Development of a Cell Depositing System Using Inkjet Technology

Ozaeta, Jason Robert

01 June 2008

In the past decade, advances in tissue engineering have allowed researchers to fabricate simple tissues. However, the process of creating these native tissues is a time consuming and inefficient process. A scaffold must first be fabricated then exposed to a sea of cells in the hopes of seeding. Furthermore, even though cells may have attached, more time must be spent in order to allow the cells to migrate to their ideal locations. To deal with this problem, researchers have investigated whether rapid prototyping principals could be adapted to facilitate the cell seeding process by placing cells in their respective locations during scaffold fabrication. The goal for this thesis was to establish the foundation for a cell-compatible printer that, in the future, could fabricate pre-seeded scaffolds. This task included implementing changes to a commercial solenoid-based inkjet system that would allow cells to be loaded into the printer in a sterile fashion. In addition, protocols had to be designed with system limitations in mind. An initial test with the designed system showed a majority of cell viability percentages above 90%. If additional tests confirm this possibility, the system should be further modified to provide cells with a proper culturing environment. Furthermore, additional research would need to be performed in order to determine whether scaffolding materials can be dispensed through the system to fabricate scaffolds.

cell printing

tissue engineering

rapid prototyping

cell printing

scaffolding

Effects of Conformal Cooling Channels on Additively Manufactured Injection Molding Tooling

Whatcott, Tyler Blaine

08 December 2020

This study focuses on the cycle-averaged mold temperature of additively manufactured injection molding tooling and how it is affected by conformal cooling channels. This was done by producing a benchmark mold out of Digital ABS produced by Stratasys, an acrylic based photopolymer, which was then used to produce injection molded parts until tool failure. Another, more cost-effective material, High Temp Resin produced by Formlabs, another acrylic based photopolymer, was also tested but yielded very little success. Then the mold design was altered by adding conformal cooling channels and again tested by producing injection molded parts while tracking the mold temperature. This experimentation was then compared to an injection molding cooling channel model in order to validate the model for use with additively manufactured tooling with conformal cooling channels for use in injection molding. The benchmark Digital ABS mold was able to produce 66 shots in the injection molding machine before complete mold failure. The Digital ABS mold had a cycle-averaged mold temperature of about 155°F. The High Temp Resin mold was able to produce 3 shots before complete mold failure. The High Temp Resin material is much more brittle, and the mold design did not take into account how brittle the material was. The Digital ABS mold with conformal cooling channels had a cycle-averaged mold temperature of 111°F. This is significantly lower than without cooling channels and has a high potential for improving tooling life. The cooling channel model predicted the cycle-averaged mold temperature to be 116°F. This proved to be a very good model and can be used as a design tool when choosing cooling channel geometry and position in additively manufactured tooling. This research shows the potential that conformal cooling channels have to help improve additively manufactured tooling life for injection molding. As shown in other research done, the ability to maintain the mold below 120°F significantly improves the life of additively manufactured tooling. The results of this study demonstrate the effectiveness of conformal cooling channels in controlling mold temperature. It should be researched further, but the use of conformal cooling channels has the potential to produce more production or prototype parts with additively manufactured tooling for injection molding.

additive manufacturing

injection molding

rapid prototyping

soft tooling

conformal cooling channels

tooling life

Engineering

Novel Stereolithographic Manufacture of Biodegradable Bone Tissue Scaffolds

Cooke, Malcolm Norman

02 July 2004

No description available.

Tissue engineering

Poly(propylene fumarate)

Biodegradable scaffolds

Biocompatible porous scaffolds

Stereolithography

Rapid prototyping

APPLICATION OF REVERSE ENGINEERING AND RAPID PROTOTYPING TECHNIQUES TO CASTING

Kolar, Venkat D.

15 May 2008

No description available.

Design

Engineering

Mechanical Engineering

reverse engineering

rapid prototyping,

fused deposition modeling

RE

Application of Rapid Manufacturing Technologies to Integrated Product Development inClinics and Medical Manufacturing Industries

Owusu - Dompreh, Francis

January 2013

No description available.

Engineering

Mechanical Engineering

Technology

Biomedical Engineering

Rapid Manufacturing

Customized Implants Manufacturing

Slice Contour Modification in Additive Manufacturing for Minimizing Part Errors

Sharma, Kunal

13 October 2014

No description available.

Mechanical Engineering

Additive manufacturing

contour modification

NURBS surface

STL file

Rapid prototyping

SYNTHESIS OF MIXED-SIGNAL SYSTEMS BASED ON RAPID PROTOTYPING

GANESAN, SREELAKSHMI

January 2001

No description available.

mixed-signal

rapid prototyping

field-programmable analog array (FPAA)

Examination of Rapid Prototype Tooling

Grunden, Eric Hans

30 August 2016

No description available.

Industrial Engineering

The Creation of Solid Models of the Human Knee from Magnetic Resonance Images

Fening, Stephen D.

27 June 2003

No description available.

Engineering, Biomedical

Solid Modeling

Parametric Modeling

Knee

Meniscus

Boolean

Rapid Prototyping

Characterization of Aluminum 3003 Ultrasonic Additive Manufacturing

Schick, David E.

January 2009

No description available.

Materials Science

Ultrasonic Additive Manufacturing

Rapid Prototyping

Thermocouples

Aluminum

Heat Treating