Your search keyword '"Elbuken, Caglar"' showing total 6 results

1. Highly sensitive electrical detection and manipulation of microdroplets on a portable and lowcost microfluidic platform

Author

Isgor, Pelin Kubra, Moschou, Despina, and Elbuken, Caglar

Published

2017

2. LoC SENSOR ARRAY PLATFORM FOR REAL-TIME COAGULATION MEASUREMENTS

Author

Cakmak, Onur, Necmettin KILINC, Ermek, Erhan, Mostafazadeh, Aref, Elbuken, Caglar, Yaralioglu, Goksenin G., Urey, Hakan, and IEEE

3. Fabrication of Nanowalled Catalytically Self-Threaded Supramolecular Polyrotaxane Microcapsules Using Droplet Microfluidics

Author

Elnaz Alizadeh-Haghighi, Aisan Khaligh, Ali Kalantarifard, Caglar Elbuken, Dönüs Tuncel, Alizadeh-Haghighi, Elnaz, Khaligh, Aisan, Kalantarifard, Ali, Elbuken, Caglar, and Tuncel, Dönüs

Subjects

nanowalled microcapsules, monodispersity, interfacial polymerization, Polymers and Plastics, 2D polyrotaxane network, Process Chemistry and Technology, Organic Chemistry, microfluidics, supramolecules, drug release

Abstract

Micrometer-scale monodisperse droplets are produced to generate nanowalled supramolecular microcapsules using microfluidics for high reproducibility and high-throughput manipulation, efficient material consumption, and control over hierarchical structure, shape, and size. In this study, an optimized microfluidic droplet generation technique and a unique liquid–liquid interfacial polymerization method were applied to fabricate the monodisperse polyrotaxane–based supramolecular microcapsules in a fast and simple way. To minimize the uncertainty due to droplet volume variation, the inlet pressures were supplied from the same source while lowering the interfacial tension and the main channel hydrodynamic resistance, which are critical for high monodispersity. The target polyrotaxane network (PN) was simply formed at the interface of the water and oil phases in ultra-monodisperse microdroplets via the cucurbit[6]uril (CB6)-catalyzed azide–alkyne cycloaddition (CB6-AAC) reaction between azido- and alkyne-functionalized tetraphenylporphyrin monomers (TPP-4AZ and TPP-4AL). The thickness of the interfacially assembled PN microcapsules was 20 nm as analyzed by cross-sectional TEM and TEM-EDX techniques. The resultant water-in-oil PN microcapsules were highly monodisperse in size and able to retain target molecules. Here, rhodamine 6G (Rh6G)-loaded PN microcapsules were fabricated, and the release rate of the Rh6G cargo was investigated over time for controlled drug release applications.

Published

2022

4. Macroporous Surgical Mesh from a Natural Cocoon Composite

Author

Yong-Ming Chen, Lian-Sheng Zang, Behlul Koc-Bilican, Ismail Bilican, Chris Holland, Demet Cansaran-Duman, Tugce Karaduman, Arzu Çolak, Yasin Bayır, Zekai Halici, Sevilay Ozmen, Asad Ali, Jalel Labidi, Caglar Elbuken, Murat Kaya, Bilican, Ismail, Elbuken, Caglar, and Sabire Yazıcı Fen Edebiyat Fakültesi

Subjects

Sustainable material, Tissue Engineering, Renewable Energy, Sustainability and the Environment, General Chemical Engineering, Fibroin, Environmental Chemistry, Biocompatibility, Tissue engineering, General Chemistry, Surgical mesh, Surgical Mesh, Sericin, Sustainable Material

Abstract

Recently, traditional polymer-based surgical meshes have drawn unwanted attention as a result of host tissue complications arising from infection, biocompatibility, and mechanical compatibility. Seeking an alternative solution, we present a hierarchically structured nanofibrous surgical mesh derived from the naturally woven cocoon of the Japanese giant silkworm, termed MothMesh. We report that it displays nontoxicity, biocompatibility, suitable mechanical properties, and porosity while showing no adverse effect in animal trials and even appears to enhance cell proliferation. Hence, we assert that the use of this natural material may provide an effective and improved alternative to existing synthetic meshes.

Published

2022

5. Sponge-derived natural bioactive glass microspheres with self-assembled surface channel arrays opening into a hollow core for bone tissue and controlled drug release applications

Author

Martin V. Sørensen, Ebru Toksoy Oner, Ilker Torun, Lalehan Akyuz, Idris Sargin, Merve Erginer Hasköylü, Muhammad Mujtaba, Aldo R. Boccaccini, Demet Cansaran-Duman, Ismail Bilican, Caglar Elbuken, Kai Zheng, M. Serdar Onses, Murat Kaya, Kaya, Murat, Bilican, Ismail, Mujtaba, Muhammad, Sargin, Idris, Haskoylu, Merve Erginer, Oner, Ebru Toksoy, Zheng, Kai, Boccaccini, Aldo R., Cansaran-Duman, Demet, Onses, M. Serdar, Torun, Ilker, Akyuz, Lalehan, Elbuken, Caglar, Sorensen, Martin Vinther, Rektörlük, and Elbüken, Çağlar

Subjects

Materials science, Bone tissue, Silica fume, General Chemical Engineering, Simulated body fluid, FABRICATION, 02 engineering and technology, SPICULES, 010402 general chemistry, SCAFFOLDS, 01 natural sciences, Industrial and Manufacturing Engineering, Biosilica, law.invention, SDG 3 - Good Health and Well-being, law, Porous beads, NANOPARTICLES, medicine, Environmental Chemistry, ENCAPSULATION, SILICA, Bone regeneration, Porosity, Nanoscopic scale, Macroporous silica, General Chemistry, Drug release, CHEMOTHERAPY, 021001 nanoscience & nanotechnology, HYDROXYAPATITE, POLYMERIC MICELLES, 0104 chemical sciences, Porifera, medicine.anatomical_structure, Chemical engineering, Bioactive glass, Drug delivery, Geodia, 0210 nano-technology, Sterrasters

Abstract

*Bilican, Ismail ( Aksaray, Yazar ), Porous, bioactive microspheres have always been a dream material to biomedical scientists for bone regeneration and drug delivery applications due to their interconnectivity, unique pore geometry, encapsulation ability and porosity spanning macroscopic, microscopic and nanoscopic length scales. Extensive efforts have been made to produce such materials synthetically at a great cost of money, time and labor. Herein, naturally-assembled multifunctional, open-channeled and hollow bioactive micro silica spheres (diameter 209.4 +/- 38.5 mu m) were discovered in a marine sponge (Geodia macandrewii), by peeling the outer surface of the sterrasters using hydrogen fluoride. The obtained micro silica spheres exhibited valuable characteristics such as homogeneously distributed pores, a cavity in the center of the sphere, and channels (approx. 3000) opening from each pore into the central cavity. Simulated body fluid analysis demonstrated the bioactivity of the micro silica spheres; whereas, no bioactivity was recorded for the original untreated sterrasters. The non-cytotoxicity and osteogenic ability of the isolated microspheres were confirmed through osteoblast cell culture. Finally, these silica based porous microspheres were tested for controlled drug release capacity. The spheres showed excellent loading and release abilities for an anti-cancer drug, carboplatin, in simulated solutions and in human cancer cell culture, HeLa, through a real time cell analyzer system. The drug loading capacity of the porous beads was determined as 10.59%. Considering the unique biological and physicochemical properties, these novel bioactive silica spheres, which we name as giant macroporous silica (GMS), are promising materials for a range of applications including bone tissue engineering and drug delivery.

Published

2021

6. A simple approach for the fabrication of 3D microelectrodes for impedimetric sensing

Author

Ismail Bilican, Caglar Elbuken, Mustafa Tahsin Guler, Sedat Agan, Kırıkkale Üniversitesi, Bilimsel ve Teknolojik Uygulama ve Araştırma Merkezi, and Elbuken, Caglar -- 0000-0001-8359-6871

Subjects

Particle counting, Electric fields, Materials science, Fabrication, Electrode spacing, Microfluidics, Nanotechnology, Hydrodynamic focusing, Threedimensional (3-d), Signal, Fluidic devices, Fluid dynamics, Etching (microfabrication), Electrical sensing, Electrical and Electronic Engineering, Electrodes, Focusing, microfabrication, microfluidic electrical sensing, Signal to noise ratio, Microchannel, particle counting, Mechanical Engineering, Electronic, Optical and Magnetic Materials, Microchannels, Microelectrode, Etching, Flow focusing, Mechanics of Materials, Radiation counters, Electrode, Hydrodynamics, Flow-focusing, Microfabrication, Etching solutions, Micro-fluidic devices, 3D microelectrodes, Microfluidic electrical sensing, flow-focusing, Microelectrodes

Abstract

WOS: 000365167700026, In this paper, we present a very simple method to fabricate three-dimensional (3D) microelectrodes integrated with microfluidic devices. We form the electrodes by etching a microwire placed across a microchannel. For precise control of the electrode spacing, we employ a hydrodynamic focusing microfluidic device and control the width of the etching solution stream. The focused widths of the etchant solution and the etching time determine the gap formed between the electrodes. Using the same microfluidic device, we can fabricate integrated 3D electrodes with different electrode gaps. We have demonstrated the functionality of these electrodes using an impedimetric particle counting setup. Using 3D microelectrodes with a diameter of 25 mu m, we have detected 6 mu m-diameter polystyrene beads in a buffer solution as well as erythrocytes in a PBS solution. We study the effect of electrode spacing on the signal-to-noise ratio of the impedance signal and we demonstrate that the smaller the electrode spacing the higher the signal obtained from a single microparticle. The sample stream is introduced to the system using the same hydrodynamic focusing device, which ensures the alignment of the sample in between the electrodes. Utilising a 3D hydrodynamic focusing approach, we force all the particles to go through the sensing region of the electrodes. This fabrication scheme not only provides a very low-cost and easy method for rapid prototyping, but which can also be used for applications requiring 3D electric field focused through a narrow section of the microchannel., Scientific and Technological Research Council of Turkey (TUBITAK) [112M944]; European Union [322019], This project was supported by The Scientific and Technological Research Council of Turkey (TUBITAK project no. 112M944) and European Union FP7 Marie Curie Career Integration Grant (no. 322019). The authors also thank Dr Aykutlu Dana, Dr Gokhan Bakan and Amir Ghobadi for their help in the measurement setup and their comments on the manuscript.

Published

2015