Search
Menu
Meadowlark Optics - Wave Plates 6/24 LB 2024

Remote Sensing Aids Photoacoustic Microscopy in Tissue Mapping

Facebook X LinkedIn Email
Researchers at the University of Hong Kong showed that biological tissue can be imaged with greater sensitivity through remote sensing of photoacoustic signals than through conventional photoacoustic imaging techniques. The researchers demonstrated a near-infrared (NIR), photoacoustic remote sensing microscopy (PARS) technique for noncontact imaging of lipids. The PARS technique enabled broad detection bandwidth, deep penetration depth, and a high signal-to-noise ratio for the imaging of biological samples, in addition to enabling noncontact implementation.

The developed microscopy technique could complement the multispectral techniques of PARS systems and provide useful alternatives for diverse biomedical studies, the researchers said.

Conventional photoacoustic microscopy (PAM) techniques use ultrasonic transducers to collect photoacoustic signals. To ensure effective signal detection, water or a gel is often added between the transducer and the tissue sample, and contact with water or gel can damage the sample. Also, acoustic transducers have limited center response frequency and detection bandwidth, which can reduce PAM’s sensitivity to broadband information.

Instead of using a transducer to detect acoustic signals, PARS uses a laser. This laser source, which is confocal with the excitation beam, serves as the probe beam. The probe beam detects elasto-optical refractive index modulation caused by photoacoustic pressure. The reflection intensity of the probe beam is monitored by the user, and the corresponding photoacoustic signals are analyzed.

The all-optical detection of acoustic signals eliminates direct contact between the PARS system and the sample, helping to protect the integrity of the sample. Further, because the acoustic signals are optically sensed, the detection bandwidth can be transferred from an ultrasonic transducer to a photodiode. This enables broadband detection of photoacoustic signals and can improve detection sensitivity and signal-to-noise ratio.
Mechanism of photoacoustic remote sensing. Courtesy of Guyue Hu, PARS Mechanism, 2023.
Mechanism of photoacoustic remote sensing. Courtesy of Guyue Hu, PARS Mechanism, 2023.
To build the NIR PARS system, the researchers used a 1.7-μm, thulium-doped fiber laser as the pump beam and a 1.5-μm, continuous-wave laser as the detection beam. The detection beam was made confocal with the pump beam in order to detect initial ultrasonic pressure.

PowerPhotonic Ltd. - Bessel Beam Generator MR 6/24

The researchers imaged two forms of pure lipid samples and analyzed the corresponding power spectrum density of the photoacoustic signals. The pump beam selectively stimulated the C-H bond in the lipids. The pump wavelength was selected to overlap the first vibrational overtone of the C-H bond in response to the intensive absorption of lipid molecules. The strong absorption efficiency of the C-H bond at the first overtone region enabled a high signal-to-noise ratio of about 55 dB under moderate irradiation and detection conditions. The researchers found that optical detection via PARS provided a broader frequency response than that of a conventional transducer.

The researchers took advantage of the noncontact nature of PARS and the deep penetration depth at the NIR region to perform tissue-scale lipid imaging on a model organism and mouse brain slices. The resulting images showed good contrast and signal-to-noise ratio, demonstrating that PARS can provide high-performance imaging capability on the tissue scale.

“Photoacoustic remote sensing microscopy achieves label-free imaging that can target specific molecular bonds,” professor Kenneth K.Y. Wong said. “Optical detection of ultrasonic signals provides noncontact operation and a broader frequency response. Meanwhile, the photoacoustic remote sensing microscopy shows high performance for lipid distribution mapping on the tissue scale.”

The research was published in Advanced Photonics Nexus (www.doi.org/10.1117/1.APN.2.2.026011).

Published: April 2023
Glossary
photoacoustic
Photoacoustic refers to the generation of acoustic (sound) waves following the absorption of light (usually laser pulses) by a material. This phenomenon occurs when light energy is absorbed by a material, leading to localized heating and subsequent thermal expansion, which generates pressure waves (sound waves) that can be detected using ultrasonic sensors. The photoacoustic effect is utilized in various scientific and medical applications, including: Photoacoustic imaging (PAI): A...
remote sensing
Remote sensing is a method of data collection and observation where information about objects, areas, or phenomena on Earth's surface is gathered from a distance, typically using sensors onboard satellites, aircraft, drones, or other platforms. This technique enables the monitoring and analysis of Earth's surface and atmosphere without direct physical contact. Remote sensing systems capture electromagnetic radiation (such as visible light, infrared, microwave, or radio waves) reflected or...
medical lasers
Medical lasers are devices that produce intense beams of light with specific characteristics and properties, which are used for various medical applications. These lasers emit light in the form of coherent and focused beams, allowing precise control over the energy delivered to tissues. The term "laser" stands for "light amplification by stimulated emission of radiation." In the medical field, lasers are employed for diagnostic, therapeutic, and surgical purposes. Their applications...
photoacousticPhotoacoustic MicroscopyMicroscopyremote sensingremote sensing microscopyphotoacoustic remote sensing microscopyPAMPARSPARS microscopyResearch & TechnologyeducationThe Hong Kong University of Science and TechnologyUniversity of Hong KongImagingmedicalBiophotonicsAsia PacificsensingSensors & Detectorsbiomedical sensingmedical lasersLasersTechnology NewsBioScan

We use cookies to improve user experience and analyze our website traffic as stated in our Privacy Policy. By using this website, you agree to the use of cookies unless you have disabled them.