A Personalized Multifunctional 3D Printed Shape Memory‐Displaying, Drug Releasing Tracheal Stent

Maity, Nabasmita; Mansour, Nicola; Chakraborty, Priyadarshi; Bychenko, Darya; Gazit, Ehud; Cohn, Daniel

doi:10.1002/adfm.202108436

Cited by 36 publications

(27 citation statements)

References 55 publications

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“…Highest MW photopolymers tested PPF (31 000 g mol -1 ) with 50 wt% DEF [67] Poly(CL-co-DLLA)-MA (15 000 g mol -1 ) with 8 wt% NVP [68] NA NA Estimated value in theory and from the literature (refs. [68][69][70][71][72][73][74]); b) Obtained from the information sheet of xolo GmbH; c) Average 20-35 mm h -1 for commercial DLP printers obtained from gorillaoutput.com; d) Currently only for small objects in the centimeter range; NA: not available.…”

Section: Techniquementioning

confidence: 99%

“…[ 70 ] Most recently, they further improved the 3D printing materials by developing poly(propylene glycol)/PCL triblock photopolymers with MW ranging from 9700 to 13 700 g mol –1 . [ 71 ] The 3D printed tracheal stents exhibited largely increased flexibility due to the introduction of poly(propylene glycol) segments (typical MW of 8000 g mol –1 ), while maintaining excellent shape‐memory properties (Figure 3b).…”

Section: Heat‐assisted Vat Photopolymerizationmentioning

confidence: 99%

“…Reproduced with permission. [ 71 ] Copyright 2021, Wiley‐VCH. c) 3D printed gyroid scaffolds, ear model, and vascular model from copolymers of D,L‐LA and CL with varied MW, and cell staining after they were seeded on the 3D printed films at day 1.…”

Section: Heat‐assisted Vat Photopolymerizationmentioning

confidence: 99%

See 2 more Smart Citations

Challenges and Opportunities in 3D Printing of Biodegradable Medical Devices by Emerging Photopolymerization Techniques

Bao

Paunović

Leroux

2022

Adv Funct Materials

145

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Since the first report of 3D printed biodegradable structures by stereolithography, vat photopolymerization has shown great potential in the fabrication of medical implants and devices. Despite its superior printing quality and manufacturing speed, the development of biodegradable devices by this technique remains challenging. This results from the conflicting viscosity requirements for the printing resins, i.e., low viscosity is required for highresolution 3D printing, whereas high viscosity is often needed to provide high mechanical strength. Recently emerging photopolymerization-based 3D printing techniques, including heat-assisted digital light processing (DLP) and volumetric printing, have brought new hope to the field. With its tolerance to high viscosity resins, heat-assisted DLP enables the fabrication of complex, personalizes architectures from biodegradable photopolymers that are not printable by conventional printing techniques. On the other hand, volumetric printing, which abandons the layer-by-layer printing principle and thus circumvents the dependence on low viscosity resins, could be highly beneficial for the 3D printing of biodegradable devices. This perspective evaluates the key challenges associated with biodegradable photopolymers used in the 3D printing of medical implants and devices. One focuses on their chemical structures and physical properties and discusses future directions offered by these emerging techniques.

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Section: Techniquementioning

confidence: 99%

Section: Heat‐assisted Vat Photopolymerizationmentioning

confidence: 99%

See 1 more Smart Citation

Challenges and Opportunities in 3D Printing of Biodegradable Medical Devices by Emerging Photopolymerization Techniques

Bao

Paunović

Leroux

2022

Adv Funct Materials

145

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show abstract

“…[1][2][3] As a chemical process-based 3D printing technique, vat photopolymerization possesses remarkable advantages, such as flexible material design, high print resolution, fast printing, and smooth print surface. [4][5][6] As most commonly used vat photopolymerization methods, stereolithography (SLA), [7,8] digital light processing (DLP), [9,10] and continuous liquid interface production (CLIP) [11,12] have shown wide DOI: 10.1002/marc.202200202 potential in customized fabrication of tissue scaffolds, [13,14] medical devices, [15,16] soft robots, [17,18] dental implants, [19,20] microfluidic devices [21,22] and drug delivery systems. [6,23] SLA and DLP usually rely on the layer-bylayer solidification of a liquid resin containing (macro)monomers that can be photocrosslinked under light irradiation in the presence of a photoinitiator.…”

Section: Introductionmentioning

confidence: 99%

Recent Trends in Advanced Photoinitiators for Vat Photopolymerization 3D Printing

Bao

2022

Macromol. Rapid Commun.

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3D printing has revolutionized the way of manufacturing with a huge impact on various fields, in particular biomedicine. Vat photopolymerization‐based 3D printing techniques such as stereolithography (SLA) and digital light processing (DLP) attract considerable attention owing to their superior print resolution, relatively high speed, low cost, and flexibility in resin material design. As one key element of the SLA/DLP resin, photoinitiators or photoinitiating systems have experienced significant development in recent years, in parallel with the exploration of 3D printing (macro)monomers. The design of new photoinitiating systems cannot only offer faster 3D printing speed and enable low‐energy visible light fabrication, but also can bring new functions to the 3D printed products and even generate new printing methods in combination with advanced optics. This review evaluates recent trends in the development and application of advanced photoinitiators and photoinitiating systems for vat photopolymerization 3D printing, with a wide range of small molecules, polymers, and nanoassemblies involved. Personal perspectives on the current limitations and future directions are eventually provided.

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“…Therefore, 4D printing of implants that conform to biological curvature can be a potential technology for reconstitution of defective organs and tissues. Various 4D printing strategies have been applied for the manufacture of surgical implants on recent trends, such as bone scaffolds [ 30 , 31 ], tracheal stents [ 28 , 32 ], and cardiac patches [ 29 ]. Their deformation mainly depends on two types of materials: (i) shape memory polymers (SMPs), such as thermo-sensitive polycaprolactone-based composites [ 32 ]; (ii) responsive shape morphing materials, such as 3D structures deformed by anisotropic swelling property distributed spatially [ 28 ].…”

Section: Introductionmentioning

confidence: 99%

4D-printed bilayer hydrogel with adjustable bending degree for enteroatmospheric fistula closure

Qu¹,

Huang²,

Li³

et al. 2022

Materials Today Bio

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A Personalized Multifunctional 3D Printed Shape Memory‐Displaying, Drug Releasing Tracheal Stent

Cited by 36 publications

References 55 publications

Challenges and Opportunities in 3D Printing of Biodegradable Medical Devices by Emerging Photopolymerization Techniques

Challenges and Opportunities in 3D Printing of Biodegradable Medical Devices by Emerging Photopolymerization Techniques

Recent Trends in Advanced Photoinitiators for Vat Photopolymerization 3D Printing

4D-printed bilayer hydrogel with adjustable bending degree for enteroatmospheric fistula closure

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