Transversal ultrasound light guiding deep into scattering media

Biomedical applications requiring tissue diagnosis, activation, and treatment could be substantially leveraged by optical methods, owing to their unique feature set. However, their widespread application is severely limited by the strong light scattering that occurs in many tissues of interest, which dramatically limits achievable penetration depths. Here we demonstrate a new method to solve this issue by utilizing free-running ultrasound waves, transversal to the light propagation direction, to guide light into deeper tissue regions. We study the formation of the ultrasound-induced refractive index structures and waveguides using simple ultrasound field configurations and analyze their effects on the propagation of short light pulses. Our results show waveguide support and associated light intensity increase up to the depths of at least 20 mm in Intralipid-20% phantoms with a reduced scattering coeffcient close to real tissue. Thus we present an important milestone towards low-loss light delivery, focusing and manipulation in deep tissue.