BIOMEDICAL OPTICAL IMAGING AND BIOPHOTONICS GROUP
Professor James G. Fujimoto

Optical Coherence Tomography

Optical coherence tomography (OCT) can generate high resolution, cross-sectional and three dimensional images of microstructure in biological systems.

Imaging can be performed in real time without the need to remove and process a specimen as in conventional biopsy.

 Principles of OCT imaging. OCT generates cross-sectional and three dimensional images of tissue microstructure and architectural morphology in vivo in real time.


Principles of OCT imaging. OCT generates cross-sectional and three dimensional images of tissue microstructure and architectural morphology in vivo in real time.

Optical coherence tomography (OCT) is an emerging imaging modality which can generate high resolution, cross-sectional and three dimensional images of microstructure in biological systems. OCT is analogous to ultrasound B mode imaging, except that it uses light instead of sound. Imaging is performed by measuring the echo time delay of optical backscattering in the tissue as a function of transverse position. The penetration depth of OCT imaging is limited by attenuation from optical scattering to ~2 to 3 mm in most tissues, however image resolutions of 1-15 um may be achieved. OCT functions as a type of “optical biopsy” enabling in situ visualization of tissue microstructure with resolutions approaching that of conventional histopathology. Imaging can be performed in real time without the need to remove and process a specimen as in conventional biopsy.

Schematic of a Spectral / Fourier Domain OCT system for human retinal imaging.

Schematic of a Spectral / Fourier Domain OCT system for human retinal imaging.

Schematic of a Swept Source / Fourier Domain OCT imaging system.

Schematic of a Swept Source / Fourier Domain OCT imaging system.

OCT technology utilizes advances in photonics and fiber optics such as femtosecond broadband lasers, high speed wavelength swept lasers and line scan camera technologies. Recent developments using Fourier domain detection achieve dramatic improvements in resolution and imaging speed. Three dimensional, volumetric imaging with extremely high voxel density is now possible, enabling microstructure and pathology to be visualized and rendered in a manner analogous to MR imaging. OCT is rapidly becoming a clinical standard in ophthalmology, where it can image retinal pathology with unprecedented resolutions. OCT is also being developed for other applications ranging from cancer detection in endoscopy, to intravascular imaging in cardiology.