Abstract
.Significance: Spectral-domain optical coherence tomography (SD-OCT) offers depth-resolved imaging of optical scattering contrast but is limited in sensitivity to optical absorption. Dual-modality imaging combined with the noncontact absorption contrast of photoacoustic remote sensing (PARS) microscopy can augment SD-OCT applications with specific molecular and functional contrasts in an all-optical, fiber-based platform.Aim: To develop a fiber-based multimodal PARS and SD-OCT imaging system, which efficiently uses a common 1050-nm light source for SD-OCT and PARS interrogation.Approach: PARS microscopy has predominantly utilized a 1310-nm interrogation light source to date. Hence, a recent dual-modality PARS and 1050-nm SD-OCT imaging system required three distinct wavelengths including a 532-nm PARS excitation, necessitating a free-space optical architecture with discrete subsystems. Here, we validate the first use of a 1050-nm interrogation wavelength for PARS. This enables the transition to fiber-based interferometry as is standard in modern SD-OCT systems, though infeasible with inclusion of an additional 1310-nm wavelength. PARS interrogation functionality is integrated using a broadband optical circulator.Results: Dual-modality imaging is demonstrated in carbon fiber phantoms and a mouse ear in vivo. SD-OCT provided a lateral resolution, axial resolution in air, and of sensitivity, and PARS contributed 532-nm optical absorption contrast with a 47-dB SNR, and lateral and axial resolutions of 2.4 and , respectively. Total interrogation power was reduced from 90% to 58% of the ANSI limit compared to a previous three-wavelength approach.Conclusions: Adapting PARS to use the 1050-nm SD-OCT light source for interrogation enabled implementation of a fiber-based dual-modality system configuration, with image quality maintained. This will facilitate development of potential applications demanding handheld, catheter-based, or endoscopic form factors.
Highlights
Optical coherence tomography (OCT) is a modality that generates depth-resolved images of the optical scattering intensity within a sample.[1]
Total interrogation power was reduced from 90% to 58% of the American National Standards Institute (ANSI) limit compared to a previous three-wavelength approach
We reported an all-optical, dual-modality imaging system that integrated photoacoustic remote sensing (PARS) microscopy with spectral-domain optical coherence tomography (SD-OCT).[15]
Summary
Optical coherence tomography (OCT) is a modality that generates depth-resolved images of the optical scattering intensity within a sample.[1] Functioning on the basis of low-coherence interferometry, it is capable of providing μm-order axial resolution, determined inversely by the spectral bandwidth of the light source. The utility of OCT has been proven in several clinical and Journal of Biomedical Optics. OCT offers remarkable sensitivity to backscattered light, its ability to reveal optical absorption is relatively limited, and scattering contrast alone provides poor specificity for differentiating salient features in many tissues. Several multimodal imaging systems have been reported, combining OCT with the complementary contrast of other imaging mechanisms including fluorescence,[5] photoacoustic, and nonlinear microscopies.[6,7,8]
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