Optoacoustic imaging

Optoacoustic imaging, commonly known as photoacoustic imaging, is a cutting-edge imaging modality that leverages the photoacoustic effect to render detailed images of structures, particularly in turbid environments. This advanced technique synergizes the precision of spectroscopy with the depth resolution of ultrasound, offering a unique toolset for medical and research applications.

Background and Principles[edit | edit source]

The photoacoustic effect, underpinning optoacoustic imaging, refers to the generation of acoustic waves when pulsed or modulated optical radiation is absorbed by a material^[1]. In the context of biomedical imaging, the emitted acoustic waves—often within the ultrasound frequency range—are captured and used to construct images of the tissue or structure of interest.

Technical Components and Workflow[edit | edit source]

To conduct optoacoustic imaging, specific components are integral:

Light Source: Typically, a pulsed laser provides the required optical radiation, which is tuned to specific wavelengths for targeted imaging applications.
Ultrasound Detector: After tissue absorption, the generated acoustic waves are detected using an ultrasonic transducer^[2].
Image Reconstruction Algorithms: These computational tools transform the captured acoustic signals into meaningful, interpretable images.

Applications[edit | edit source]

Optoacoustic imaging has been explored and applied across various disciplines due to its unique advantages:

Medical imaging[edit | edit source]

Oncology: Identification and characterization of tumors^[3].
Neurology: Brain imaging, particularly in rodent models, to study hemodynamics and oxygen metabolism^[4].
Ophthalmology: Imaging of the retina and choroidal vasculature^[5].

Research & Development:

Drug Delivery Monitoring: Tracking drug carriers and assessing their distribution^[6].
Functional Imaging: Capturing dynamic physiological responses to interventions or stimuli^[7].

Advantages and Limitations[edit | edit source]

Pros:

High Spatial Resolution: Combining optical and acoustic properties provides images with superior spatial resolution.
Depth: Capable of visualizing structures several centimeters beneath the surface^[8].

Cons:

Limited to Optically Absorptive Targets: Can only detect structures or molecules that absorb the specific wavelengths of light used.

Future Perspectives[edit | edit source]

With ongoing technological innovations, optoacoustic imaging is poised for broader applications. Efforts are being made to enhance system portability, improve imaging depth, and expand its clinical utility.

Conclusion[edit | edit source]

Optoacoustic imaging represents an exciting frontier in biomedical imaging. Its capacity to integrate the advantages of both optical and ultrasound imaging provides a powerful diagnostic and research tool that continues to find application in diverse biomedical domains.

References[edit | edit source]

↑ Wang, L. V., & Yao, J. (2016). A practical guide to photoacoustic tomography in the life sciences. Nature Methods, 13(8), 627–638.
↑ Xu, M., & Wang, L. V. (2006). Photoacoustic imaging in biomedicine. Review of Scientific Instruments, 77(4), 041101.
↑ Luke, G.P., Yeager, D., & Emelianov, S.Y. (2012). Biomedical applications of photoacoustic imaging with exogenous contrast agents. Annals of Biomedical Engineering, 40(2), 422-437.
↑ Yao, J., Wang, L., Yang, J. M., Maslov, K. I., Wong, T. T., Li, L., ... & Wang, L. V. (2015). High-speed label-free functional photoacoustic microscopy of mouse brain in action. Nature methods, 12(5), 407-410.
↑ de la Zerda, A., Paulus, Y. M., Teed, R., Bodapati, S., Dollberg, Y., Khuri-Yakub, B. T., ... & Blumenkranz, M. S. (2010). Photoacoustic ocular imaging. Optics letters, 35(3), 270-272.
↑ Wang, B., Yantsen, E., Larson, T., Karpiouk, A. B., Sethuraman, S., Su, J. L., ... & Emelianov, S. Y. (2008). Plasmonic intravascular photoacoustic imaging for detection of macrophages in atherosclerotic plaques. Nano letters, 9(6), 2212-2217.
↑ Wang, L. V. (2009). Multiscale photoacoustic microscopy and computed tomography. Nature Photonics, 3(9), 503–509.
↑ Zhang, H. F., Maslov, K., & Wang, L. V. (2007). In vivo imaging of subcutaneous structures using functional photoacoustic microscopy. Nature Protocols, 2(4), 797–804.

Search WikiMD

Ad.Tired of being Overweight? Try W8MD's physician weight loss program.
Semaglutide (Ozempic / Wegovy and Tirzepatide (Mounjaro) available.
Advertise on WikiMD

WikiMD is not a substitute for professional medical advice. See full disclaimer.

Credits:Most images are courtesy of Wikimedia commons, and templates Wikipedia, licensed under CC BY SA or similar.

[1] Wang, L. V., & Yao, J. (2016). A practical guide to photoacoustic tomography in the life sciences. Nature Methods, 13(8), 627–638.

[2] Xu, M., & Wang, L. V. (2006). Photoacoustic imaging in biomedicine. Review of Scientific Instruments, 77(4), 041101.

[3] Luke, G.P., Yeager, D., & Emelianov, S.Y. (2012). Biomedical applications of photoacoustic imaging with exogenous contrast agents. Annals of Biomedical Engineering, 40(2), 422-437.

[4] Yao, J., Wang, L., Yang, J. M., Maslov, K. I., Wong, T. T., Li, L., ... & Wang, L. V. (2015). High-speed label-free functional photoacoustic microscopy of mouse brain in action. Nature methods, 12(5), 407-410.

[5] Zerda, A., Paulus, Y. M., Teed, R., Bodapati, S., Dollberg, Y., Khuri-Yakub, B. T., ... & Blumenkranz, M. S. (2010). Photoacoustic ocular imaging. Optics letters, 35(3), 270-272.

[6] Wang, B., Yantsen, E., Larson, T., Karpiouk, A. B., Sethuraman, S., Su, J. L., ... & Emelianov, S. Y. (2008). Plasmonic intravascular photoacoustic imaging for detection of macrophages in atherosclerotic plaques. Nano letters, 9(6), 2212-2217.

[7] Wang, L. V. (2009). Multiscale photoacoustic microscopy and computed tomography. Nature Photonics, 3(9), 503–509.

[8] Zhang, H. F., Maslov, K., & Wang, L. V. (2007). In vivo imaging of subcutaneous structures using functional photoacoustic microscopy. Nature Protocols, 2(4), 797–804.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]