The goal of the proposed research is to develop a novel optical imaging technology for in vivo functional imaging of biological tissue. Encoding light by high-frequency ultrasound in biological tissue yields high spatial resolution: 100 mu/m in the R21 phase and 20 m/um in the R33 phase with a maximum imaging depth of 2-4 mm. The current optical technologies for in vivo high-resolution imaging of biological tissue include primarily confocal microscopy and optical-coherence tomography. Confocal microscopy can achieve approximately 10-mu/mm resolution but can image up to only 0.5 mm into biological tissue. Optical-coherence tomography can achieve approximately 10-mu/m resolution but can image only approximately -1 mm into scattering biological tissue. Although both technologies are useful in their areas of strength, many superficial lesions of interest are deep beyond reach. Both of the technologies depend primarily on singly backscattered photons for spatial resolution. Because biological tissues, with the exception of ocular tissue, are highly scattering for light transport, singly backscattered light attenuates rapidly with imaging depth. Therefore, both of the technologies have fundamentally limited maximum imaging depths that restrict their applications. The proposed optical imaging system overcomes this limitation on maximum imaging depth. The proposed technology does not depend on singly backscattered light. A chirped ultrasonic wave is focused into biological tissue. Any light that is encoded by ultrasound, including both singly and multiply scattered photons, contributes to the imaging signal. The axial resolution is achieved with ultrasonic-frequency sweeping and Fourier transformation. The lateral resolution is acquired by focusing the ultrasonic wave. The imaging resolutions as well as the maximum imaging depth are scaleable with the ultrasonic frequency. Dual wavelengths will be employed in the R33 phase for the functional imaging of oxygenation saturation of hemoglobin. Focused optical delivery and optical spatial filtering are used to improve the signal-to-noise ratio. The proposed technology--a quantum leap from the state of the art--is complementary to confocal microscopy and optical-coherence tomography and has the potential for broad application in biomedicine.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21CA094267-01A1
Application #
6581615
Study Section
Special Emphasis Panel (ZCA1-SRRB-9 (O1))
Program Officer
Baker, Houston
Project Start
2003-09-06
Project End
2004-08-31
Budget Start
2003-09-06
Budget End
2004-08-31
Support Year
1
Fiscal Year
2003
Total Cost
$130,300
Indirect Cost
Name
Texas Engineering Experiment Station
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
847205572
City
College Station
State
TX
Country
United States
Zip Code
77845
Kothapalli, Sri-Rajasekhar; Wang, Lihong V (2009) Ex vivo blood vessel imaging using ultrasound-modulated optical microscopy. J Biomed Opt 14:014015
Zemp, Roger J; Kim, Chulhong; Wang, Lihong V (2007) Ultrasound-modulated optical tomography with intense acoustic bursts. Appl Opt 46:1615-23