TY - JOUR
T1 - Magnetic Nozzle‐Free Embedded 3D (MagNoFE3D) Printing
AU - Piñan Basualdo, Franco N.
AU - Trikalitis, Vasileios D.
AU - Visconti, Sabrina
AU - Ficuciello, Fanny
AU - Goulas, Constantinos
AU - Rouwkema, Jeroen
AU - Misra, Sarthak
PY - 2024/10/10
Y1 - 2024/10/10
N2 - The functional principle behind extrusion-based printing is the capability of flowing material through a nozzle on demand, which must solidify upon deposition, a behavior exhibited only by some materials. Embedded printing offers a solution to maintain shape fidelity during the deposition of a wider range of materials. However, the use of a moving nozzle in a support bath can lead to bath disturbance and the spreading of the ink. In this study, a novel embedded printing technique that eliminates the need for a nozzle by employing a magnetic sphere as the plotting moiety is introduced. The externally steered sphere creates a path by locally fluidizing the bath, allowing the simultaneously injected ink to flow into the space behind it. The method is benchmarked using water as an ink, achieving free-form printing without additional stabilization methods. The creation of solid structures is also demonstrated by printing a photocurable ink that is crosslinked and removed from the bath. Moreover, the plotting magnet can be incorporated into the printed part during the crosslinking, thus giving place to a magnetically responsive structure. This advancement paves the way for innovations in fields such as tissue engineering and microrobotics by enabling the fabrication of intricate and functional designs.
AB - The functional principle behind extrusion-based printing is the capability of flowing material through a nozzle on demand, which must solidify upon deposition, a behavior exhibited only by some materials. Embedded printing offers a solution to maintain shape fidelity during the deposition of a wider range of materials. However, the use of a moving nozzle in a support bath can lead to bath disturbance and the spreading of the ink. In this study, a novel embedded printing technique that eliminates the need for a nozzle by employing a magnetic sphere as the plotting moiety is introduced. The externally steered sphere creates a path by locally fluidizing the bath, allowing the simultaneously injected ink to flow into the space behind it. The method is benchmarked using water as an ink, achieving free-form printing without additional stabilization methods. The creation of solid structures is also demonstrated by printing a photocurable ink that is crosslinked and removed from the bath. Moreover, the plotting magnet can be incorporated into the printed part during the crosslinking, thus giving place to a magnetically responsive structure. This advancement paves the way for innovations in fields such as tissue engineering and microrobotics by enabling the fabrication of intricate and functional designs.
KW - UT-Hybrid-D
UR - http://www.scopus.com/inward/record.url?scp=85205800687&partnerID=8YFLogxK
U2 - 10.1002/admt.202401097
DO - 10.1002/admt.202401097
M3 - Article
SN - 2365-709X
JO - Advanced Materials Technologies
JF - Advanced Materials Technologies
M1 - 2401097
ER -