Nutrient conduit networks can be introduced within the Polyethylene Glycol Diacrylate (PEGDA) tissue construct to enable cells to survive in the scaffold. Nutrient conduit networks can be created on PEGDA by macrochannel to nanochannel fabrication techniques. Such networks can influence the mechanical and cell activities of PEGDA scaffold. There is no study conducted to evaluate the effect of nutrient conduit networks on the maximum tensile stress and cell activities of the tissue scaffold. The study aimed to explore the influence of the network architecture on the maximum tensile stress of PEGDA scaffold and compared with the nonnetworked PEGDA scaffold. Our study found that there are 1.78 and 2.23 times decrease of maximum tensile stress due to the introduction of nutrient conduit networks to the PEGDA scaffold at 23°C and 37°C temperature conditions, respectively. This study also found statistically significant effect of network architecture, PI concentration, temperature, and wait time on the maximum failure stress of PEGDA samples (P value < 0.05). Cell viability results demonstrated that networked PEGDA hydrogels possessed increased viability compared to nonnetworked and decreased viability with increased photoinitiator concentrations. The results of this study can be used for the design of PEGDA scaffold with macrosize nutrient conduit network channels.
Large thick tissue constructs have reported limited success primarily due to the inability of cells to survive deep within the scaffold. Without access to adequate nutrients, cells placed deep within the tissue construct will die out, leading to non-uniform tissue regeneration. Currently, there is a necessity to design nutrient conduit networks within the tissue construct to enable cells to survive in the matrix. However, the design of complex networks within a tissue construct is challenging. In this paper, we present the Lindenmayer system, an elegant fractal-based language algorithm framework, to generate conduit networks in two- and three-dimensional architecture with several degrees of complexity. The conduit network maintains a parent-child relationship between each branch of the network. Several L-system parameters have been studied-branching angle, branch length, ratio of parent to child branch diameter, etc-to simulate several architectures under a given L-system notation. We have also presented a layered manufacturing-based UV-photopolymerization process using the Texas Instruments DLP system to fabricate the branched structures. This preliminary work showcases the applicability of L-system-based construct designs to drive scaffold fabrication systems.
Tissue Engineering has been studied to develop tissues as an alternative approach to the organ regeneration. Successful artificial tissue growth in regenerative medicine depends on the precise scaffold fabrication as well as the cell-cell and cell-scaffold interaction. Scaffolds are extracellular matrices that guide cells to grow in 3D to regenerate the tissues. Cell-seeded scaffolds must be implanted to the damaged tissues to do the tissue regeneration. Scaffolds’ mechanical properties and porosities are the two main scaffold fabrication parameters as the scaffolds must be able to hold the pressure due to the surrounding tissues after the implantation process. In this research, scaffolds were fabricated by photolithography and Poly(ethylene glycol) Diacrylate (PEGDA) which is a biocompatible and biodegradable material was used as a fabrication material. In order to compare the compressive properties of PEGDA only with the compressive properties of drug delivered PEGDA, firstly, PEGDA only solutions were prepared. Then, PEGDA was mixed with Meloxicam 15 mg, Hydrochlorothiazide 12.5 mg, Cyclobenzaprine 10 mg and Spironolactone-hctz 25-25 mg respectively and they were placed under the UV light for about 15 minutes to solidify the cylindrical shaped hydrogels. 5 samples from each group were fabricated under the same conditions. Laboratory temperature, photoinitiator concentration and UV light intensity was kept constant during the fabrication process. After the fabrication was completed, Instron 3369 universal mechanical testing machine with the 5 mm/min compression rate was used to do the compression tests to compare the drug effects on PEGDA hydrogels. Our results indicate that average ultimate strength of PEGDA only samples was 3.820 MPa. Also, due to the fact that Meloxicam 15 mg and PEGDA mixture did not solidify under the UV light at all, compression test could not be performed for PEGDA- Meloxicam 15 mg mixture. However, Hydrochlorothiazide 12.5 mg, Cyclobenzaprine 10 mg and Spironolactone-hctz 25-25 mg dissolved within the PEGDA completely and our compression results show that average ultimate strengths were 3.372 MPa, 1.602 MPa, 1.999 MPa respectively. This preliminary research showcases that compressive properties of the PEGDA-based photopolymerized scaffolds can be altered with the control of the drug type and drug concentration.
System engineering (SE) is a multidisciplinary approach for the design, management, and realization of a complex system. In product development, SE is utilized on structuring a product development process into simple and collaborative activities that proceed throughout the entire product life-cycle, while at the same time, supporting engineers' decision making. Project based engineering design classes are suitable for undergraduate students to study and practice the concepts of SE while solving real-world design problems. In this paper, we document the product development process, especially the structured design methodologies used in an undergraduate Senior Design project. Student learning outcomes are assessed and compared with previous semesters. We have observed overall satisfying student learning in nearly all aspects. Hence, we believe the multidisciplinary project helps students learn valuable knowledge of SE that is usually acquired through real world working experiences.
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