BIOMEDICAL IMAGING: Optical absorption's suppression of interference promising for biomedical imaging

Sept. 16, 2014

A new discovery could improve medical imaging within biological tissue: Physicists from the University of Twente and Yale University found that light traveling through a diffusing material follows a straighter path if the material partially absorbs the light.

A new discovery could improve medical imaging within biological tissue: Physicists from the University of Twente (Enschede, The Netherlands) and Yale University (New Haven, CT) found that light traveling through a diffusing material follows a straighter path if the material partially absorbs the light.¹

Numerical calculations reveal the distribution of light intensity inside an opaque diffusing medium. Light enters the material from the left. The top image demonstrates multiple scattering, which causes the light paths to become random walks (blue arrows). The light exits in random directions, which precludes imaging. The bottom image illustrates an absorbing opaque medium. The transport of light occurs via straighter paths, which results in a coherent image on the right-hand side. (Image courtesy of the Dutch Foundation for Fundamental Research on Matter)

Photons traveling through a scattering medium perform a random walk, which resembles an uncoordinated stagger. The researchers found that in opaque media such as biological tissue, light absorption actually straightens this path, leading to less diffraction by scattering and thus improved imaging through the material.

This seems counterintuitive: Light absorption is usually detrimental for imaging, as it reduces the intensity of the visible image. But the researchers discovered that if enough light is absorbed, interference is suppressed; numerical calculations showed that long, meandering light paths are suppressed far more than short, straight paths. With increasing absorption, straight ("ballistic") light paths persist while the number of scattered paths is considerably reduced.

1. S. F. Liew et al., Phys. Rev. B, 89, 25 (2014); doi:10.1103/PhysRevB.89.224202.