Journal
OPTO-ELECTRONIC ADVANCES
Volume 4, Issue 8, Pages -Publisher
CHINESE ACAD SCI, INST OPTICS & ELECTRONICS, ED OFF OPTO-ELECTRONIC ADV
DOI: 10.29026/oea.2021.200081
Keywords
flexible ultrasound transducer; fiber-laser ultrasound sensor; multiscale photoacoustic imaging; photoacoustic microscopy; photoacoustic computed tomography
Categories
Funding
- National Natural Science Foundation of China [61775083, 61705082, 61805102, 61860206002]
- Local Innovative and Research Teams Project of Guangdong Pearl River Talents Program [2019BT02X105]
- Guangzhou Science and Technology Plan [201904020032]
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Photoacoustic imaging (PAI) technology has been developed to achieve multiscale imaging of biological samples using a flexible fiber-laser ultrasound sensor (FUS) based on optical fibers. The FUS allows for tuning of spatial ultrasound responses by bending the fiber laser, enabling wide-view optical-resolution photoacoustic microscopy and photoacoustic computed tomography at different depths. Compared to traditional rigid piezoelectric transducers, the flexible FUS provides the flexibility to design various multiscale PAI modalities.
Photoacoustic imaging (PAI) is a noninvasive biomedical imaging technology capable of multiscale imaging of biological samples from organs down to cells. Multiscale PAI requires different ultrasound transducers that are flat or focused because the current widely-used piezoelectric transducers are rigid and lack the flexibility to tune their spatial ultrasound responses. Inspired by the rapidly-developing flexible photonics, we exploited the inherent flexibility and low-loss features of optical fibers to develop a flexible fiber-laser ultrasound sensor (FUS) for multiscale PAI. By simply bending the fiber laser from straight to curved geometry, the spatial ultrasound response of the FUS can be tuned for both wide-view optical-resolution photoacoustic microscopy at optical diffraction-limited depth (similar to 1 mm) and photoacoustic computed tomography at optical dissipation-limited depth of several centimeters. A radio-frequency demodulation was employed to get the readout of the beat frequency variation of two orthogonal polarization modes in the FUS output, which ensures lownoise and stable ultrasound detection. Compared to traditional piezoelectrical transducers with fixed ultrasound responses once manufactured, the flexible FUS provides the freedom to design multiscale PAI modalities including wearable microscope, intravascular endoscopy, and portable tomography system, which is attractive to fundamental biological/medical studies and clinical applications.
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