Abstract
Nonlinear photothermal microscopy is applied in the imaging of biological tissues stained with chlorophyll and hematoxylin. Experimental results show that this type of organic molecules, which absorb light but transform dominant part of the absorbed energy into heat, may be ideal probes for photothermal imaging without photochemical toxicity. Picosecond pump and probe pulses, with central wavelengths of 488 and 632 nm, respectively, are spectrally filtered from a compact supercontinuum fiber laser source. Based on the light source, a compact and sensitive super-resolution imaging system is constructed. Further more, the imaging system is much less affected by thermal blurring than photothermal microscopes with continuous-wave light sources. The spatial resolution of nonlinear photothermal microscopy is ~ 188 nm. It is ~ 23% higher than commonly utilized linear photothermal microscopy experimentally and ~43% than conventional optical microscopy theoretically. The nonlinear photothermal imaging technology can be used in the evaluation of biological tissues with high-resolution and contrast.
Highlights
Photothermal (PT) microscopy (PTM) is very attractive for intact imaging with sensitivity as high as a single-molecule level [1,2,3]
We have demonstrated the simultaneous linear PT (LPT) and nonlinear PT (NLPT) imaging of mouse spinal cord, kidney and small intestine stained with chlorophyll or hematoxylin
NLPTM is applied in the imaging of biological tissues stained with chlorophyll and hematoxylin
Summary
Photothermal (PT) microscopy (PTM) is very attractive for intact imaging with sensitivity as high as a single-molecule level [1,2,3]. Many organic molecules, such as melanin [10], heme proteins [10] and chlorophyll [11], absorb light but transfer most of the absorbed energy to heat. Such non-/weakly emissive organic molecules possess capabilities of being used as the probes for PT imaging without cytotoxicity. The absorption spectrum varies among different molecules/cells in the biological tissues, such as a relatively narrow band with a peak at 550 nm for hemoglobin in skin [10], a broad band extending from UV to near infrared for melanin [10] and structured spectrum with several peaks for chlorophyll [18]. A laser source with a broad spectral range is necessary for imaging of different tissues
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
