Arixin, Crooks, Nathan, Ross, Maureen T., Green, Nicholas, Tetsworth, Kevin, Allenby, Mark C., Gu, YuanTong, Wong, Cynthia S., Powell, Sean K., Woodruff, Maria A.

“…Melt electrowriting (MEW) has grown in popularity in biofabrication research due to its ability to fabricate complex, high-precision networks of fibres. These…”
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Manufacture of Biomimetic Auricular Surgical Implants Using 3D Printed High Density Polyethylene Microfibers by Paxton, Naomi C, Luposchainsky, Simon, Reizabal, Ander, Saiz, Paula G, Bade, Stuart, Woodruff, Maria A, Dalton, Paul D

“…This study demonstrates a new approach to manufacturing biomimetic auricular surgical implants using melt electrowriting (MEW) technology to fabricate…”
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