Rasim Guldiken scite author profile

Microscale hydrogels find widespread applications in medicine and biology, e.g., as building blocks for tissue engineering and regenerative medicine. In these applications, these microgels are assembled to fabricate large complex 3D constructs. The success of this approach requires non-destructive and high throughput assembly of the microgels. Although various assembly methods have been developed based on modifying interfaces, and using microfluidics, so far, none of the available assembly technologies have shown the ability to assembly microgels using non-invasive fields rapidly within seconds in an efficient way. Acoustics has been widely used in biomedical area to manipulatedroplets, cells and biomolecules. In this study, we developed a simple, non-invasiveacoustic assembler for cell-encapsulating microgels with maintained cell viability (>93%). We assessed the assembler for both microbeads (with diameter of 50 µm and 100 µm) and microgels of different sizes and shapes (e.g., cubes, lock-and-key shapes, tetris, saw) in microdroplets (with volume of 10 µL, 20 µL, 40 µL, 80 µL). The microgels were assembled in second sin a non-invasive manner. These results indicate that the developed acoustic approach could become an enabling biotechnology tool for tissue engineering, regenerative medicine, pharmacology studies and high throughput screening applications.

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Sheathless Size-Based Acoustic Particle Separation

Guldiken

Gallant

et al. 2012

Sensors

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Particle separation is of great interest in many biological and biomedical applications. Flow-based methods have been used to sort particles and cells. However, the main challenge with flow based particle separation systems is the need for a sheath flow for successful operation. Existence of the sheath liquid dilutes the analyte, necessitates precise flow control between sample and sheath flow, requires a complicated design to create sheath flow and separation efficiency depends on the sheath liquid composition. In this paper, we present a microfluidic platform for sheathless particle separation using standing surface acoustic waves. In this platform, particles are first lined up at the center of the channel without introducing any external sheath flow. The particles are then entered into the second stage where particles are driven towards the off-center pressure nodes for size based separation. The larger particles are exposed to more lateral displacement in the channel due to the acoustic force differences. Consequently, different-size particles are separated into multiple collection outlets. The prominent feature of the present microfluidic platform is that the device does not require the use of the sheath flow for positioning and aligning of particles. Instead, the sheathless flow focusing and separation are integrated within a single microfluidic device and accomplished simultaneously. In this paper, we demonstrated two different particle size-resolution separations; (1) 3 μm and 10 μm and (2) 3 μm and 5 μm. Also, the effects of the input power, the flow rate, and particle concentration on the separation efficiency were investigated. These technologies have potential to impact broadly various areas including the essential microfluidic components for lab-on-a-chip system and integrated biological and biomedical applications.

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Microfluidically Reconfigured Wideband Frequency-Tunable Liquid-Metal Monopole Antenna

Dey

Guldiken

Mumcu

2016

IEEE Trans. Antennas Propagat.

107

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Annular-ring CMUT arrays for forward-looking IVUS: transducer characterization and imaging

Degertekin

Guldiken

Karaman

2006

IEEE Trans. Ultrason., Ferroelect., Freq. Contr.

126

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In this study, a 64-element, 1.15-mm diameter annular-ring capacitive micromachined ultrasonic transducer (CMUT) array was characterized and used for forward-looking intravascular ultrasound (IVUS) imaging tests. The array was manufactured using low-temperature processes suitable for CMOS electronics integration on a single chip. The measured radiation pattern of a 43 140-m 2 array element depicts a 40 view angle for forwardlooking imaging around a 15-MHz center frequency in agreement with theoretical models. Pulse-echo measurements show a ;10-dB fractional bandwidth of 104% around 17 MHz for wire targets 2.5 mm away from the array in vegetable oil. For imaging and SNR measurements, RF Ascan data sets from various targets were collected using an interconnect scheme forming a 32-element array configuration. An experimental point spread function was obtained and compared with simulated and theoretical array responses, showing good agreement. Therefore, this study demonstrates that annular-ring CMUT arrays fabricated with CMOS-compatible processes are capable of forwardlooking IVUS imaging, and the developed modeling tools can be used to design improved IVUS imaging arrays.

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Fluidic assembly at the microscale: progress and prospects

Crane

Onen

Carballo

et al. 2012

Microfluid Nanofluid

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Rasim Guldiken

The assembly of cell-encapsulating microscale hydrogels using acoustic waves

Sheathless Size-Based Acoustic Particle Separation

Microfluidically Reconfigured Wideband Frequency-Tunable Liquid-Metal Monopole Antenna

Annular-ring CMUT arrays for forward-looking IVUS: transducer characterization and imaging

Fluidic assembly at the microscale: progress and prospects

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