A fiber optic ultrasound transducer for biomedical ultrasound imaging applications Jingcheng Zhou, Nan Wu, Xingwei Wang* Department of Electrical and Computer Engineering, University of Massachusetts Lowell, Lowell MA 01854, USA Results: generation 2.A novel material, gold nanocomposite, was synthesized by directly reducing gold nanoparticles within polydimethylsiloxane (PDMS) through a one-pot protocol. 3.A chicken wing was used as the biomedical ultrasound imaging target. The fiber optic ultrasound transducer was fabricated by coating the gold nanocomposite on the tip of an optical fiber. A hydrophone was used as the fiber optic ultrasound receiver. 4.The ultrasound images were obtained by scanning the transducer mechanically. This poster demonstrates the ultrasound imaging capability of the fiber optic ultrasound transducer by using a chicken wing target. 0.16 3 2 2 19.89 mJ/cm 20 1 0 0 -5 -10 -10 -20 (a) -11 -10 -9 Time (s) -8 -15 0 -7 5 10 15 Frequency (b) 20 25 Fig. 2 (a) The generated photoacoustic ultrasound with pressure 88 kPa. (b) The bandwidth is wider than 20 MHz . -20 2 1.2 mm Focal point 1 (b) 0.78 -1 0 1 2 -10 0 -2 0 mm -1 0 0 1 2 Lateral Position (mm) Results: ultrasound imaging Nanosecond laser 3-axis moving stage Coupler Photoacoustic generator Hydrophone DAQ Chicken wing Fig. 4 The schematic diagram of the experimental setup of the B-mode ultrasound imaging using a chicken wing as the target. A nanosecond laser (Surelite SL I-10, Continuum) was used as the excitation source. A hydrophone (HGL-0200, Onda) was used to collect acoustic signals and to transmit signals to a data acquisition system (DAQ) (M2i.4032, Spectrum). The DAQ system was trigged by a trigger signal from the laser. The hydrophone and the fiber optic ultrasound generator were mounted on a 3-axis moving stage (NRT100, Thorlabs) in order to scan ultrasound images. Contact *Xingwei Wang (Vivian), Ph.D., Associate Professor Department of Electrical and Computer Engineering Center for Photonics, Electromagnetics, and Nanoelectronics (CPEN) University of Massachusetts Lowell, Ball Hall, Room 403 One University Ave., Lowell, MA 01854 Tel: 978-934-1981 FAX: 978-934-3027 Xingwei_Wang@uml.edu http://faculty.uml.edu/xwang/ 3 The ultrasonic field was acquired within a rectangular area (5.0 mm by 4.0 mm) with the resolution of 0.1 mm by the scanning hydrophone. Trigger signal 1. Xiaotian Zou, Nan Wu, Ye Tian, and Xingwei Wang, "Broadband miniature fiber optic ultrasound generator", Optics Express, 22(15), 2. Nan Wu, et al. "High-efficiency optical ultrasound generation using one-pot synthesized polydimethylsiloxane-gold nanoparticle nanocomposite", Journal of the Optical Society of America B, 29(8), 2016-2020 2012. 3. Xiaotian Zou, Tyler Schmitt, David Perloff, Nan Wu, Tzu-Yang Yu, and Xingwei Wang, "Nondestructive corrosion detection using fiber optic photoacoustic ultrasound generator", Measurement, 2014 0.62 -30 Fig. 3 Ultrasonic field distribution in a longitudinal section generated from fiber optic ultrasound generator. (a) Pressure distribution of ultrasonic field. (b) Normalized magnitude distribution of ultrasonic field [1]. 10 5 Focal area Lateral Position (mm) 15 10 0.47 -40 4 (a) Fig. 1 (a) A photo of the photoacoustic generation experimental setup. (b) Gold nanocomposite coated fiber tip [1-3]. 30 0.31 5 Fig. 5 The ultrasound image of the chicken wing. The project was partially supported by National Science Foundation Grant NSF: CMMI-1055358 (Career award) Normalized Magnitude (dB) 4 0 -2 Water References 0 Axial Position (mm) (a) Gold nanocomposite film (125.5 μm in thickness) 5 Amptitude (MPa) MMF (b) Axial Position (mm) Results: ultrasonic field distribution dB 1.This poster presents the design, fabrication and characterization of a fiber optic ultrasound transducer based on photoacoustic (PA) ultrasound generation principle for biomedical ultrasound imaging applications. Voltage (mV) Objectives
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