Visijet s300

Manufactured by 3D Systems

Sourced in United States

The VisiJet S300 is a high-performance 3D printing material produced by 3D Systems. It is a thermoplastic material designed for use in 3D printing systems. The VisiJet S300 offers precise and consistent printing results, making it suitable for a variety of applications.

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Lab products found in correlation

Visijet m3 crystal, by 3D Systems (5 mentions) Projet 3500 hdmax, by 3D Systems (3 mentions) Sw pro, by Dassault Systèmes (2 mentions) Projet hd3500, by 3D Systems (2 mentions) Ease release 200, by Smooth-On (2 mentions) Visijet crystal, by 3D Systems (1 mentions) Cyclohexane, by Avantor (1 mentions) Phosphate buffer saline (pbs), by Merck Group (1 mentions) Ethanol, by Avantor (1 mentions) N hexane, by Avantor (1 mentions) Dimethyl sulfoxide (dmso), by Merck Group (1 mentions) Bovine serum albumin (bsa), by Merck Group (1 mentions)

7 protocols using visijet s300

Transparent 3D Printing Materials for Microfluidics

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VisiJetCrystal EX200, (along with its support material VisiJet S300), Watershed 11122XC, and Dreve Fototec SLA 7150 Clear were selected due to their transparency and potential use in imaging. ABSplus P-430 was selected to represent fused deposition modelling (FDM) fabrication methods.
VisiJet® Crystal and VisiJet® S300 Support Material was supplied by 3D Systems, Australia. WaterShed XC 11122 was supplied by Somos, Australia. Dreve Fototec 7150 Clear was supplied by Dreve Otoplastik GmbH, Germany. The composition of these materials is proprietary, however they are typically based upon acrylate monomers (available information on contents can be found in Table S2 in ESI†). Acrylonitrile butadiene styrene (ABS) 655 cm³ rolls were obtained from Solutions 2 Enterprise, UK. SLA, inkjet^{29 (link)} and digital processing SLA (DP-SLA)^{5 (link)} using photopolymers provide the highest resolutions for microfluidic applications. Further information regarding 3D printer materials used in biological applications for microfluidics is available in the literature.^{17 (link)}

Macdonald N.P., Zhu F., Hall C.J., Reboud J., Crosier P.S., Patton E.E., Wlodkowic D, & Cooper J.M. (2015). Assessment of biocompatibility of 3D printed photopolymers using zebrafish embryo toxicity assays †Electronic supplementary information (ESI) available: Supporting Fig. S1–2 and Table T1. See DOI: 10.1039/c5lc01374g Click here for additional data file. ‡We would also want to draw the attention of the reader to the availability of the dataset associated with this paper, available here (http://dx.doi.org/10.5525/gla.researchdata.238).. Lab on a Chip, 16(2), 291-297.

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3D Printed Capsule Cutting-Sealing Platform

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Design of the capsule cutting-sealing platform was carried out using Solidworks software (Dassault Systèmes, SW PRO). Printing was done using the ProJet 3500 HDMax (3D systems) 3D printer. VisiJet M3 Crystal and VisiJet S300 (3D systems, 1.0000-M06 and 1.0000-M03) served as printing material and support material, respectively. Schematics are deposited on https://www.thingiverse.com/thing:4005301.

Mashinchian O., Hong X., Michaud J., Migliavacca E., Lefebvre G., Boss C., De Franceschi F., Le Moal E., Collerette-Tremblay J., Isern J., Metairon S., Raymond F., Descombes P., Bouche N., Muñoz-Cánoves P., Feige J.N, & Bentzinger C.F. (2022). In vivo transcriptomic profiling using cell encapsulation identifies effector pathways of systemic aging. eLife, 11, e57393.

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3D-Printed Membrane Supports for Filtration

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The membrane supports were fabricated by using non-porous urethane acrylate oligomers (acrylonitrile butadiene styrene (ABS)) and proprietary hydroxylated wax (VisiJet® S300, 3D Systems, USA) in a MJP 3D printer (ProJet 3500 HD Max printer, 3D Systems, USA).
Polyethersulfone (PES, Ultrason, Mw = 55 kDa, BASF), as main polymer, polyethylene glycol (PEG, Mw = 400 g mol -1 , Sigma), as pore former, and dimethyl sulfoxide (DMSO, purity > 99%, Sigma, 80 g), as solvent, were used to prepare the dope solution for the selective layer. Phosphate buffer saline (PBS, pH = 7.4, Sigma) tablets, deionized water (DI, Veolia purification system, resistivity = 18.2 MΩ) were used for the preparation of PBS solutions. Commercial EZ Rinse-C oil (3D Systems, USA) was used for removing the wax from the pores of the printed membrane supports. Bovine serum albumin (BSA, 1 g L -1 , Mw = 67 kDa, pH = 7.0, heat shock fraction grade, purity > 98 %, Sigma) was used as the model foulant. Cyclohexane (99 %, VWR), n-Hexane (98.5 %, VWR), acetone (99 %, Sigma), isopropanol (99.5 %, VWR) and ethanol (99 %, VWR) were used in the chemical compatibility test.

Mazinani S., Al-Shimmery A., Chew Y.M.J, & Mattia D. (2019). 3D Printed Fouling-Resistant Composite Membranes. ACS applied materials & interfaces, 11(29).

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Fabrication of Customizable CI Actuators

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The mold was designed using SolidWorks software (Dassault Systèmes SolidWorks Corp., United States) to create the CI actuators with constructible convex and concave parts. Each mold had various sizes by controlling the height and radius. Notably, there was the gap between two convex and concave molds of 0.5 mm so that the CI actuator fabricated by the molds has a thickness of 0.5 mm. This design was printed using a 3D printer (ProJet HD 3500, 3D Systems Inc., United States) [Materials: part (VisiJet M3 Crystal, 3D Systems Inc., United States) and supporter (VisiJet S300, 3D Systems Inc., United States)]. In order to remove the supporter of the output mold, it was placed in a 75°C convection oven (DCF-31-N, Dae Heung Science, South Korea) for 6 h. All remaining supporters were removed from the oil bath in an ultrasonic cleaner (SaeHan Ultrasonic Co., South Korea). After washing and drying, in order to prevent silicone from sticking to the surface of the mold, a release agent (Ease release 200, Smooth-On, Inc., United States) was sprayed and dried for 30 min.

Song K, & Cha Y. (2020). Hemispherical Cell-Inspired Soft Actuator. Frontiers in Bioengineering and Biotechnology, 8, 20.

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Capsule Cutting-Sealing Platform Design

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Mashinchian O., Hong X., Michaud J., Migliavacca E., Lefebvre G., Boss C., Franceschi F.D., Moal E.L., Collerette-Tremblay J., Isern J., Raymond F., Raymond F., Descombes P., Bouché N., Muñoz‐Cánoves P., Feige J.N., & Bentzinger C.F. (2020). In Vivo Transcriptomic Profiling using Cell Encapsulation Identifies Effector Pathways of Systemic Aging.

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3D Printing of Detailed Dental Models

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The machine, ProJet 3500 HDMax (3D Systems, South Carolina, America), used for 3D printing has a precision of 16 μm and can be used with two materials [4 (link)]. The printer use UV-curable plastic, VisiJet M3 Crystal (3D Systems, South Carolina, America), and support material, VisiJet S300 (3D Systems, South Carolina, America), which allow for hands-free, melt-away removal without damaging the delicate structures. Every tooth was created in duplicate, such that there were six experimental pairs, including twelve pairs of root canals.

Cui Z., Wei Z., Du M., Yan P, & Jiang H. (2018). Shaping ability of protaper next compared with waveone in late-model three-dimensional printed teeth. BMC Oral Health, 18, 115.

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Mold Design and Fabrication for Beam Specimens

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A mold for beam-shaped specimens (50 mm length × 5 mm width × 1 mm thickness) was designed using Solidworks software (Dassault Systems Solidworks Corp., Waltham, MA, USA). Specifically, the mold was made using a 3D printer (ProJet HD3500, 3D Systems Inc., Rock Hill, SC, USA). The designed mold was made of part (VisiJet M3 Crystal, 3D Systems Inc., USA) and supporter (VisiJet S300, 3D Systems Inc., USA) materials. After printing, the mold was heated in a convection oven (DCF-31-N, Dae Heung Science, Incheon, Korea) for melting the supporter. Lastly, the supporter was completely removed from the mold in an oil bath in an ultrasonic cleaner (Sae Han Ultrasonic Co., Seoul, Korea). After washing and drying, a release agent (Ease release 200, Smooth-On, Inc., Macungie, PA, USA) was sprayed on the mold surface to prevent the silicone from sticking to the surface of the mold.

Song K, & Cha Y. (2018). Fe3O4–Silicone Mixture as Flexible Actuator. Materials, 11(5), 753.

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