Scopus İndeksli Yayınlar Koleksiyonu / Scopus Indexed Publications Collection
Permanent URI for this collectionhttps://hdl.handle.net/11147/7148
Browse
4 results
Search Results
Article Citation - WoS: 6Citation - Scopus: 7Engineering Free-Standing Electrospun Pllcl Fibers on Microfluidic Platform for Cell Alignment(Springer Science and Business Media Deutschland GmbH, 2024) Yildirim-Semerci,Ö.; Arslan-Yildiz,A.Here, a PLLCL-on-chip platform was developed by direct electrospinning of poly (L-lactide-co-ε-caprolactone) (PLLCL) on polymethyl methacrylate (PMMA) microfluidic chips. Designed microchip provides the electrospinning of free-standing aligned PLLCL fibers which eliminates limitations of conventional electrospinning. Besides, aligned fiber structure favors cell alignment through contactless manipulation. Average fiber diameter, and fiber alignment was evaluated by SEM analyses, then, leakage profile of microchip was investigated. 3D cell culture studies were conducted using HeLa and NIH-3T3 cells, and nearly 85% cell viability was observed in PLLCL-on-chip for 15 days, while cell viability of 2D control started to decrease after 7 days based on Live dead and Alamar Blue analyses. These findings emphasize biocompatibility of PLLCL-on-chip platform for 3D cell culture and its ability to mimic extracellular matrix (ECM). Immunostaining results prove that PLLCL-on-chip platform favors the secretion of ECM proteins compared to control groups, and cytoskeletons of cells were in aligned orientation in PLLCL-on-chip, while they were in random orientation in control groups. Overall, these results demonstrate that the developed platform is suitable for the formation of various 3D cell culture models and a potential candidate for cell alignment studies. © The Author(s) 2024.Conference Object Serum Creatinine Detection in a Microfluidic Chip Using a Smartphone Camera(Chemical and Biological Microsystems Society, 2022) Karakuzu, B.; Tarim, E.A.; Tekin, H.C.We present a microfluidic chip platform to detect serum creatinine levels using the enzyme-linked immunosorbent assay (ELISA) principle. In the platform, surface modified microfluidic channel sensitively captured target molecules from the serum sample, and then ELISA protocol was applied inside the channels. Afterward, the blue color formed as a result of the enzymatic reaction was measured via a smartphone camera. The proposed strategy allows the detection of creatinine rapidly in a minute amount of the serum samples without the need for expensive equipment. Thus, chronic kidney disease (CKD) could be monitored easily at point-of-care settings via the proposed creatinine detection strategy. © 2022 MicroTAS 2022 - 26th International Conference on Miniaturized Systems for Chemistry and Life Sciences. All rights reserved.Article Introducing Engineering Students To Microfluidics and 3d Printing Using Hands-On Activities(American Society for Engineering Education, 2023) Dogan, E.; Borgaonkar, A.D.; Nafisi, N.; Miri, A.K.Microfluidics technology involves the regulation of flow in micron-sized channels for desired reactions, with applications in biological modeling, drug manufacturing, screening of biological agents, and various engineering fluid dynamics-related purposes. Despite its growth and development, microfluidics has not been widely included as a teaching topic in undergraduate engineering education. This manuscript presents a hands-on project-based learning approach that can be easily implemented into core engineering courses, such as fluid mechanics, transport, chemical reactions, and others. Project-based activities presented here have three main parts: material preparation based on synthetic polymers, light-assisted manufacturing of a microfluidic device, and mass transport experiments to observe the fluid behavior. The project leverages 3D printing and the potential to connect students with makerspaces and 3D printing and to get them started on the path to bringing their ideas to life. The paper includes a breakdown of how to access and evaluate these activities. As a result of this hands-on activity, students will understand how fluid mechanics concepts are applied to microfluidics. Students will also learn about a novel interdisciplinary field that is growing rapidly. Engineering technology students will benefit from exposure to the application side of this emerging field through these lab-style activities that they are accustomed to in the majority of their core courses. Finally, the authors hope that such successful integration will encourage faculty to introduce other novel science and engineering topics that are currently only accessible through research experiencebased courses. © 2023, American Society for Engineering Education. All rights reserved.Article Citation - WoS: 8Citation - Scopus: 11Cost-Effective and Rapid Prototyping of Pmma Microfluidic Device Via Polymer-Assisted Bonding(Springer, 2021) Sözmen, Alper Baran; Arslan Yıldız, AhuMicrofluidic systems are relatively new technology field with a constant need of novel and practical manufacturing materials and methods. One of the main shortcomings of current methods is the inability to provide rapid bonding, with high bonding strength, and sound microchannel integrity. Herein we propose a novel method of assembly that overcomes the mentioned limitations. Polymer-assisted bonding is a novel, rapid, simple, and inexpensive method where a polymer is solubilized in a solvent and the constituted solution is used as a bonding agent. In this study, we combined this method with utilization of several phase-changing materials (PCMs) as channel-protective agents. Glauber's salt appeared to be more suitable as a channel-protective agent compared to rest of the salts that have been used in this study. Based on the bonding strength, quality analyses, leakage tests, and SEM imaging, the superior assisting bonding solvent was determined to be dichloromethane with a PMMA concentration of 2.5% (W/V). It showed a bonding strength of 23.794 MPa and a nearly non-visible bonding layer formation of 2.83 mu m in width which is proved by SEM imaging. The said combination of PCM, solvent, and polymer concentration also showed success in leakage tests and an application of micro-droplet generator fabrication. The application was carried out to test the applicability of developed prototyping methodology, which resulted in conclusive outcomes as the droplet generator simulation run in COMSOL Multiphysics version 5.1 software. In conclusion, the developed fabrication method promises simple, rapid, and strong bonding with sharp and clear micro-channel engraving.