Nanosecond-resolution photothermal dynamic imaging via MHZ digitization and match filtering

Yin, Jiaze; Lan, Lu; Zhang, Yi; Ni, Hongli; Tan, Yuying; Zhang, Meng; Bai, Yeran; Cheng, Ji‐Xin

doi:10.1038/s41467-021-27362-w

Cited by 35 publications

(66 citation statements)

References 67 publications

(77 reference statements)

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“…The inclusion of the higher harmonics in the demodulation improved the SNR by a factor of ∼2, since all MIP signal components were recovered (Figure ). This was also demonstrated in a previous work using point-scan imaging …”

Section: Discussionsupporting

confidence: 79%

“…The ability to record decay profiles is an important feature that has proven useful for instrument design and optimization, theory development, signal simulation, and target compound characterization. 15,26 Here, it is demonstrated for K-FeCy microparticles that the thermal decay time decreases with particle size, most likely because the effective transfer surface area between the specimen and the surrounding increases. In general, K-FeCy exhibits longer thermal decay times than polymer beads of the same size, 26 even when suspended in 1-propanol, which facilitates heat dissipation.…”

Section: ■ Discussionmentioning

confidence: 87%

“…This was also demonstrated in a previous work using point-scan imaging. 15 Based on the Abbe resolution equation R x, y = λ/2NA, the theoretical diffraction limit of the current WIPH system is 411 nm. As confirmed with the help of the test target, the spatial coverage of one camera pixel, which is defined by the objective magnification (40×), the focal length of the tube lens (200 mm), and the pixel size (20 μm), is ∼500 nm.…”

Section: ■ Discussionmentioning

confidence: 99%

“…Since a LIA usually demodulates only one of the (lower) harmonics, the MIP signal amplitude is not maximized, and the nonlinear photothermal decay cannot be accurately resolved. This led to the development of multiharmonic demodulation MIP schemes, such as photothermal dynamics imaging (PDI) . PDI makes use of high bandwidth detection to obtain nanosecond temporal resolution per pixel within a single pulse excitation and enables retrieval of the thermal decay profile, which can improve the chemical contrast in complex samples and provide valuable physical properties of the target.…”

Section: Introductionmentioning

confidence: 99%

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Ultrafast Widefield Mid-Infrared Photothermal Heterodyne Imaging

Paiva

Schmidt

2022

Anal. Chem.

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Mid-infrared photothermal (MIP) microscopy is a valuable tool for sensitive and fast chemical imaging with high spatial resolution beyond the mid-infrared diffraction limit. The highest sensitivity is usually achieved with heterodyne MIP employing photodetector point-scans and lock-in detection, while the fastest systems use camera-based widefield MIP with pulsed probe light. One challenge is to simultaneously achieve high sensitivity, spatial resolution, and speed in a large field of view. Here, we present widefield mid-infrared photothermal heterodyne (WIPH) imaging, where a digital frequency-domain lock-in (DFdLi) filter is used for simultaneous multiharmonic demodulation of MIP signals recorded by individual camera pixels at frame rates up to 200 kHz. The DFdLi filter enables the use of continuous-wave probe light, which, in turn, eliminates the need for synchronization schemes and allows measuring MIP decay curves. The WIPH approach is characterized by imaging potassium ferricyanide microparticles and applied to detect lipid droplets (alkyne-palmitic acid) in 3T3-L1 fibroblast cells, both in the cell-silent spectral region around 2100 cm–1 using an external-cavity quantum cascade laser. The system achieved up to 4000 WIPH images per second at a signal-to-noise ratio of 5.52 and 1 μm spatial resolution in a 128 × 128 μm field of view. The technique opens up for real-time chemical imaging of fast processes in biology, medicine, and material science.

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Section: Discussionsupporting

confidence: 79%

Section: ■ Discussionmentioning

confidence: 87%

Section: ■ Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Ultrafast Widefield Mid-Infrared Photothermal Heterodyne Imaging

Paiva

Schmidt

2022

Anal. Chem.

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“…The emerging mid-infrared photothermal (MIP) microscopy 18 inherits IR absorption spectroscopy's advantages but circumvents conventional IR micro-spectroscopy's low-resolution and slow speed limit. MIP microscopy provides diffraction-limited resolution at the visible band using a visible probe beam and is compatible with both point-scanning [25][26][27][28] and wide-field [29][30][31][32][33][34] configuration. Yet, existing MIP microscopy suffer from slow volumetric imaging speed and low depth resolution.…”

Section: Introductionmentioning

confidence: 99%

Bond-selective intensity diffraction tomography

Zhao¹,

Matlock

Song

et al. 2022

Advanced Chemical Microscopy for Life Science and Translational Medicine 2022

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Recovering molecular information remains a grand challenge in the widely used holographic and computational imaging technologies. To address this challenge, we developed a computational mid-infrared photothermal microscope, termed Bond-selective Intensity Diffraction Tomography (BS-IDT). Based on a low-cost brightfield microscope with an add-on pulsed light source, BS-IDT recovers both infrared spectra and bond-selective 3D refractive index maps from intensity-only measurements. High-fidelity infrared fingerprint spectra extraction is validated. Volumetric chemical imaging of biological cells is demonstrated at a speed of ~20 seconds per volume, with a lateral and axial resolution of ~350 nm and ~1.1 µm, respectively. BS-IDT's application potential is investigated by chemically quantifying lipids stored in cancer cells and volumetric chemical imaging on Caenorhabditis elegans with a large field of view (~100 µm x 100 µm).

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Visualizing DNA/RNA, Proteins, and Small Molecule Metabolites within Live Cells

Jia,

Cui,

Ding

2024

Small

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Live cell imaging is essential for obtaining spatial and temporal insights into dynamic molecular events within heterogeneous individual cells, in situ intracellular networks, and in vivo organisms. Molecular tracking in live cells is also a critical and general requirement for studying dynamic physiological processes in cell biology, cancer, developmental biology, and neuroscience. Alongside this context, this review provides a comprehensive overview of recent research progress in live‐cell imaging of RNAs, DNAs, proteins, and small‐molecule metabolites, as well as their applications in molecular diagnosis, immunodiagnosis, and biochemical diagnosis. A series of advanced live‐cell imaging techniques have been introduced and summarized, including high‐precision live‐cell imaging, high‐resolution imaging, low‐abundance imaging, multidimensional imaging, multipath imaging, rapid imaging, and computationally driven live‐cell imaging methods, all of which offer valuable insights for disease prevention, diagnosis, and treatment. This review article also addresses the current challenges, potential solutions, and future development prospects in this field.

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Nanosecond-resolution photothermal dynamic imaging via MHZ digitization and match filtering

Cited by 35 publications

References 67 publications

Ultrafast Widefield Mid-Infrared Photothermal Heterodyne Imaging

Ultrafast Widefield Mid-Infrared Photothermal Heterodyne Imaging

Bond-selective intensity diffraction tomography

Visualizing DNA/RNA, Proteins, and Small Molecule Metabolites within Live Cells

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