Mojo 3d printer

Manufactured by Stratasys

Sourced in United States

The Mojo 3D printer is a compact and easy-to-use desktop 3D printer designed for professional and educational environments. It offers a build volume of 5 x 5 x 6 inches (127 x 127 x 152 mm) and utilizes fused deposition modeling (FDM) technology to create 3D printed parts from thermoplastic materials.

Automatically generated - may contain errors

Lab products found in correlation

Autocad, by Autodesk (2 mentions) Palmitic acid, by Fujifilm (1 mentions) Solidworks, by Dassault Systèmes (1 mentions)

Spelling variants of this product

3D printer (6 citations)

7 protocols using mojo 3d printer

Design and Fabrication of ESCAR Device

Cited 1 time

Check if the same lab product or an alternative is used in the 5 most similar protocols

The design and fabrication of ESCAR were described in detail in our previous paper (22 (link)). Briefly, ESCAR was designed with the aid of AutoCAD (Autodesk Inc., CA, USA) and fabricated by a Mojo 3D printer (Stratasys, Inc., MN, USA) followed by a series of post-printing procedures. ABSplus^™ white was used as the printing material and SR-30^™ was used as the soluble support material. ESCAR consisted of three chambers: one “SC” chamber at the center, and two “blood circulation” chambers on the left and right sides. The “SC” chamber, as seen in Fig. 1, had a dimension of 3 cm in length × 2.5 cm in height × 1 cm in width and two open windows (length 3 cm; height 2.5 cm; surface area 7.5 cm²). The “blood circulation” chamber had an open window (length 3 cm; height 2.2 cm; surface area 6.6 cm²). Therefore, the total surface area available for drug permeation (

{S A}_{permeation}

) was 13.2 cm² (6.6 cm² × 2).

Fujiwara T., Tanaka K., Inoue E., Kikyo M, & Takai Y. (1999). Bni1p Regulates Microtubule-Dependent Nuclear Migration through the Actin Cytoskeleton in Saccharomyces cerevisiae. Molecular and Cellular Biology, 19(12), 8016-8027.

+ Open protocol

+ Expand

3D Printed Watertight ESCAR Layout

Check if the same lab product or an alternative is used in the 5 most similar protocols

The ESCAR layout was drawn using AutoCAD (Autodesk Inc., San Rafael, CA, USA). Each component was printed using a Mojo 3D printer (Stratasys, Inc., Edina, MN, USA) via the fused deposition modeling technology. ABSplus white (an acrylonitrile butadiene styrene-based thermoplastic material) and SR-30 were utilized as the printing material and the support material, respectively. After printing, the support material was removed by the Ecoworks-based solution with the aid of a WaveWash 55 Clean system (Stratasys, Inc., Edina, MN, USA). Acetone was sprayed onto the outer and inner surfaces to make the components watertight. Sequentially, the acetone-treated components were placed under (i) ambient temperature overnight and then (ii) at 50 °C in a convection oven for at least 72 h to remove the acetone residues. Furthermore, all the contact surfaces were smoothened by a series of sandpapers with medium grits and superfine grits.

Chan D.C., Chutkowski C.T, & Kim P.S. (1998). Evidence that a prominent cavity in the coiled coil of HIV type 1 gp41 is an attractive drug target. Proceedings of the National Academy of Sciences of the United States of America, 95(26), 15613-15617.

+ Open protocol

+ Expand

3D Printed Grooved Barrel for Tubing

Check if the same lab product or an alternative is used in the 5 most similar protocols

A grooved barrel was printed using a Mojo 3D printer (Stratasys, Eden Prairie, MN, USA). The barrel has a diameter of 2.2 cm and a spiral groove with a width of 2 mm and a depth of 2 mm, and a pitch of 6 mm (Figure 2c). The barrel is used for geometric guidance, which ensures that the tubing has a fixed radius of curvature (~1 cm) and coiling pitch.

Hahn Y.K., Hong D., Kang J.H, & Choi S. (2016). A Reconfigurable Microfluidics Platform for Microparticle Separation and Fluid Mixing. Micromachines, 7(8), 139.

+ Open protocol

+ Expand

Portable Thermal Regulation Device Design and Assembly

Check if the same lab product or an alternative is used in the 5 most similar protocols

The PS container was fabricated by combining 2.0-cm-thick polystyrene boards. A 1.0-cm-diameter hole was created in the lid to direct the generated water vapor and hydrogen outside the container. A 2.0-mm-thick piece of chloroprene rubber was placed between the top of the container and lid, providing a seal between the lid and container. Two bands were placed around the PS container to fix the lid to the container.
The stand and frame were fabricated using a Mojo 3D printer (Stratasys, Rehovot, Israel) with an ABS resin (Mojo P430 QuickPack Print Engine, Stratasys).
The PP container was made of a 200-µm-thick PP film. The stand and 80 g of palmitic acid (Wako Pure Chemical Industries, Ltd., Osaka, Japan) were placed inside the container, and a handle made of PP film was placed on top of the PP container for easy operation. palmitic acid (C₁₆H₃₂O₂) is a type of saturated fatty acid with a melting point of 62.9 °C.
A commercially available exothermic agent (Morians Heat Pack size L; Morian Heat Pack Co. Ltd., Irima City, Japan; http://www.morians.co.jp/morians/structure.html) and a VI container (SR250; ASVEL, Yamatokoriyama-shi, Japan) were also used as components for the device. The main components of the exothermic agent consisted of calcium oxide and aluminum, and 45 g was used in this experiment.

Kimura Y, & Ikeuchi M. (2023). Development of non-electrically controlled SalivaDirect LAMP (NEC-SD-LAMP), a new nonelectrical infectious disease testing method. Scientific Reports, 13, 11791.

+ Open protocol

+ Expand

Disposable Glove-based Sensor Fabrication

Check if the same lab product or an alternative is used in the 5 most similar protocols

Fabrication of the disposable glove-based sensor was carried out utilizing a semiautomatic MPM-SPM screen printer (Speedline Technologies, Franklin, MA). A 125 μm thick stainless-steel stencil (Metal Etch Services, San Marcos, CA) was designed using AutoCAD and laser-cut. To facilitate a smooth and planar printing surface, a finger mold (10.0 × 2.3 × 1.3 cm³) was drawn using SolidWorks 3D CAD (DS SolidWorks, Waltham, MA) and printed using a Mojo 3D printer (Stratasys, Eden Prairie, MN). The 3D printed molds were inserted into the nitrile gloves before screen-printing the sensor structures. The Ag/AgCl layer was printed on the index finger as the reference electrode and as a connecting pad, followed by a layer of carbon and an insulator layer to complete the sensing electrode. The screen-printed sensor was cured at 70°C for 10 min after each layer was printed. The Ag/AgCl-based ink served as the reference electrode, whereas carbon ink was used for the working and counter electrodes. The transparent insulating layer was carefully printed on the sensor interconnects to provide a dielectric segregation of the three-electrode system and to subside sensors short-circuits. (Reviewer 2, comment#3) The same printing procedure was used to print a circular carbon pad (1 cm diameter) on the thumb finger.

Barfidokht A., Mishra R.K., Seenivasan R., Liu S., Hubble L.J., Wang J, & Hall D.A. (2019). Wearable electrochemical glove-based sensor for rapid and on-site detection of fentanyl. Sensors and actuators. B, Chemical, 296, 126422.

+ Open protocol

+ Expand

Intracranial Artery Stenosis Model Creation

Cited 1 time

Check if the same lab product or an alternative is used in the 5 most similar protocols

A human-specific intracranial artery stenosis model was created by modifying a prior method to build a brain aneurysm model.^{12 (link), 13 (link)} Digital Imaging and Communication in Medicine (DICOM) data acquired from CT angiography were exported, and the 3D vessel image was converted to a stereolithography format (.stl). The wall shear stress distribution, streamlines, and flow velocity were calculated and visualized for the model. Patient-specific vascular molds were fabricated using a Mojo 3D printer (Stratasys, Eden Prairie, Minnesota, USA). The vascular molds made of acrylonitrile butadiene styrene (ABS) were soaked in ABS solvent and chemically smoothed to remove the stair-like layers of the printed objects.^{13 (link)} After drying, degassed polydimethylsiloxanes (PDMS) were coated and cured on the cast, and hollow stenosis models acquired by removing the mold.

Kaneko N., Satta S., Komuro Y., Muthukrishnan S.D., Kakarla V., Guo L., An J., Elahi F., Kornblum H.I., Liebeskind D.S., Hsiai T, & Hinman J.D. (2020). Flow-mediated Susceptibility and Molecular Response of Cerebral Endothelia to Sars-CoV-2 Infection. Stroke, 52(1), 260-270.

+ Open protocol

+ Expand

Noninvasive OA Rat Model Development

Check if the same lab product or an alternative is used in the 5 most similar protocols

The noninvasive OA rat model was established as described previously [20 (link)]. Animals were anesthetized and maintained using isoflurane, and the noninvasive anterior crucial ligament rupture model was established using the indicated machine: Electroforce 3200 (Bose Corp., MN, USA), Solidworks (Dassault Systemes, MA, USA), or Mojo 3D printer (Stratasys, MN, USA). After the model was established, we intraarticularly injected PBS or recombinant Atsttrin once a week for 4 weeks in total. After 4 weeks of treatment, the rats were sacrificed for histological evaluation.

Wei J.L., Fu W., Ding Y.J., Hettinghouse A., Lendhey M., Schwarzkopf R., Kennedy O.D, & Liu C.J. (2017). Progranulin derivative Atsttrin protects against early osteoarthritis in mouse and rat models. Arthritis Research & Therapy, 19, 280.

+ Open protocol

+ Expand

About PubCompare

Our mission is to provide scientists with the largest repository of trustworthy protocols and intelligent analytical tools, thereby offering them extensive information to design robust protocols aimed at minimizing the risk of failures.

We believe that the most crucial aspect is to grant scientists access to a wide range of reliable sources and new useful tools that surpass human capabilities.

However, we trust in allowing scientists to determine how to construct their own protocols based on this information, as they are the experts in their field.

Ready to get started?

Revolutionizing how scientists
search and build protocols!