Multimodal spectral focusing CARS and SFG microscopy with a tailored coherent continuum from a microstructured fiber

We report a technologically novel microscopy system for bioimaging based on 100 fs Titanium:Sapphire (Ti:Sa) laser coherent continuum from a tailored, 9 cm long All Normal Dispersion (ANDi) fiber, enabling concurrent image contrast with a) Spectral Focusing Coherent Anti-Stokes Raman Scattering (SF-CARS) (spanning 900-3200 cm-1) and b) sum-frequency-generation (SFG). Both modalities were efficiently excited with power levels at the microscope focus compatible with biological samples. Moreover, using the continuum, images were recorded in the back-scattering (epi-detection) geometry, without the necessity for an expensive, computer-controlled, Spatial Light Modulator (SLM), clearly demonstrating the strong signal levels achieved. Image contrast from the multiple modalities provided greater chemical and structural insights than imaging with any single technique in isolation. Numerical simulations supported these developments in regard to both the optimum fiber length for SC generation and the achievement of high spectral resolution in SF-CARS via careful group-delay-dispersion matching across the pump and Stokes pulses using just an inexpensive sequence of short glass blocks inserted into the Stokes beam. We show bio-images of mouse tissue recorded concurrently via label/stain-free contrast from multiple modalities: CARS, Two Photon auto-Fluorescence (TPaF) and Second Harmonic/Sum Frequency Generation (SHG/SFG). Overall our approach delivers optimum performance in back-scattered (epi-) detection configuration, suited for thick samples, at reduced complexity and cost. The addition of this simple fiber add-on to lasers already widely used for TPF microscopy can thus extend the capabilities of a significant number of existing microscopy laboratories.